Login| Sign Up| Help| Contact|

Patent Searching and Data


Title:
ANCHOR ASSEMBLY OF THERMALLY INSULATING BUILDING CONTACT AND CONTACTLESS SYSTEM AND MOUNTING JIG AND INSTALLATION TOOL FOR ADJUSTMENT OF ANCHOR ASSEMBLY
Document Type and Number:
WIPO Patent Application WO/2013/037332
Kind Code:
A1
Abstract:
The anchoring connection includes a self-supporting anchor (1, 1a, 1b, 1c, 1d) without inner reinforcement pins, the body (2) of which Worn metallic or non-metallic netting in the form of a tubular coil or space spiral (17, 17a) is provided with at least one screwing and/or recessing item, the external maximum dimension Φz of which, vertical to the longitudinal axis (5) of the body (2), is always bigger than the external maximum dimension Φz of the body (2) vertical to the longitudinal axis (5) of the body (2). Each screwing item is equipped with at least one cutting edge and/or at least one cutting surface for the creation of the efficient screwing surface (33), which represents the screwing surface (33) or a sum of projections of screwing surfaces (33) to a plane vertical to the longitudinal axis (5) of the body (2). Each recessing item is equipped with at least one recessing edge and/or at least one recessing surface for the creation of the efficient recessing surface (34), which represents the surface or a sum of projections of recessing surfaces (34) to a plane vertical to the longitudinal axis (5) of the body (2). Furthermore, the anchoring connection includes the expansion filling material (3), which fills, after hardening: the body (2) of the anchor (1, 1a, 1 b, 1c, 1d) outside and inside or, as the case may be, the inside of the coil or space spiral of the body (2), the surroundings of the external screwing and/or recessing item, all free space in the anchoring hole (15) and marks in the building insulation (16) created after the penetration of the screwing and/or recessing item into the building insulation (16). A mounting jig (11) and an installation tool (19) are designed for adjustment of the anchor assembly.

Inventors:
MICEK IVAN (SK)
Application Number:
PCT/CZ2012/000091
Publication Date:
March 21, 2013
Filing Date:
September 13, 2012
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
ECORAW CZ S R O (CZ)
MICEK IVAN (SK)
International Classes:
B25B31/00; E04B1/76; E04F13/08; F16B13/00; F16B13/14
Foreign References:
CZ22586U12011-08-15
DE29617495U11996-11-28
DE102006021513A12007-11-15
DE102009059204A12011-06-22
EP2213888A22010-08-04
CZ290305B62002-07-17
Attorney, Agent or Firm:
SMRČKOVÁ, Marie (Praha 6, CZ)
Download PDF:
Claims:
P A T E N T C L A I M S

1. The anchor assembly for the insulating building contact and contactless system, includes

a building structure (17) and , a building insulation (16), between which an air gap (32) is situated in the contactless system, in which gluing targets (31) are formed;

the anchor (1 , 1a, 1b, 1c, 1d) made of metallic or non-metallic netting and created in the form of a tubular coil or spiral, which is slid into the anchoring hole (15) in the contactless and contact systems, from the external side of the building insulation (16) and through the building insulation (16) up to building structure (17), and then the anchor (1 , 1a, 1b, 1c, 1d) in the anchoring hole (15) is filled with the expansion filling material, which creates the anchoring connection (3), characterized in that the anchoring connection includes

15

- self-supporting anchor (1 , 1a, i b, 1c, 1d) without inner reinforcement pins, the body (2) of which, is made with at least one screwing and/or recessing item, the external maximum dimension (Φζ) of which, vertical to the longitudinal axis (5) of the body (2), is always bigger than the external maximum dimension (Ot) of the body (2) vertical to

20 the longitudinal axis (5) of the body (2); whereas

- each screwing item is equipped with at least one cutting edge and/or at least one cutting surface for the creation of efficient screwing surface, which represents the

^ screwing surface (33) of a sum of projections of screwing surfaces (33) to a plane vertical to the longitudinai axis (5) of the body (2); and

- each recessing item is equipped with at least one recessing edge and/or at least one recessing surface, for the crfeation of efficient recessing surface, which represents the

^ recessing surface (34) or a sum of projections of recessing surfaces (34) to a plane vertical to the longitudinal axis (5) of the body (2); and

- the expansion filling material (3) that fills, after hardening: the body (2) of the anchor (1 , 1a, 1b, 1c, 1d) outside and inside or, as the case may be, the inside of the coil or

^ space spiral of the body (2), the surroundings of the external screwing and/or recessing item, all free space in the anchoring hole (15) and the marks in the building insulation (16) formed after the penetration of the screwing and/or recessing item into the building insulation (16).

2. The anchor assembly pursuant to the claim 1 , characterized in that

the body (2) of the anchor (1 , 1a, 1b, 1c, 1d) is provided with at least one screwing and/or recessing item on one or both of its ends or its end parts or in their immediate vicinity.

3. The anchor assembly pursuant to the claim 1 , characterized in that

each screwing item is selected from a group, including independently or in

combination of the screwing module (10, 10a, 10b, 10c, 10d, 10f, 10g, 10h, 10i) with blades, screwing ring, blades and load-bearing ring (18) or, as the case may be, with blades.

4. The anchor assembly pursuant to the claim 1 , characterized in that

each recessing item is selected from a group, including independently or in combination, a cut segment (4), rim (6), shoulder, (9), shim (7,7a) and conical extension (29).

5. The anchor assembly pursuant to the claim 2, characterized in that

the anchor (1 ) is realized, as the screwing anchor (1d), which is created by:

- a combination of the body (2) of the anchor (1 b) with a rim (6) and the cap

screwing module (10), or

- a combination of the bbdy (2) of the anchor (1) firmly connected with the screwing module (10), or

- from the body of the anchor (1 ) ended with blades or, as the case may be, provided with a

permanent deformation, i.e. shoulder (9)( or conical extension (29).

6. The anchor assembly pursuant to the claim 1 , characterized in that

the screwing and/or recessing item is created as one integral unit with the anchor (1 , 1a, 1b, 1c, 1d) before,' at or even after sliding into the anchoring hole (15).

'?'

7. The anchor assembly pursuant to the claim 1 , characterized in that

the screwing and/or recessing item are created as an independent cap or put-on item.

8. The anchor assembly pursuant to the claim 1 , characterized in that

the screwing and/or recessing items are located in the building insulation (16) sind possibly up into the building structure (17,17a) or even behind building structure (17, 17a), whereas the following parameters are designed in advance pursuant to thickness and type of the material of the building insulation (16):

- distance (d) between the external surface of the building insulation (16) and the nearest facing point of the screwing and/or recessing item,

- distance (h) between the most distant point of the screwing and/or recessing item from the external surface of the building insulation (16) and !

- depth (L) of sliding of the body ,(2) of the anchor (1 , 1a, 1b, 1c, 1d) into the building insulation (16).

9. The anchor assembly pursuant to the claim 1 , characterized in that

the shoulder (9) and/or conical extension (29) on the external surface of the body (2) of the anchor (1) features permanent sufficiently created deformation after sliding of the anchor (1 , 1a, 1 b, 1c, d) into the anchoring hole (15).

10. The anchor assembly* pursuant to the claim 1 , characterized in that

the individual parts of the anchor assembly are made of non-metallic materials or from metal stainless materials and from metal materials, which have surface anti-corrosion treatment.

11. The mounting jig for adjustment of the anchor assembly pursuant to the claim 1 or any of the previous claims 1 - 7 characterized in that

it includes a solid case (12), ended with a collet (13), and in the solid case (12) a movable distancing pin (14) is situated.

12. The installation tool for adjustment of the anchor assembly pursuant to the claim 1 or any of the previous claims 1 - 7 characterized in that

it includes a handle (20), which is followed with a thread part (21) that bears the adjustable stop (22), and , the thread part (21) is followed with a driver (23) with longitudinal protrusions (24), whereas the installation tool (19) is ended with a guiding pin (25), which is replaceable as an advantage.

Description:
Anchor assembly of thermally insulating building contact and contactless system and mounting jig and installation tool for adjustment of anchor assembly

Technical Field

The invention concerns the anchoring assembly for thermally insulating building contact and contactless system, which includes the building structure and the building insulation, between which there is an air gap in the contactless system, in which gluing targets are formed, and it also includes the anchor made of a netting of metallic or non-metallic material, and is formed in the form of a tubular coil or spiral. The anchor is inserted into the anchoring hole from the external side of the building insulation and through the building insulation up to the building structure, and then the anchor in the anchoring hole is filled with an expansion filling material.

The invention also concerns the mounting jig for adjustment of the anchor assembly.

The invention also concerns the installation tool for adjustment of the anchor assembly.

Background of the Invention

The technical solution concerns especially safe anchoring of thermally insulating layers of varied composition without or with the air gap between tHe layers and the building struc'ture The building structure can be formed from a wide scale of the building materials as well as a combination of such materials, whiclV can be separated with air gaps.

Nowadays, rieariy exclusively plastic dowels and/or plastic dowels with metal reinforcement pin are used for anchoring ' thermally insulating systems into the structure. The disadvantage of these dowels is, among other things, that they create undesired thermal bridges. Thermal bridges are even more important in case of disc dowels with a reinforcement steel pin. The new generation of disc anchors/dowels already eliminates the creation of thermal bridges; however at the expense of higher prices and higher labour demands during the installation.

The disadvantage of disc dowels of a varied type is also the fact that the insulating material/ through which the cylindrical part of the dowel goes, is 'not firmly connected with the dowel, it cases the possibility of vibrations of thermally-insulating layers by the impact of wind, even if the layers are not in certain parts of the building structure and/or its bigger surface firmly connected with the building structure by gluing. Whereas this loss of cohesion of the thermally insulating system can result from various reasons: by failure to comply with the technological discipline, by the application of poor quality glues in violation of the applicable standards or by the change of the conditions of the surface of the building structure, for example humidity. This situation can become crucial in case of conditions, which precede the destruction of the insulating layers due to the aforesaid reasons. Even this shortcoming is partially eliminated by the last generation of disc dowels with the use of different modifications. However, it is at the expense of higher costs and higher labour demands during the installation.

A serious shortcoming of disc anchors is the inability of the dowels to achieve the required strength of anchoring. In practice it is not possible to count, as a default, with homogeneity of the surface of the building structure, into which the thermal insulation shall be anchored. Depending on the nature of the material, of which it is made, joints, cracks, cavities, etc. can appear in it. '

An example cain be a bricked wall or the use of hollow shaped bricks. In these cases, it is not possible to count on the correct function of the anchor. It is not possible to estimate exactly either what is the number of such non-functioning anchors in the system to ensure safety of the anchoring, because drilling of the anchoring holes takes place after gluing the insulating material on the uilding structure and, therefore, it is realized virtually at random.

Disc anchors, which are used when anchoring the thermally insulating layers, are only designed for stress by the force of wind, which causes underpressure, which tries to pull away (tear away) the insulating material from the building structure primarily with forces that are vertical to the building structure. These anchors are not able to transfer the forces in Bend, shear or combined stress. The applicable standards and regulations describe and determine the role of disc anchors as a way of additional anchoring of thermal insulations. Additional in the sense that the main role in creating the hold-down force between the building structure and the insulating material is taken over exclusively by the glue applied on the insulating material and located on the building structure. In case of any loss of the cohesion of the glue with the building structure, it is not possible to count on the disc dowel taking over the task of holding the thermally insulating layers on the building structure.

The destruction of the thermally insulating layers, which tend to occur, is caused primarily by the loss of cohesion of the gluing layer with the building structure. These cases absolutely prevail over the cases when the destruction occurs by tear-off of the insulating material from the glue due to the effect of forces caused by wind. The current known solutions of chemical anchors are based on a similar or equal principle of the chemical anchor with various modifications of shapes of bodies of anchors. However, all solutions of this type use the reinforcement steel item of a varied shape and place as the load-bearing item. However, in case of anchoring thermally insulating systems, the use of reinforcement steel and also other items slid into the anchor itself is undesired because it results in the creation of unsuitable thermal bridges. Another considerable disadvantage for the use of these anchors in the area of thermally insulating but also other systems is the time demand for their installation and their rather high price. For example, the anchor itself consists of an external grip and/or case, into which the liquid mass, mainly a two-component one, which can flow also into the cavities of the building structure, is dosed. After inserting the load-bearing reinforcement anchoring, primarily a steel item, the liquid filling hardens. Such created connection usually features high strength, which often exceeds the strength of the building structure.

The disadvantage of disc anchors is the creation of thermal bridges. If it is necessary to avoid the occurrence of the creation of thermal bridges, the head of the disc anchor shall be embedded into the insulating material. Technically, this matter is solved by the creatioii of a recess into the insulating material and the consequent application of the anchor so that the head of the disc anchor rests on the bottom of the recess. Consequently the space, which was formed above the head of the disc anchor is sealed by gluing a ring or a place of the insulating material of the relevant thickness, so that it does not exceed the external size of the anchored insulating material. This solution increases the labour demands of the creation of the anchoring connection; it represents a time loss- ¾nd can violate the strength of the insulating layer.

CZ 290 305 (1996) describes a distance piece for the building purposes made of a tubular item in the shape of a coil, produced from metallic or non-metallic material with loops or perforations along the whole surface, and filled with a filling material inside and outside of the'tubular item.

Another improvement of this solution is represented by CZ PV 2010 - 300 (2010), which introduces the anchor for thermally insulating building systems and its anchoring. The body of the anchor is made of a similar material in the shape of a spatial spiral, which is filled, both outside and inside, with a filling material, so that the anchoring with the use of the filling material is spread within a wider space. Summary of the Invention

The said disadvantages are eliminated or considerably limited for the anchoring assembly pursuant to this invention, the subject matter of which consists in the fact that the anchoring connection is formed from a self-supporting anchor without inner reinforcement pins, the body of which is made of metallic or non-metallic netting in the form of a tubular coil or space spiral, and is provided with at least one stud and/or recessing item, the external. maximum dimension Φζ vertical to the longitudinal axis of the body is always bigger than the external maximum dimension Φί of the body vertical to the longitudinal axis of the body. The anchor assembly hereunder includes an expansion filling material, which fills, after getting hardened: the body of the anchor outside and inside or, as the case may be, the inside of the coil or space spiral of the body, the surroundings of the screwing and/or recessing item, all free space in the anchoring hole and slots in the building insulation formed after the penetration of the screwing and/or recessing item into the building insulation.

The main advantage of this invention is -increasing the holding-down ability of the anchored building insulation to the body of the anchor and, thereby, increasing the required strength for pulling out the anchored building insulation from the body of the anchor, and especially using the anchoring connection also for extremely stressed building insulating systems and for bigger thicknesses of the building insulations, which were increased in the recent years from the value of 50 mm - 70 mm to the value of 150 and more mm. Strong, non-detachable, reliable and safe connection of the building insulation with the body of the anchor is reflected in high resistance of the building insulation to tearing away from the body of the anchor by alternating forces, e.g. in case of vibrations of the building insulation due to the effects of the forces of wind. The anchoring system pursuant to this invention complies with the requirements for increased demands of l ad of the insulating systems due to the effect of climatic changes and the requirements for anchoring of the insulating layers, i.e. mounting and connecting of unusual, new composition. The anchoring system pursuant to this invention increases the service-life of the thermally insulating systems in the building industry. The anchor is self-supporting and it does not require any additional inner metal reinforcement items. Metal or plastic netting is an available material, easy to process, which fully complies with the type of anchoring with the expansion filling material. The netting is easy to process into a tubular coil or space spiral. The screwing and/or recessing item operates in the surfaces outside of the body of the anchor in the building insulation or, as the case may be, in the building structure as another structural item for strengthening and anchoring. The screwing and/or recessing item on the body of the anchor with at least one cutting edge and/or cutting surface contributes to increasing the force required for pulling out of the building insulation from the body of the anchor, whereby it increases safety of the anchoring assembly in the insulating systems. The penetration of cutting parts of the screwing and/or recessing item is regardful of the used building insulation and the holes created in this way as marks left behind by cutting edges or surfaces are consequently filled with the expansion material, whereby the strength of the building insulation in the place of the installation of the anchor is restored. Different types and shapes of the screwing and/or recessing item on the body of the anchor respect the requirements put on the anchoring of various types and thicknesses of the building insulations. The anchoring connection, made of an anchor, screwing and/or recessing item on the body of the anchor and the expansion filling material, increases safety of mounting of the building insulation onto the building structure a ' nd, furthermore, the anchoring connection is also suitable for an eroded building structure or, as the case may be, for a building structure With inner holes and cavities, which are reliably filled with the expansion filling material. n the other side, this anchoring connection increases safety of anchoring of the building insulation also by increasing the holding-down force by means of the screwing and/or recessing item.

It is advantageous when the body of the anchor is equipped with at least one screwing and/or recessing item on one or both of its ends or its end parts or in their close vicinity, which represents the most suitable location of these items, because the end parts of the body of the anchor facing the ; building insulation or, on the contrary, the building structure shall carry an increased load. However, screwing and/or recessing items may be situated along the whole length of the body.

It is also advantageous when each screwing item is selected from a group including, independently or in combination, a screwing module with blades, screwing ring, blades, load-bearing ring with blades. Each screwing item is equipped with at least one cutting edge and/or at least one cutting surface for the creation of an efficient screwing surface, which represents a screwing surface or a sum of projections of screwing surfaces to a plane vertical to the longitudinal axis of the body of the anchor.

It is also advantageous, when the recessing item is selected from a group, including independently or in combination, a cut segment, rim, shoulder, shim, conical extension whereas each recessing item is equipped with at least one recessing edge and/or at least one recessing surface, for the creation of efficient recessing surface, which represents a surface or a sum of projections of the recessing surfaces to a plane vertical to the longitudinal axis of the body. Each screwing item and/or recessing item is located inside the building insulation or, as the case may be, in or behind the building or ceiling structure.

The structure of the screwing item and/or recessing item achieves optimum efficient screwing and/or recessing surface for various used building insulations. In case of solid building insulations, it is suitable to use a bigger number of smaller screwing items to achieve the efficient screwing surface. In case of less strong building insulations, a smaller number of screwing items with a larger surface is sufficient for achieving the efficient screwing surface. For achieving the efficient recessing surface, the type of the material used for the building insulation is crucial. In case of recessing efficient surfaces, it is important to achieve the highest possible ratio of Φζ to Φί, i.e. the ratio of the maximum outer dimension of the recessing surface to the maximum outer dimension of the body of the anchor. Jhe maximum outer dimension is the diameter in a majority of cases. When the screwing item and/or recessing item is located inside the building insulation, the expansion filling material encases all structural items of the anchoring connection, whereby it limits access of water or air humidity to the parts of the connection and it also positively influences the limitation of the creation of the thermal bridge.

It is also advantageous when the anchor is realized as a screwing anchor, which is formed with a combination with an anchor with a rim and a cap screwing module, or a combination of the body of the anchor firmly connected with screwing module, or from the body of the anchor ended with blades, or, as the case may be, from the body of the anchor, provided with a permanent deformation, i.e. shoulder or conical extension.

This screwing anchor does not require any reinforcement structural items, which are nowadays used primarily from metal materials, which can cause the occurrence of thermal bridges. The structure of this screwing anchor with screwing items is suitable especially for bigger thicknesses of the building insulations. Due to its principle of anchoring, a majority of still normally used disc anchors with the steel reinforcement pin is not able to ensure safe securing of the building insulation on the building structure. ; ' ;i ' :

The screwing item and/or recessing item can be formed as one integral unit with the anchor before, at or even after it is inserted into the anchoring hole or as an independent cap or put-on item.

It is also advantageous when the shoulder and/or conical extension on the external surface of the body of the anchor feature a permanent sufficiently formed deformation for sliding the anchor into the anchoring hole. The system of the integral anchor or the anchor made of several items enables variability when choosing the anchoring system of the particular insulating layers. This variability e.g. enables also sufficient restoration and anchoring with the anchoring system pursuant to this invention, for already realized but very damaged thermal insulations with insufficient thickness, where there is a threat of destruction. During the restoration of this damaged system, it is possible to use the anchoring system pursuant to this patent, which has the task to realize additional anchoring, i.e. restore the function of the original thermally insulating layers, and the second part of the anchoring system pursuant to this invention ensures sufficient anchoring of additional thermally insulating layers.

At the same time, it is advantageous when the anchor is slid into the anchoring hole through the building insulation up to the anchoring hole in the building structure, and the screwing and/or recessing items are located in the building insulation or, as the case may be, even behind the building structure. The following parameters are identified in advance with an advantage pursuant to thickness and type of the material of the building insulation. .

The distance between the outer surface of the building insulation and the nearest faced point of the screwing' item and/or recessing item is marked as parameter d. This parameter d is identified by the designer pursuant to the technological regulation of the manufacturer of the anchoring system. This parameter is chosen so as to avoid or prevent from the occurrence of the thermal bridge of the building insulations. This parameter can change with a different thickness and it is usually increased with the thickness of the building insulations.

Another parameter is marked as h, which is the distance between the most distant point of the screwing and/or recessing item from the external surface of the building insulation. This parameter is established by used type of the screwing item. Therefore, screwing items with the smallest value of this parameter are used for thinner building insulation. .

Another selected parameter is marked as L and it represents the depth of inserting of the body of the anchor into the building insulation. By using the screwing or recessing module, the value of the parameter L is decreased; however, the force necessary for pulling out of the building insulation from the body of the anchor is increased in a major way.

Furthermore, it is advantageous when individual parts of the anchor assembly are made of non-metallic materials or metal stainless materials or metal materials, which have anti-corrosion surface treatment. Filling the anchoring hole with the expansion filling material results in the fact that this material encases all these structural items of the anchoring system, whereby it prevents from penetration of air humidity or water to the used metal parts with anti-corrosion treatment and from their possible corrosion.

It is advantageous for the adjustment of the anchor assembly, specifically for the creation of the recessing items, as for example a shoulder or conical extension, when a mounting jig is used, which includes a solid case, ended with a collet, and in the solid case a movable distance pin is situated for the adjustment of the anchor slid into the building insulation, into the building structure or into the ceiling structure. The mounting jig is usually used during the installation in the horizontal insulation of the ceiling structures, where by the creation of an additional permanent deformation on the anchor, which was slid into or above the building structure through the screwing item in the building insulation, and in this position it was then fixed still before filling the anchor with the expansion filling material. This procedure enables, before the permanent fixation of the anchors, to level the insulated surface with the expansion filling material along the whole surface of the ceiling structure.

For the adjustment of the anchoring assembly, it is advantageous to use the installation tool, which includes a handle, which' is followed with a threaded part that has an adjustable stop, and the threaded part is followed with a driver with longitudinal protrusions, whereas the installation tool is ended with a guiding pin, preferably replaceable. The use of the installation tool is unavoidable for the compliance with the required parameter d established by the project, i.e. embedding the anchor into the thermal insulation at a particular depth, which prevents from the occurrence of a thermal bridge. The use of the installation tool is also necessary for correct location of the screwing and recessing" item in the building insulation.

The proposed solution of the anchoring connections for safe anchoring 1 of the building insulations in the contact and contactless way complies with the requirements put on this type of anchoring. In the structure, it does not cause the creation of thermal bridges. The use of the anchoring system pursuant to this invention is not time demanding and comparable with other anchoring items used in the area of anchoring of the building insulations.

The advantage of the anchoring system is its variability and safety of the anchoring connections' which is achieved with its use. By the composition of various items of this system, the optimum required anchoring effect is always obtained. With the use of it, it is possible to respond to various materials, from which the insulating layers are formed, to their thickness, type of load, weight of the insulating layers or position of the insulating layers. Even the use of the body of the anchor with the created rim considerably influences the size of the force required for pulling out of the insulating material in the direction from the building structure. With the use of the screwing parts of the system, it is possible to perfectly meet the requirement that the anchor does not create, the undesired thermal bridge. The anchoring system pursuant to this invention connects in itself all required properties for anchoring the insulating systems and it integrates the best properties of the anchoring items, which are used in this area. The easy-to-produce parts of the systems enable simpler installation of the insulating systems also in other positions that it is usual, i.e. in the horizontal position. The system of creation of the permanent deformation with the mounting jig pursuant to this invention, after sliding of the anchor to the definitive position in the anchoring hole, enables, after securing with the cap screwing part and/or with the use of the screwing anchor, to stabilize the ' position of the building insulation with respect to the building structure in the required distance from the building structure, e.g. the ceiling insulation, without the prior fixation of the insulating material with glue or vice versa. It results in savings of costs of the glue and in time savings. Inserting or sliding in of the body of the anchor is realized with the use of the installation tool pursuant to this invention, which secures inserting of the body of the anchor into the anchoring hole. Therewith it prevents from incorrect inserting of the body of the anchor by forced installation of the body of the anchor into the' anchoring hole and its resulting deformation. The use of this installation tool eliminates the possibility of incorrect or insufficient sliding of the anchor into the anchoring hole at its full length.

One of the main features of this system is the provision of control over the quality of the performed operations in anchoring of the building insulations to the construction supervisor or to another person that is interested in the correct realization of all steps of the installation. With its adjustable or replaceable part, the installation tool repeatedly secures the required inserting of the body of the anchor into the building insulation even during inserting the body of the anchor, whereby it ensures avoiding of the creation of the thermal bridge. The cylindrical part of the installation tool has adjustable length and is replaceable so that it could consider the specific length of the applied anchors.

Overview of Figures in Drawings

The invention is described in detail hereinbelow in the not limiting exemplary illustrations and it is explained in the enclosed drawings 1 - 36. The anchor with ' cut segments and not illustrated filling is displayed in Fig. 1 and 2.

Fig. 1 on the left displays a front view of the anchor with four cut segments and on the right a side-view, of this anchor is displayed.

Fig. 2 on the right illustrates the anchor with six cut segments in the front view and on the left this anchor is displayed in the side-view.

The anchor with a rim and not illustrated filling is illustrated in Figures 3 - 6, where in the left part of the figure a longitudinal section is displayed, in the right part there is a side-view, namely

Fig. 3 the basic body of the anchor with a rim,

Fig. 4 the body of the anchor with a rim, interrupted along the circumference,

Fig. 5 the body of the anchor with a rim and a flat shim,

Fig. 6 the body of the anchor with a rim and a shaped shim.

Fig. 7 illustrates, in longitudinal section, the anchor with a shoulder, without displayed filling, into which the installation tool is inserted.

Fig. 8 - 11 illustrate possible options of bodies of the screwing anchors without displayed fillings, on the left in the longitudinal section, on the right in the side-view, which illustrate σ :

Fig. 8 the body 'of the screwing anchor made of coil produced from netting, with rounded screwing module J

Fig. 9 the body of the anchor produced from space spiral, with flat screwing ring,

Fig. 10 the body of the screwing anchor with tubular body and cap screwing module, consisting of a load-bearing ring with installed blades,

Fig. 11 two bodies of the anchors located concentrically in each other, where the outer of which is provided with a rim and the inner body of the screwing anchor is firmly connected with the integrated ring carrying the blades, with detail A from the front view Fig. 11.

Fig. 12 and 13 represent bodies of the screwing anchor, without displayed fillings, with blades, where the body in the front view is displayed in the left part of the figure and in the side-view in the right part of the figure.

Fig. 12 illustrates the body of the screwing anchor with three integrated blades, and

Fig. 13 illustrates the body of the screwing anchor with one integrated blade. Fig. 14 -17 display alternative designs of the cap screwing modules. Fig. 14 illustrates in longitudinal section the body of the anchor with a rim, in combination with a cap screwing module in the left part of the figure, in the right part a side-view of the cap screwing module created with 6 blades.

Fig. 15 - 17 illustrate a detail of a cap screwing module, in the bottom part in the horizontal projection and in the top part in the front view, namely

Fig. 15 with four square blades,

Fig. 16 with four blades with leading edge, and

Fig. 17 with eight blades.

Fig. 18 and 19 display a cap screwing module with one and two blades with the same lead.

Fig. 18 illustrates a cap screwing module with one connected blade, in the left part in the front view, in the right part in the side-view,

Fig. 19 illustrates a cap screwing moduli with two blades, in the left part in the front view, in the right part in the side-view.

Fig. 20 illustrates the application of the body of the anchor with a rim with cap screwing module in the thermally insulating building structure.

Fig. 21 - 25 illustrate ' one exemplary realization of the layout of the body of the anchor with a rim in combination with a blade cap screwing module, and the technology of the anchoring procedure in the thermally insulating system in two steps.

Fig. 21 illustrates ' in vertical section a screwed-in cap screwing module in the building insulation in the first technological step, with detail B of the screwing module,

Fig. 22 displays the body of the anchor with a rim, slid into the cap screwing module in the anchoring hole.

Fig. 23 illustrates the first technological step of the previous operation and

Fig. 24 illustrates the- second technological step.

Fig. 25 illustrates an alternative in the transverse section in the left part of the figure a cap screwing module and in the right part a detailed shape of the driver of the installation tool.

The applications of the anchors pursuant to this invention in the thermally insulating ceiling system are illustrated in Fig. 26 - 31 , which display

Fig. 26 the anchor with a rim with cap screwing module,

Fig. 27 the anchor with a rim and a shaped shim,

Fig. 28 the anchor with a rim with cap screwing module, in anchoring into the ceiling structure with hollow spaces,

Fig. 29 the anchor with a rim and with a shoulder in combination with a cap screwing module, Fig. 30 the anchor with a rim and with conical extension in combination with a cap screwing module,

Fig. 31 the same design as in Fig. 27 with the use of reinforcements above the ceiling structure.

Fig. 32 illustrates a vertical section through the thermally insulating system with an anchor with a rim and a flat shim.

Fig. 33 and 34 display the action of forces in the created anchoring connection of the anchoring system, where the following is displayed:

Fig. 33 the state-of-the-art of the technology of anchoring of the building insulations and

Fig. 34 anchoring of the building insulations pursuant to this invention for the thermally-insulating building contactless system, and

Fig. 35 the state-of-the-art of the technology of anchoring of the building insulations and

Fig. 36 anchoring of the building insulations pursuant to this invention for the thermally-insulating building contact system.

Examples of Designs of the Invention

On the product of the body 2 of the anchor 1, primarily steel fabric or fabric from anti-corrosive steel is used and the diameter of the used wire on the product of the fabric and dimension of the loops of the fabric depend on the type and dimensions of the anchor 1. The body 2 of the anchor 1 can also be made of perforated metal sheet. '

The body 2 of the anchor 1 can also be produced from other flat, permanently deformable materials, even non-metallic, which can meet the condition of self- supporting capacity of the body 2 of the anchor 1, i.e. the ability to transfer the required forces in anchoring and also enable the penetration of the expandirig filling material 3 from its inner space in the direction of the wall of the anchoring hole 15.

The body 2 of the anchor 1 can be made of the aforesaid materials in the form of a tubular coil or space spiral or tube, on condition that it enables the penetration or filling with the expansion filling material 3 through the loops or perforations ' from its inner space to the wall of the anchoring hole†5 l . The body 2 of the anchor 1 can also

i

consist of several concentrically located coils or tubes.

The basic item of the anchoring assembly for thermally insulating, contact and contactless systems is the anchor JL The anchor 1 is provided, usually on one open end of the body 2, with cut opening segments 4 or opening rim 6 or, as the case may be, extended shoulder 9 or conical extension 29 or screwing module 10. Alternatively it concerns a screwing anchor Id with extending open end of the body 2.

The anchor 1 is always slid into the anchoring hole 15 with its untreated end. The other treated end of the body 2, after the application of the anchor 1 into the anchoring hole 15, is located slid into a certain depth of the insulation 16 of the building system, in certain distance from the external surface of the building insulation 16 or tightly levelled with it, " which is established by the project of the specific thermally-insulating or hydro-insulating, contact or contactless building system. This distance depends on specific conditions of the anchoring connection and can be in the order of mm. It ensures that the anchor 1 does not create undesired thermal bridges.

Therefore, of course, the biggest external dimension \ of the body 2 of the anchor i is always smaller than the external maximum dimension Φζ of the treated end or shoulder 9 of the anchor As, in a majority of bodies 2 of the anchors 1, it concerns tubular bodies 2 ' , ' coils or, as the case may be, space spiral, the maximum dimension Φζ of the screwing and/or recessing item, will be bigger than the external diameter 0t of the tubular coil or space spiral of the body 2. In case of use of various types of anchors 1 pursuant to this invention, with the exception of flat and shaped shims 7 for specific cases, it is not necessary to create holes, shoulders or recesses in advance for embedding the anchor 1 into the building insulation 16. During the application of the anchor t, the screwing part of the anchor 1 or screwing module 10 enters, with its cutting edge or cutting edges, into the material of the building insulation 16. After the expansion of the filling material 3, the cut slot, which was made by the penetration of the cutting edges into the building insulation 16, is filled with the said material. The expansion filling material 3 fills the whole space of the anchoring hole 15. Its overflow from the anchoring hole 15 is cut off after hardening or setting to the level with the anchored building insulation 16.

Exemplary designs of anchors la wit cut segments 4, displayed in Fig. 1 and 2, are described on the exemplary designs 1 and 2. The cut segments 4 represent a recessing item, with efficient recessing surface 34, which increases resistance of the anchoring system against pulling out of the building insulation 16 from the body 2 of the anchor la. The body 2 of the anchor l a is filled with a not illustrated filling material 3, which fixes the cut segments 4 in their particular position, whereby it ensures efficient function of the recessing surface 34; E a m p l e 1

(Fig. 1 )

The left part of Fig. 1 displays the anchor l a in the front view on one open end containing four cut segments 4, which represent recessing items and create the efficient recessing surface " 34· The anchor l a is made by cutting one of the open ends of the body 2_in the longitudinal direction, to various lengths x of cutting, with respect to the longitudinal axis 5 of the body 2. Bending of individual segments 4 is made under the angle g towards the longitudinal axis 5 of the body 2 of the anchor l a. Individual segments 4 have the angle a of bending, and length x of curvature, which is determined by the type of the not illustrated anchored building insulation 16. Generally it applies that the number of the segments 4 created by cutting into the body 2 of the anchor l a is determined by the outer diameter Χ of the body 2 of the anchor l a and the type of the building insulation 16.

Fig. 1 on the right displays a specific exemplary design of this anchor l a in the side-view, with four equal square cut segments 4, mutually in regular intervals. 1 Each segment 4_preserves its curvature within a considerable part of its length x, which is equal to the outer diameter Ot of winding of the coil of the body 2 of the anchor 1 a. Therefore, in this exemplary design the body 2 of the anchor l a is made of the coil, but it can be also made of a space spiral or tube, whereas the function of this anchor a is the same.

During the installation, the anchor l a is' slid into the not illustrated anchoring hole with pressure, specifically with the free ' end without cuts, and without the necessity of rotation of the anchor a into the depth of the anchoring hole 15. The depth of the anchoring hole is specified in advance pursuant to the required p oject, and is set-up on the not illustrated installation tool (see below Fig. 23, 24). After sliding the anchor l a into the not illustrated building insulation 16, the segments 4 are slid into the building insulation 16 pursuant to the project so as not to create a thermal bridge. It means that the free ends of the cut segments are usually 4 slid into the b'uilding insulation 16 in a certain distance from the external surface of the building insulation 16,

By changing the angle g of bending of the segments 4^ the biggest outer diameter Φζ of the segments 4 can be changed. The smaller the angle a is, the bigger the maximum outer diameter Φζ of the segments 4 is and the bigger the force for pulling out of the building insulation 16 from the body 2 of the anchor l a shall also be.

This type of the anchor a is relatively simple to be produced. E x a m p l e 2

(Fig. 2)

Fig. 2 on the right illustrates another type of the anchor la with six cut segments 4_in the front view and on the left this anchor la is displayed in the side- view.

This anchor la " is .made in the first step by cutting one open end of the cylindrical body 2 of the anchor la, in the longitudinal direction, pursuant to the type of the anchored building insulation 16. In the following production step, the free cut ends of the segments 4 are turned in plane that is vertical to the longitudinal axis 5 of the body of the anchor, in one direction (see Fig. 2 on the left), by deflecting from the longitudinal axis 5 of the body 2 of the anchor la, with the relevant radius. Generally it applies that the number of the segments 4 is established by the outer diameter Ot of the body 2 of the anchor la and the type of the anchored building insulation 16. This type has the blade segments 4, in regular mutual intervals, inclined tangentially with respect to the cylindrical body 2 of the anchor la.

During the installation, the anchor la is slid into not illustrated anchoring hole with its free end without cuts and turned to the left, in this specific exemplary design (Fig. 2 on the left). The rotation of this type df the anchor la is generally realized always in the direction pursuant to the orientation of turning of the segments 4. The anchor la is turned with the use of a driver (see Fig. 25) on the installation tool (see Fig. 23, 24) into the depth set-up on the installation tool.

The same applies to sliding the free ends of the blade segments 4 as in the previous case, i.e. the condition of absence of the creation of thermal bridges shall be complied with. For sliding of this type of the anchor la, it is sufficient to generate a smaller force when inserting it into the building insulation 16 than in the previous exemplary design. Fig-. 2 oh the left displays the point A, which is the most distant point from the longitudinal axis 5 of the body 2 of the anchor la. The bigger the distance of the point A will be from the longitudinal axis 5 of the body_2 of the anchor la, the bigger the force shall be generated to pull out the building insulation 16 from the anchor la after the creation of the anchoring connection.

The alternative type of the anchor l b with a rim 6 and the not illustrated filling is illustrated in Figures 3 - 6. The rim 6 is opened in the direction from the longitudinal axis 5, so that its out£r maximum peripheral dimension, the diameter Φζ of the rim 6, is always bigger than outer maximum peripheral dimension, the diameter Φί of the body 2 of the anchor l b. The rim 6 is a recessing item, which creates the efficient recessing surface 34 of the anchor lb with a rim 6. The size of the force, which resists pulling out of the building insulation 16 from the body 2 of the anchor lb, is directly proportional to the diameter Φζ of the rim 6_and, at the same time, it depends on the ratio of the diameter Φζ of the rim 6_to the diameter Φί of the body 2 of the anchor l b, therefore also to the size of the efficient recessing surface 34.

E x a m p l e 3

(Fig. 3)

The alternative anchor lb with peripheral rounded rim 6 on one open end, by which the anchor lb is slid during anchoring into the building insulation 16 of the building layers, is displayed in Fig. 3, where in the left part of the figure the anchor lb is displayed in the longitudinal section, in the right part in the side-view. The rim 6 created on one side of the anchor is connected, not interrupted along the periphery of the anchor lb. Its biggest outer diameter Φζ on the open end of the rim 6 depends on the outer diameter 0t !df the body 2 of the anchor lb, type of the material used for the anchored insulation 16, arid the material, from which the anchor b is made. The creation of the rim 6 on the Body 2 of the anchor lb has a significant effect on the size of the force, which shall be generated for tearing off the building insulation 16 in the direction from the building structure 17, be that for the systems of contact or contactless thermal insulation.

This anchor l b is produced in dependence on the type of the material of the body 2 of the anchor IJb by pressing in special sequential tools or by the coiling itself, e.g. from a pre-shaped material into the required shape. In case of non-metallic materials of the body 2 of the anchor l b, it can also concern other types of the production, e.g. by hot forming etc. The type of the production of this anchor lb is fairly dependent on the size of the serial production.

E x a m p l e 4

(Fig. 4)

The alternative type of the anchor lb with body 2 of the anchor lb, on the open end for sliding into the building layers provided with an interrupted rim 6, is displayed in Fig. 4, on the left in the longitudinal section, on the right in the side-view. The rim 6 is also rounded in the transverse section with respect to the longitudinal axis 5; however, it is interrupted along the whole surface from the periphery up to the body 2 of the anchor lb, and' it creates six rectangular blades with radial layout. This version of the rim 6 of the body 2 of the anchor l b is suitable especially for the body 2 of the anchor lb, which is made of the material that does not enable to create the connected rim 6 by means of a permanent deformation, and of the anchors lb, the body 2 of which can be made of a several-fold spiral.

E x a m p l e 5

(Fig. 5)

Fig. 5 displays. in the left part the longitudinal section, on the right side-view of the anchor lb with rounded interrupted rim 6, where on the body 2 immediately before the rounded rim 6 a flat shim 7 is slid. In this case it can concern a combination of various materials used on the product of the body 2 of the anchor l b with a rim 6 and a flat distributing shim 7a. The annular distribution shim 7a can be manufactured from primarily thermally non-conductive materials so that it would not contribute to the creation of the thermal bridge. The dimensions of the distribution shim 7a, i.e. its outer diameter, inner diameter and its thickness are dependent on type of the anchored material and dimensions of the insulation 16 or, as the case may be, on other strength requirements. ~ ■

During the application, the body 2 of the anchor lb is slid into the anchoring hole together with the put-on distribution shim 7a before being filled with the filling material. The body 2 of the anchor l b shall be inserted into the anchoring hole so that the rim 6 on the body 2 of the anchor lb would press the flat distribution shim 7a to contact with the metal material. To slide the annular distribution shim 7a into the building insulation 16, a recess is made in the building insulation 16, which fills the whole remaining space of the recess after the filling material expands. Consequently the excessive expansion filling material is levelled (e.g. by cutting off) with the external plane of the building insulation 16. Therewith the creation of the thermal bridge is eliminated without additional gluing of the building insulation 16.

E x a m p l e 6

(Fig. 6)

The body of the anchor lb with a rim 6, on which a shaped shim 7b is put immediately before the rounded interrupted rim 6, is displayed in Fig. 6, on the left in the longitudinal section, on the right in the side-view.

The shaped shim 7b supported by the body 2 of the anchor lb can have a different shape and size pursuant to the required purpose. The shaped shim 7b in the exemplary design is made 1 with a suspension loop on the arm of the shape shim 7b. Therewith it is possible to create e.g. a "suspension" on the building structure with various types of application, that is suitable for connecting various objects or structure, e.g. advertisement boards for the objects, which already have external thermal insulation, and the jacket of the construction consists of the insulating layers. In case of objects with an internal thermal insulation, where the building insulation 16, primarily polystyrene, forms the . inner jacket, it is possible to attach, in this way, objects or structures with the anchor b directly to the building insulation 16. The use of this combination of the body 2 of the anchor l b with the shaped shim 7b of a varied type is very advantageous for the building structures 17, where for example the inner partition walls are from polystyrene, or for the layers, where polystyrene or another building insulation 16 with similar properties is used. The shaped shim 7b can also include various types of consoles pursuant to the purpose and type of the anchored subjects.

E x a m p l e 7

(Fig. 7)

Fig. 7 illustrates in longitudinal section the anchor 1c with a shoulder 9 on the body 2, without displayed filling. A mounting jig H ' s slid into the body 2 of the anchor 1 c.

The basic part of the' mounting jig H is " a solid case 12, ended with a collet 13. In the solid case 12, a movable distancing pin 14 is situated.

Fig. 7 schematically displays the creation of permanent additional deformation in the form of an external shoulder 9 on the body 2 of the anchor 1 c with the use of the mounting jig 11 This shoulder 9 is made primarily on the body 2 of the anchor 1 c, which is already slid into the not illustrated anchoring hole 15 with the objective to create or increase the hold-down force of the anchor 1 c.

At first, the mounting jig H is slid into the body 2 of the anchor 1 c so that the protrusions of the collet 13 are located in the place, where the permanent deformation of the body 2 of the anchor lc is to be created. With a blow of e.g. a hammer on the central distancing pin 1 of the mounting jig in the direction indicated with the arrow in Fig. 7, the collet 13 is extended, which will cause the extension and permanent deformation of the body 2 of the anchor 1_c in the required place. The depth of sliding of the mounting jig H into the body 2 of the anchor lc can be marked in advance on the solid case ' l^ of the mounting jig 11 After the termination of the impact of the force on the distancing pin 14, this pin is ; automatically, by pre-tensioning of the collet 13 on the cone of the distancing pin 14, returned to the initial position and the mounting jig H is pulled out of the body 2 of the anchor lc. The creation of the peripheral shoulder 9 with permanent deformation on the body 2 of the anchor lc has a safety or installation effect. With the use of the shoulder 9, the body 2 of the anchor 1c is secured in the required position and the force is increased, after the anchor lc is filled with the expansion material, which shall be generated to pull out the anchor 1c from the anchoring hole: 15. The central distancing pin 14 can be also pressed into the cone of the collet 13 manually or with a device, be that continually or with interruption.

Screwing anchors ld without displayed fillings 3, in various options, displayed in Fig. 8 - 11 , on the left in , the longitudinal section, on the right in the side-view, are in detail described in the following exemplary designs 8 - 1 1. The screwing items consist of additional screwing modules 10a in Fig. 8 and 9, and a cap screwing module IQb in Fig. 10. The screwing item in Fig. 11 represents a slid-in screwing anchor Id on the body 2 of the anchor Ί . AN " these screwing modules create efficient screwing surface 33 that is suitable for the building insulation 6 with higher strength.

E x a m p l e 8

(Fig. 8)

Fig. 8 displays a screwing anchor Id consisting of the body 2 of the anchor Id and additional screwing module 10a. The screwing anchor Id consists of a permanent, fixed connection, whic cannot be dismantled, of the additional screwing module 10a and the body 2 in the 'shape of the coil or space spiral from the material, which is permanently deformable, sufficiently strong for the required strength of anchoring and can also be porous or includes holes enabling overflow of the expansion filling of the body 2 of the screwing anchor d from its inner space in the direction of the wall of the anchoring hole. This type of the screwing anchor'ld is suitable for the cases, when it is not possible technologically to create the rim with screwing blades directly from the material, from which the body of the anchor is made.

E x a m p I e 9

(Fig. 9)

Fig. 9 displays the body 2 of the screwing anchor Id, produced from a spatial multiple spiral, with additional screwing module 10a. The multiple spiral creates, by means of permanent, sufficiently strong connection with additional screwing module 10a, which cannot be disrriantled, the body 2 of the screwing anchor Id. The creation of screwing blades directly on the body 2 of the anchor id consisting of the multiple space spiral can be problematic in terms of production. Therefore, the creation of the screwing anchor Id with the use of the additional screwing module 10a that is firmly connected with the multiple spiral solves this problem. The material of the additional screwing module 10a and the material of the body 2 of the screwing anchor d need not be equal but both materials shall enable the creation of a fixed connection, e.g. by welding, gluing etc.

E a m p l e 10

(Fig. 10)

Fig. 10 displays the screwing anchor Id with body 2 in the tubular shape with a rim 6 and a cap screwing module 10b, e.g. consisting of a load-bearing ring 18 with installed blades. It is an example of the use of the body 2 of the anchor l b with a rim 6, where a cap screwing module 10b is put on the body 2 of the anchor l b with a rim 6. On the body 2 of the anchor lb, a peripheral uninterrupted or interrupted rim 6 is created on one side. By sliding of the body 2 into the screwing module 10b, this rests on the rim 6 of the anchor lb, whereby the functionally screwing anchor Id is created. Then this assembly is inserted into the anchoring hole. By the following filling of the screwing anchor Id with the expanding expansion material 3, the anchoring connection is created with high ability to contain the forces impacting in the direction of tearing the building insulation 16 away from the building structure V7. !

E x a m p l e 11 ;

(Fig. 11)

As it is evident in Fig. 11 , the screwing anchor Id is created from two concentrically located bodies 2a, 2b, where the external body 2a is provided with a rim 6, and the internal body 2b that is firmly connected with the additional screwing module 10a, in this case e.g. created by the integrated ring carrying the blades. In this case, therefore, two concentrically located bodies 2a, 2b and one screwing module 10a are used. The material of the bodies 2 can be preferably steel or stainless steel. The material of the screwing module 10a can be e.g. plastic.

The detail A from the longitudinal section in Fig. 11 illustrates the type of sliding of the screwing module 10a into the screwing anchor Id with a rim 6. During the application of this alternative screwing anchor Id into the not illustrated building insulation, the procedure is as follows: at first slide the outer body 2a with a rim 6 into the building insulation; consequently slide the inner body 2b integrally connected with the screwing module 10d. The inner body 2b with the screwing module 10 shall be secured in the required position by screwing into the building insulation in the required depth. The possible use of the concentric location of two or, as the case may be, more bodies 2a, 2b is suitable for extremely demanded anchoring connections, where the effect of rather big forces is expected. The mutual position of both bodies 2a, 2b is identified by the use of the applicable screwing module 10a, which also performs the distance role and maintains. the distance of both bodies 2a, 2b so that the condition of penetration of the filling material is met.

E a m p l e 12

(Fig. 12)

Fig. 12 represents the body of the screwing anchor Id with three integrated blades, without displayed filling material 3, where in the left part of the figure the body 2 is displayed in the front view, and in the right part of the figure it is in the side-view. The screwing anchor d' is made of steel or another fabric enabling its permanent deformation to the required shape of the body 2 of the screwing anchor Id and its screwing blades. Three screwing blades in the mutual interval of 120 ° are made by simple cutting of one free end of the body 2 and rotation of the blades at a particular angle β, whereby the screwing anchor Id with three blades is created: This screwing anchor Id is simple to produce and its use with the required effect is simple and efficient. It does not require any modification of the drilled anchoring hole 15 in the building insulation 16 that is not illustrated. It is used for anchoring primarily polystyrene building insulations 16 or building insulations with similar properties.

The number of the screwing blades, their angle of rotation β, outer diameter Φζ of the screwing blades and the width xl of the screwing parts of the body 2 of the screwing anchor Id is established by the material of the anchored building insulation 16, its thickness, required' length of drilled bore of the body 2 of the screwing anchor Id into the building insulation 16 with the required forces impacting in the direction of tearing the building insulation 16 from the building structure 17. The leading - cutting edges of the screwing blades can be modified to achieve easier penetration through the building insulation 16 " during the production of the body 2 of the screwing anchor 1d.

E x a m p l e 13

(Fig. 13)

Fig. 13 represents the body 2 of the screwing anchor IcLwith one integrated blade, creating the ' screwing module 10d, Without displayed filling material 3, where the left part of the figure displays the body 2 in the front view and the right part of the figure in the side-view. The body 2 of the screwing anchor Id with one integrated blade is made of the material, which enables the creation of an rim 6 on the body 2 of this anchor Id Consequently, the rim 6 is permanently deformed in the production into the shape of a simple thread. After inserting the screwing anchor Id into the drilled anchoring hole 15 in the building insulation 16. with the use of a simple thread of the screwing anchor Id, and its rotation in the relevant direction pursuant to the sense of the helical line, the screwing anchor Id is screwed into the required depth in the building insulation 16. The outer diameter Φζ of the rim 6 and the rise s of its blades are established by the material of the anchored building insulation 16, its thickness, required length of drilled bore of the body 2 of the screwing anchor Id into the building insulation 16 with the required forces impacting in the direction of tearing the building insulation 16 away from the building structure 1_7. To ensure an easier penetration through the building insulation 16, the leading cutting edge can be modified during the j production of the body 2 of this screwing anchor Id.

Alternative designs of details of cap screwing modules are displayed in Fig. 14 - 17, in bottom part of the figures 15 - 17 in the horizontal projection and in the top part in the front view. The cap screwing modules 10d, 10f, 10q, 10e have virtually the same screwing blades in radial arrangement in regular intervals, which enable to bore the screwing module 10d, iOf, 10g, 10e into the building insulation 16. The number of blades, their turning and their shape always result from the requirement for anchoring a specific building insulatio " n 16 and its physical and strength properties.

The following shall apply to these alternative designs: by means of the

^ expanding expansion filling material 3 of the- screwing anchor Id, which gets to the blades through the cUts, which are made by the blades of the cap screwing modules 10d, 10f, 10g, lOe by their recessing during screwing, the cap screwing module IOf is connected with the building insulation 16. The strength of the connection is increased and, at the same time, the creation of the possible thermal bridge is limited.

^ The blades of the screwing module lOd, IOf, lOg., lOe are usually integrally connected with the load-bearing ring 18 and they can be made of the same material or, as the case may be, it can concern a combination of various materials of the load- bearing ring 8 and the blades. It is advantageous to use the fully-plastic design of the screwing module lOd, IOf, lOg., lOe with the load-bearing ring 18.

The screwing module can be made of metallic and non-metallic materials,

35 which comply with the strength conditions for transfer of the relevant forces. In case when the screwing module is connected with the body of the anchor in a fixed way, that cannot be dismantled, the used material shall enable gluing, welding or connection with brass.

E x a m p l e 14

(Fig. 14)

One of possible specific designs of use of the plastic cap screwing module 10e with six sheet screwing blades in combination with the metal body 2 of the screwing anchor Id, made e.g. of a metal fabric, is illustrated in Fig. 14. The left part of the figure illustrates, in longitudinal section, the body 2 of the anchor lb with a rim 6, in combination with the cap screwing module lOe with six screwing blades. The right part of the figure displays a side-view of this cap screwing module 10e. The front leading edge is made partially of a direct line and partially of a curved shape; the rear edge is nearly a straight line. A : combination of a straight line and a curved edge create a possibility of easier penetration of the front cutting edge into the building insulation 16.

E x a m p l e 15

(Fig. 15)

Fig. 15 illustrates another possible creation of the cap screwing module lOf with four screwing blades, of which each has a rectangular surface with rounded edges. Between the neighbouring edges of the near blades, nearly the right angle is formed. This specific design is made of a perforated metal sheet and normal carbon steel or, as the case may : be, of stainless steel. The advantage of the solution is decreasing weight of this 1 screwing module lOf, and especially thorough connection of blades of the screwing module Of with not illustrated building insulation 16, into which it is screwed. A cap screwing module |0f can be produced with a waste-free type of production.

E x a m p l e 16

(Fig. 16)

Fig. 16 illustrates another alternative of realization of the cap screwing module 10g with four blades; each blade has a curved leading edge. Each blade has, in the side-view, the rear edge with a straight line edge and the curved front edge which are in vertical direction to each other. The near edges of the adjacent blades virtually have the right angle, wit the "difference with respect to the previous design that the blades occupy a smaller surface in the side section. The additional force, which is formed by the use of this type of the cap screwing module lOg, is smaller than in the previous exemplary design. It can be ..used with an advantage in the building insulations 16 with material of bigger density and strength than polystyrene, e.g. mineral wool.

E x a m p l e 17

(Fig. 17)

Fig. 17 illustrates another creation of the cap screwing module lOh with eight screwing blades. The blades with radial layout in the side-view from Fig. 17, nearly fill the surface between their smallest inner diameter and the biggest diameter. The near edges of the adjacent blades form an acute angle between themselves. In this case it is also possible to obtain this cap screwing module 10h in a waste-free way.

E x a m p I e 18

(Fig. 18) -

A cap screwing module 10d with one connected blade is illustrated in Fig. 18, specifically in the left part of the figure 18 in the front view and in the right part of the figure 18 in the side-view. The left part of the figure 18 illustrates the scheme of the helical line with one thread created on the cap screwing module lOd. The helical line creates one thread with the rise s and the outer diameter Φζ corresponding to the height of the rise of the ' thread. By a change of these parameters, various required effects are achieved. In case of this cap screwing module 10d, with the helical line with one thread, there is an advantage of creating a minimum cutting mark in the building insulation 16 on the entry of the bit into the building insulation 16; therefore, a smaller force is sufficient for screwing into the building insulation 16.

The rise s of the thread of this screwing module lOd is bigger in comparison with a double-thread version displayed on the following Fig. 19 and described in example 19. The outer diameter Φζ of the screwing blade in the shape of the helical line depends on the required parameters and requirements for the connection created by the relevant not illustrated screwing anchor 4d.

E x a m p I e 19

(Fig. 19)

A cap screwing module lOi with two blades, which have the same rise of the thread and, therefore, they have the outer diameter Φζ. The left part of Fig. 19 displays a cap screwing module lOi with two blades in the front view, in the right part in the side-view. It illustrates graphically how the double-thread version of blades in the shape of the helical line' decreases the thickness of the cap screwing module lOi in comparison with the screwing module lOd illustrated in Fig. 13 or 18, which has the screwing blade in the shape of the helical line with one thread. In the double-thread solution of the thread of the cap screwing module 10L thickness of this module is decreased to the value of one half of the rise s/2 of the thread, with respect to the previous exemplary design of the single-thread module lOd with one blade. This fact is used with an advantage in decreasing thickness of the screwing modules, in anchoring of thermal building insulations 16 with smaller thicknesses and also to eliminate the creation of undesired thermal bridges.

E a m p l e 20

(Fig. 20)

The application of the anchor 1b with a rim 6 and a cap screwing module

10b:

Fig. 20 displays, in section, the body of the anchor lb with a rim 6 slid into the cap screwing module 10b, in this case made of a metal sheet by pressing. The advantage of this solution is the identical radius of the rim of the body of the anchor b with the rim 6 with the radius of screwing module 10b. After sliding into screwing module 10b, which is already screwed into the building insulation 6 as tightly as possible, the anchor lb rests into the screwing module 10 and the depth d of sliding of the rim 6 of the body 2 of the anchor lb towards to the face side of the building insulation 16 is sufficient, despite the fact that the screwing module 10b is not screwed too deeply into the building insulation 16. The most distant point of the blade of the screwing module 10b from the external surface of the building insulation 16 represents the depth h. This the depth h ' is the distance, which is optimal with respect to the requirement for the limitation of the thermal bridge and, at the same time, it can be the maximum with respect to reducing the thickness of the building insulation 16, which generates resistance against pulling out of the anchor lb from the building insulation 6. This possibility of the combination of the body 2 of the anchor lb and the building insulation 16 is used especially in case of anchoring the building insulation 16 of smaller thicknesses, where too deep screwing of the screwing module 10b is not required but, at the same time, it is necessary' to comply with achieving the depth of sliding of the body 2 of the anchor lb into the building insulation 16. The distance d represents the distance between the external surface of the building insulation 16 and the closest faced point of the screwing item Ob. The depth L corresponds to the sliding of the body 2 of the anchor lb into the building insulation 16. E x a m p l e 21

(Fig. 21 , 22, 23, 24, 25)

The application of the installation tool 19 for the adjustment of the anchoring system.

One of possible exemplary applications of the anchor l b with a rim 6 in combination with the blade cap screwing module 10b is described hereinbelow, including a possible procedure of anchoring in the thermally insulating system in two steps.

Fig. 21 displays, in vertical section, a cap screwing module 10b screwed into the building insulation 16 in the first technological step and with detail B of this screwing module 10b. It displays a screwing module 10b screwed into the building insulation 16 before sliding the body 2 of the screwing anchor Id into the anchoring hole 15. The diameter of the anchoring hole 15 is equal to the inner diameter of the cap screwing module 0b due to the trouble-free sliding of the screwing anchor Id into the anchoring hole 15 through the hole of the cap screwing module 10b. That is Why the outer diameter of the load-bearing ring 18 is bigger than the diameter of the drilled anchoring hole 15. By screwing of the cap screwing module 10b into the building insulation 16, this is pressed by the load-bearing ting 18 of the blades of the module 10b in a way, which increase's the anchoring hole 15 where the cap screwing module 10b has already passed through the anchoring hole 15. Therefore, the load-bearing ring 18 of blades of the cap screwing module 10b can be designed in a different way in various types of the building insulations 16. To ensure stronger building insulation 16, a wedge shape is advantageous; it is displayed in Fig. 21 in the top right hand corner in detail B. When anchoring the building insulation 16 made of polystyrene, the resistance generated by the; building insulation 16 is insignificant and slight clamping and reinforcement of the position of the cap screwing module 10b of the building insulation 16 is welcomed! '

Fig. 22 in the right part displays the body 2 of the anchor 10b with a rim 6, creating the screwing anchor Id, when the body 2 is slid into the cap screwing module 10b in the anchoring hole 15. As the biggest outer diameter Φζ of the rim 6 of the anchor lb is bigger than outer diameter of the load-bearing ring 18 of the blades of the screwing module 10b, the building insulation 16 generates a slight resistance against sliding of the screwing anchor Id into the building insulation 16 in the area of the rim 6 of the body 2 of the screwing anchor Id. The rim 6 is designed so that it does not enter into the building insulation 16 under a negative angle; however, it does not concern resistance that would negatively influence time or quality of the installation. Fig. 23 illustrates the first technological step of the previous operation and Fig. 24 illustrates the following second technological step. Fig. 23 depicts inserting the cap screwing module 10b and follow-up screwing of this module 10b into the required position, i.e. depth d of the sliding module 10b into the building insulation 16. For the realization of this task, the installation tool 19 is used.

The installation tool 19 consists of a handle 20, which is followed with a threaded part 2Λ that carries an adjustable stop 22. The threaded part 2J. is followed with a driver 23 with longitudinal protrusions 24. The installation tool 9 is ended with a guiding pin 25, which can be replaced.

The installation tool 19 falls, with its driver 23 with longitudinal protrusions 24^ into the recess 26 in the loadrbearing ring 18 of the cap screwing module 10b. A cap screwing module 10b is slid through a guiding pin 25 of the installation tool 9 and is put with its recesses 26' on the part of the installation tool 19 with longitudinal protrusions 24. It enables to enclose a cap screwing module 10b on the face side of the drilled anchoring hole 15, and by slight pressure in the direction into the anchoring hole 15 and by turning in the direction of the rise of the blades screw the cap screwing module 10b into the required position, i.e. depth d of sliding of the module 10b into the building insulation 16. -

Fig. 24 displays compliance with the pre-determined depth h and depth h of sliding of the body 2 of the anchor 1 into the building insulation 16 that is pre-set on the installation tool 19. The body 2 of the anchor l b with the collar 6 is slid through the adjustable pin 25 of the installation tool 19 to the end position, where the rim 6 of the body 2 of the anchor lb rests on the driver 23 of the installation tool 19 with protrusions 24. Then the anchor l b is slid into the? anchoring hole 15 into the correct position, i.e. depth d of the sliding module 10b into the building insulation 16 determined by the project. Compliance with the dimension of the depth h of sliding determined by the project is enabled by the adjustable stop 22 on the installation tool 19. The installation tool 19 does not enable to slide it deeper or, as the case may be, it shows that the body 2 of the 'anchor 1 is not in the correct position yet and it needs to be corrected.

Fig. 25 illustrates an alternative design in the transverse section in the left part of the figure - a cap screwing module 10b in longitudinal section with displayed recesses 26 in the load-bearing ring 18.

The right part of Fig; 25 displays a part of the driver 23 of the installation tool 19, which falls with its part with the protrusions 24 into the recesses 26 of the cap screwing module 10b according to the figure 25 on the left. It generally applies to the installation tool 19, for any screwing anchor Id and cap screwing module 0b or, as the case may be, for any anchor l b with a rim 6, that the correct position, i.e. depth d of screwing of the cap screwing module 10b, is signalled with the set-up of the adjustable stop 22 on the installation tool 19, which rests on the face side of the building insulation 16 and will not enable further screwing of the cap screwing module 10b.

The required position, i.e. the depth d of sliding of the module 10 into the building insulation 16, is established by the parameters of the thermally insulating system and the type of thermal insulation of the contact or contactless system. The required position, i.e. depth d of sliding of the module 10b into the building insulation 16, shall be determined by the authorized person pursuant to the applicable technical conditions, subjected to the compliance with the applicable standards for contact or contactless thermally insulating systems.

As the used type and diameter of the cap screwing module 10b and also its position in the building insulation 16, i.e. the depth d of sliding of the module 10b into the building insulation 16 changes for different parameters of the thermally insulating system, the multi-functional installation tool 19 is equipped with adjustable 'and replaceable parts, which cover the whole range of used combinations of the screwing modules 10b and bodies 2 of the anchor 1 while respecting their various length and

20 - .

diameters. The adjustable and replaceable parts of the installation tool 19 are the adjustable stop 22 and the guiding pin 25. The replaceable part of the installation tool

19 is the driver 23. The application of the installation tool 19 also avoids incorrect location of the body 2 of the anchor l b with a rim 6 into the anchoring hole 15 and its

^ possible deformation, during which the required quality of the connection would not have to meet the required properties. It is one of the properties of the system, which is focused on safety anchoring of the thermally insulating layers with the possibility of inspection or self-regulation of quality of the installation.

^ Other alternatives of use of the screwing system and the mounting jig 11 of the anchors 1 pursuant to this invention in the thermally insulating ceiling system are illustrated in Fig. 26 - 31 , in the transverse section of the ceiling structure 17a, and they are described in the exemplary designs 22 - 27.

In all these anchoring systems pursuant to the invention, in case it is necessary to exclude the occurrence of the undesired thermal bridge, the anchors 1 are sunk into

35 the building insulation Ϊ6. The depth of sinking d of the anchor into the building insulation 16 is proportional to the thickness and type of the used building insulation 16. The value of the depth d, ' i.e. the distance between the external surface of the building insulation and the closest inclined point of the rim of the screwing item is identified by the project.

E x a m p I e 22

(Fig. 26)

Fig. 26 displays, in the transverse section, the application of the anchoring system when anchoring the building insulation 16 in the ceiling structure 17a. In the figure, the building insulation 16 is anchored with the use of the body 2 of the anchor l b with a rim 6Jn combination with the screwing module 10. The advantage of this type of anchoring, in comparison of the mostly used common disc anchor, is reliability of the anchoring connection. The body 2 of the anchor l b pursuant to this invention penetrates the load-bearing ceiling building structure 17a and it is not significant, if it becomes so in the not illustrated gap of the ceiling structure 17a or, as the case may be, if it concerns a part of the ceiling structure 17a from another material than wood or sandwich structure made of different materials, e.g. a porous material.

The procedure of the installation of the anchoring system starts by the creation of the installation gluing points 27 from cement mortar or expansion foam material in the air gap 32 on the ceiling structure 17a, which temporarily fix the building insulation 16 in the correct position. Consequently an anchoring hole 15 is drilled through the building insulation 16 up to building ceiling structure 17a. The application of the anchoring system can be used in the contact and contactless building layers. Depending on it, the type of realization of the installation gluing points 27 or another type of gluing used in the contact type of insulation of the buildings is selected. Consequently a cap screwing: module 10 is screwed into the anchoring hole 15 into the required position, i.e. depth d of sliding of the module 10b in the building insulation 16. The anchoring hole 15 is filled, after inserting the body 2 of the anchor l b with a rim 6 into the anchoring hole; 15, with the expansion filling material 3, usually foam.

The use of the' anchoring system with the cap screwing module 10 enables safe installation in this position for the insulating layers of bigger weight too.

E x a m p l e 23

(Fig. 27)

Fig. 27 displays the anchoring system pursuant to this invention for the installation of the ceiling insulating system 17. similar to the one in the previous exemplary design 22 displayed in Fig. 26 for the anchor l b with a rim 6, however with the difference, that instead of the- screwing module 10, the shaped shim 7b with a suspended hole is used in this case. This solution enables the installation or additional installation of the ceiling building insulation 1j3 on the ceiling structure 17a and it also enables the installation of the equipment of adequate weight, lights, audio or video equipment etc.

E a m p l e 24

(Fig. 28)

Fig. 28 illustrates, in the transverse section of the anchoring system, the anchor lb with a rim 6 and a cap screwing module 10, in anchoring into the ceiling structure 17a with hollow spaces, e.g. into the ceiling structure 17a consisting of beams 28 with inner cavities.

Anchoring of the ceiling thermally insulating system into the ceiling of this building structure 17a with the use of the current disc anchors is not safe with respect to the inability of expanding the anchoring parts of the disc dowel in the fixed anchoring hole 15. '

In case of the anchoring system according to the submitted invention, it is not important in what place of the beam 28 of the ceiling building structure 17a with hollow spaces the anchoring hole 15 is drilled, because the expanding properties of the filling material 3 ensure safe anchoring also in the places, where an anchoring hole 15 was possibly drilled in a place Of a cavity of this ceiling structure 17a. !

E x a m p l e 25

(Fig. 29)

Fig. 29 illustrates the anchoring system pursuant to the invention with an anchor lb with a rim 6 and with a shoulder 9 in combination with a cap screwing module 10b. This exemplary design represents the use of the creation of permanent deformation, i.e. shoulder 9, on the body 2 of the anchor l b with a rim 6 in the required place of the body 2 of the anchor l b.

In this case, contrary to Fig. 26, the procedure of the installation is as follows: Gluing points 27 are created in the minimum volume from the expansion filling material 3 on the ceiling structure 17a, the building insulation 16 is enclosed and anchoring holes 15 are drilled/After inserting the body 2 of the anchor lb with a rim 6 into the anchoring hole 15, a permanent deformation on the body 2 of the anchor l b is created in the form of a shoulder 9. Consequently, a cap screwing module 10b is screwed into the anchoring hole 15. Then the anchor b is filled with the expansion filling material 3. In the application, the anchoring connection creates permanent deformation on the body 2 of the anchor l b featuring the ability of transferring bigger forces in the axial direction.

In case of an additional need of anchoring another structure to the already thermally insulated ceiling, it is possible to use, in combination with the body 2 of the anchor IJb and the created permanent deformation in the form of a shoulder 9, also a shaped shim 7b, similarly to. Fig: 27.

E x a m p I e 26

10

(Fig. 30)

Fig. 30 illustrates the anchoring system with the anchor l b with a rim 6 and with a conical extension 29 in combination with a cap screwing module 10b. It concerns another possible type of the permanent deformation created on the body 2 of the anchor l b with a rim 6. A change of the shape of the permanent deformation, i.e. conical extension 29 at !the end of the body 2 of the anchor lb is achieved with a replacement of the collets 3 in the mounting tool ' 1 After sliding the anchor b into the anchoring hole 15, the end of the anchor lb, exceeding the ceiling building structure 17a, is shaped with the mounting tool H into the conical extension 29.

20

E x a m p l e 27

(Fig. 31)

Fig. 31 illustrates the anchoring system pursuant to this invention, in the same design as Fig. 29, with the difference, that above the ceiling structure 17a, building

^ reinforcements 30 are placed, which reinforce this building ceiling structure 17a and distribute the load on a bigger surface. The anchoring connection is created with the use of the anchor lb with a rim 6, the cap screwing module 10b, with the creation of the permanent deformation in the form of shoulder 9 bn the body 2 of the anchor lb, in the place, where the body goes beyond the building reinforcement 30. By filling it with

^ the expansion filling material 3, the installation of the anchoring system is completed.

This solution is suitable in case, when the ceiling structure 17a has not sufficient strength, additional thickness or, as the case may be, if from certain reasons, e.g. due to not enough strong or porous material of the ceiling structure 17a, it is not possible to attach the anchor lb with a rim 6.

35 E x a m p I e 28

(Fig. 32)

Fig. 32 illustrates a vertical section through the anchoring system pursuant to this invention, containing the anchor l b with a rim 6 and with a flat shim 7a. The building insulation 16, e.g. from mineral wool, is anchored to the building structure 17a. In this case it is not always possible to use the screwing module and, therefore, it is necessary, after drilling the anchoring hole 15 in the building insulation 16, to make a recess into the building insulation 16 too with the diameter and depth h pursuant to the dimensions of the used body 2 of the anchor l b and flat shim 7a. After inserting the body 2 of the anchor b with the flat shim 7a and filling the body 2 of the anchor l b with the expansion filling material 3, it is not necessary to blind the created recess with additional gluing of a ring into the building insulation 16 as it is nowadays in case of other anchors. In this case, the expanding filling material 3 of the body 2 of the anchor l b fills the whole volume of the anchoring hole 15, including the recess. After drying, the excessive filling material 3 is cut off to be level with the surface of the anchored building insulation 16. It is" advantageous in this case, if the flat shim 7a is made of a plastic material.

In the following specific designs 29, 30, 31 , 32 displayed in Fig. 33, 34, 35, 36 the direction of surface effect of forces F1 , F2, F3, F4, F5 in the anchoring system is displayed in waves; namely in the created anchoring connection, where the current state-of-the-art is clarified and discussed for the thermally-insulating building contactless system in Fig. 33 and the application of the anchoring system with an anchor l b with a rim 6 and a cap screwing module 10b in Fig. 34; and for the thermally-insulating building contact system in Fig. 35 the current state-of-the-art of anchoring of the building insulations and in Fig. 36 the anchoring of the building insulations pursuant to this invention.

E x a m p l e 29

(Fig. 33)

State-of-the-art for anchoring building insulations 16 for thermally insulating contactless system. ' " · -

Fig. 33 illustrates the type of the anchoring connection of the thermally insulating contactless system illustrated in the state-of-the-art. This figure displays the connection of the building insulation 16 with the building structure 7 pursuant to the state-of-the-art in the application of the current cylindrical anchor. The figure displays surface effect of forces F_l, F2, F3, F4, which contribute to holding the anchored building insulation 16 on the building structure 17. i

The force FJ. represents the force that is created by the expansion of the filling material 3 in the anchoring hole 5 in the building structure 17.

The force F2 represents the force that is created between the created gluing target 3J. from the filling material 3_and the building structure 17. ί

The force F3 is the force, which impacts between the gluing target 3J. created with the filling material 3 and the building insulation 16.

The force F4 is the force that is created by the expansion of the filling material 3 in the part of the anchor 1, which is slid into the building insulation 16.

A sum of forces Fl + F2 gives the size of the resulting force required for pulling of the anchor 1 from the building structure 17.

A sum of forces F3 + F4 gives the size of the resulting force, which is required for pulling out of the building insulation 16 from the body 2 of the anchor

E x a m p l e 30

(Fig. 34)

Anchoring building insulation 16 pursuant to the invention for the thermally insulating contactless system in case of the application of the anchor b with a rim 6 and a cap screwing module 10b pursuant to this invention is described hereinbelow.

Fig. 34 displays the anchoring system pursuant to this invention for the comparison of the state-of-the-art identified in the previous exemplary design and displayed in Fig. 33.

To pull out the anchor 1 from the building structure 17, the sum of forces j. + F2 is required as well as : in the previous exemplary design of the state-of-the-art.

In this system of anchoring pursuant to this invention, the force, which is required for pulling out of the building insulation 16 from the body 2 of the anchor 1, is basically identified, for all types of anchors, screwing anchors and screwing modules, by the sum of forces F3 + F4 + " F5, where F5 is the force, which contributes in this sum to the considerable increase of the resulting anchoring force.

The force F5 is geherated by the use of the anchors 1 pursuant to this invention, which are provided with a rim 6, cut segments 4, screwing anchors Id, screwing module 10b, shoulder 9, shaped shims 7 and conical extension 29. The size of force F5 increases the resulting force required for pulling out the building insulation 16 from the body 2 of the anchor 1 in a major way. The force F5 depends especially on two basic parameters, namely:

d recess - distance of the face of the anchor 1_from the external surface of the building insulation 16 and

\ maximum diameter of the round surface or maximum surface of non-circular shapes.

The recess d of the rim 6 of the anchor 1 shall be optimal with respect to the elimination of the risk of occurrence of the thermal bridge. The requirement for the recess d of the anchor into the building insulation 16 is to achieve the minimum depth but while respecting the condition of the thermal bridge. All anchors pursuant to this invention are suitable for the building insulation 16 of the thickness up to 80 mm, but they are also used for the insulations exceeding 80 mm in case of the expected higher load of the insulating layers.

In case of the building insulations 16 below 80 mm, it is necessary to comply with the condition of the smallest recess d of the anchor to avoid decreasing the force F5 by decreasing the thickness of the building insulation 16, which generates resistance against pulling out of the building insulation 16 from the anchor 1 provided with a rim 6 or a screwing module 10. The bigger the thickness of the recess d of the anchor into the building insulation 16 is, the smaller the force F4 is. Therefore, the force F4 is indirectly proportional to the size of the recess d of the anchor 1.

The force F4 is directly proportional to the depth L of sliding of the body of the anchor 1 into the building insulation 16. Therefore, it is necessary to optimize, in case of the building insulations below 80 mm, the recess d of the anchor 1 especially with respect to avoiding the thermal bridge and decreasing the force F4. It is the use of the screwing anchors 1 or screwing modules 10 that increases safety of anchoring of the building insulations 16, especially in case of smaller thicknesses of the building insulations 16.

The force F5 is determined by the sum of forces from individual surfaces, which are formed by the sum of surfaces that generate resistance to pulling of the building insulation 16 from the anchor 1. From the practical standpoint, these surfaces are mostly round but they can be also different, not round.

E.g. the following applies to virtually external round surfaces:

The force F5, which is maximized by the object of the submitted invention, for the effect of virtually external round surfaces of the anchor 1, is directly proportional to the value of maximum external dimensions Φζ of the screwing and/or recessing items, which represents the diameter of the circle circumscribed around the outline of the surface or surfaces generating resistance to pulling the building insulation 16 from the body 2 of the anchor

More specifically, in the aforesaid specific exemplary designs, Φζ represents the maximum diameter of the external round screwing and/or recessing items representing the circumscribed circle crossing the most distant points of the anchor 1 from the longitudinal axis 5 of the body 2 of the anchor 1, e.g. cut segments 4, rim 6, blades, screwing modules 10, round shims 7, 7a, shoulder 9 and conical extension 29.

The ratio Φζ to Ot is also important for the force F5. The force F5 is directly proportional to the ratio Φζ to Ot. The bigger this ratio is, the bigger the anchoring force F5 is.

In case of not-round surfaces, direct proportion applies between the force F5 and the sum of created not-round surfaces, which generate resistance to pulling out of the building insulation 16' from of the anchor 1, refer to e.g. the exemplary design of the shape shim 7b in example 6, Fig. 6.

E x a m p l e 31

(Fig. 35)

State-of-the-art for anchoring the building insulation 16 in case of the thermally insulating contact system.

Fig. 35 illustrates' the type of the anchoring connection of the thermally insulating contact system illustrated in the state-of-the-art. This figure displays the connection of the building insulation 16 with the building structure 17 pursuant to the state-of-the-art, in the application of the current cylindrical anchor. The building insulation 16 is glued to the building structure 17 with the use of e.g. a layer of the cement glue or expansion material 3. *

The anchoring corresponds to the previous exemplary design with the fact, that between the building structure 17 and building insulation 16, a consistent air gap is not created on purpose and because in the air gap 32 there are no gluing targets 31 but glue 35, the effect of the forces F2, F3 is ensured by the glue 35 on the basis of cement. ,

F1 represents the force that is created by the expansion of the filling material 3 in the anchoring hole 15 in the building structure 17.

F4 is the force that is created by the expansion of the filling material 3 in the part of the anchor 1, which is slid into the building insulation 16.

A sum of forces' Έ1 + F2 is required to pull the anchor 1. from the building structure 17. A sum of forces F3 + F4 is required to pull the building insulation 16 from the body 2 of the anchor 1.

E a m p l e 32

5

(Fig. 36)

Anchoring of the building insulation 16 in case of the thermally insulating contact system pursuant to the invention in the application of the anchor l b with a rim 6 and a cap screwing modulel Ob pursuant to this invention is described below.

Fig. 36 displays the anchoring system pursuant to this invention for comparison of the state-of-the-art identified in the previous exemplary design and displayed in Fig. 35.

To pull the anchor from the building structure 17, a sum of forces F1 + F2 is required as well as in the previous exemplary design the state-of-the-art.

The force, which is required for pulling out of the building insulation 16 from the body 2 of the anchor 1 is, in this system of anchoring pursuant to this invention, also for all types of anchors, screwing anchors and screwing modules, established by the sum of forces F3 + F4 + F5, where F5 is the force, which contributes, in this sum, to a considerable increase of the resulting anchoring force.

^ The relations applicable to the force F3, F4 and F5 identified in the previous exemplary design 30 are the same.

The tests of the anchoring systems pursuant to this invention performed in the long-term demonstrated high reliability of anchoring in the building insulation 16 of the building insulating systems, contact and contactless. This type of anchoring, in which the resultant of forces includes the force F5, is used on condition of a considerable

25 ~~ ' ■

load of the thermally insulating systems or connections in such a way, in which above- standard load is expected, it is also suitable in the cases when it concerns anchoring of more porous and less strong insulating materials. However, it is not in cases of external insulation of the buildings when the applicable standard strictly sets out

^ strength properties of the building insulations 16. " On the contrary, in case of anchoring of horizontally placed ceiling insulations, the use of the anchoring system pursuant to this invention is very advantageous.

The force F5, which is created by the use of the screwing modules 10 or screwing anchors Id, considerably increases the strength of the anchoring system and

^ the anchoring connectibh.

The anchoring system pursuant to this invention, thanks to the anchors pursuant to this invention, further increases favourable properties also by the fact, that e.g. the blades of the screwing ; anchor Id or the screwing module 10b are slid into the building insulation 16, so that they loose the contact with the external environment and so they do not create undesired thermal bridges. With the type of their installation by screwing into the building insulation 16, the screwing anchors Id and the screwing modules 10, 10a , 10b, 10c, lOd, lOe, lOf, lOg, lOh, lOh, lOi enable exact sliding of the anchor 1 pursuant to the requirement of the project.

E.g. in the specific exemplary design for contactless thermally insulating building system, displayed in Fig. 34, the anchor b with a rim 6 is displayed, on which the screwing module 10b is put on. In this case the body 2 of the anchor 1 has the outer diameter Ot equal to approximately 14 mm. In this case, Φζ corresponds to the maximum diameter of the cap screwing module 10b, which corresponds to the value of about 30 mm. Polystyrene of the type EPS 70 is used as the building insulation 16. If this building insulation 16 Has' the thickness of 60 mm, the optimum recess d will correspond to approximately 5 mm, and the length L of sliding of the rim 6 of the anchor will be 55 mm. The recess d depends on the climatic conditions, in which the anchoring is realized. This fact shall be considered by the designer in the preparation of the project documentation; ·

Industrial applicability

The anchoring system is designed for the building industry, especially for thermal insulation of external jackets of the buildings.

Related marks 1 anchor

1 a anchor 1a with cut segments 4

1b anchor 1b with a rim 6

1c anchor 1c with a shoulder 9

1d screwing anchor 1d

2 body 2 of the anchor 1

2 external body 2a of the anchor 1

2 internal body 2b of the anchor 1

3 filling material

4 cut segment

5 longitudinal axis

6 rim

7 shim

7a flat shim 7a

7b shaped shim 7b

9 shoulder 9 (on the body 2)

10 screwing module

10a additional screwing module 10a

10b cap screwing module 0b

0c screwing module 10c with 3 blades

I0d screwing module 10d with 1 blade

10e screwing module 10e with 6 blades

10f screwing module 10f with 4 square blades

10g screwing module 10g with 4 blades with leading edge

I0h screwing module 10h with 8 blades

10i screwing module 10i with 2 blades

11 mounting jig

12 case

13 collet

1 distancing pin

15 anchoring hole

16 building insulation

17 building structure

17 ceiling structure

17b vertical building structure' 18 load-bearing ring 18 of the screwing module

19 installation tool

20 handle

21 thread part

22 adjustable stop

23 driver

24 protrusions

25 guiding pjn

26 recess in the load-bearing ring

27 gluing body

28 beams

29 conical extension

30 building reinforcements

31 gluing target

32 air gap

33 screwing surface

34 recessing surface

35 glue

Φζ maximum external dimension Φζ of the screwing item and/or recessing item Ot maximum external dimension Φϊ of the body of the anchor

Φ 18 outer diameter Φ 18 of the load-bearing ring 18 of blades of the screwing module a angle a of inclination of the segments to the vertical axis of the body of the anchor, vertical to its longitudinal axis

β angle β of rotation of blades to the vertical axis of the body, vertical to its longitudinal axis

d recess d-distance d between the external surface of the building insulation and the closest inclined point of the screwing item

x length x of cut of the segments on the body of the anchor

x1 width x1 of the screwing blades

A the most distant point A of blade segments from the longitudinal axis of the body of the anchor

h the distance h is the distance between the most distant point of the screwing and/or recessing item from the external surface of the building insulation

L depth L of the sliding body of the anchor into the building insulation

F1 , F2, F3, F4, F5 surface strengths