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Title:
CABINET MOUNTING METHOD AND ARTICULATED JOINT MEANS FOR USE WITH THE METHOD
Document Type and Number:
WIPO Patent Application WO/1993/007780
Kind Code:
A1
Abstract:
The invention relates to a method for storing and mounting the body for a cabinet, furniture or the like, consisting of two sides (2, 3), top (1) and base (4), where adjacent end sections of said sides, top and base are provided with articulation devices (6, 7, 8, 11) to join the parts together. Said sides, top and base are arranged in transport or storage state such that said top and one of the sides (1, 2) lie parallel with said base and the other side (3, 4). The body is mounted by moving said two sides (2, 3), together with the top (1) and base (4), in mutually parallel relationship like a parallellogram until said two sides (2, 3) are vertical, whereafter at least one of the two sets of articulation devices (6, 8) situated diagonally in the body is releasably locked into position. The means for forming an articulated joint between adjacent end sections of the structural parts, e.g., sides, top and base of a body for a cabinet or the like, comprises a cup-shaped body (6; 7; 8) which is hinge-connected to an approximately L-shaped (8'), U-shaped (6') or stepped straight arm. The arm may be equipped with a rotatable tension pin adapted for engagement with a recess in the member.

Inventors:
FRIES BROR (SE)
NAKAMOTO YUSHO (SE)
Application Number:
PCT/NO1992/000177
Publication Date:
April 29, 1993
Filing Date:
October 21, 1992
Export Citation:
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Assignee:
GRORUD JERNVAREFAB AS (NO)
International Classes:
A47B43/00; E05D3/06; E05D5/08; E05D11/10; (IPC1-7): A47B43/00; E05D11/10
Foreign References:
US3829190A1974-08-13
SE421439B1981-12-21
US2132266A1938-10-04
US2725590A1955-12-06
DE2806735A11979-08-23
US0926367A1909-06-29
US1011584A1911-12-12
Download PDF:
Claims:
P a t e n t C l a i m s
1. A method for storing and mounting the body for a cabinet, furniture or the like consisting of two sides, a top and a base, c h a r a c t e r i z e d i n that adjacent end sections of the sides, top and base are provided with articulation devices to join the parts together, that said sides, top and base in transport or storage state are arranged such that said top and one of the sides lie parallel with said base and the other side, and that the body is mounted by moving said two sides, together with the top and base, in mutually parallel relationship like a parallelogram until said two sides are vertical, whereafter at least one of the two sets of articulation devices situated diagonally in the body is releasably locked into position.
2. A method as disclosed in claim 1, c h a r a c t e r i z e d i n that all of said articulation devices are locked into position.
3. A method as disclosed in claim 1 or 2, c h a r a c t e r i z e d i n that the body is provided with a total of at least four articulation devices.
4. A means for forming an articulated joint between adjacent end sections of structural parts, e.g., sides, top and base, in a body for a cabinet, furniture or the like, c h a r a c t e r i z e d b y a cupshaped body being hingconnected to an approximately Lshaped, Ushaped or stepped straight arm.
5. 5A means as disclosed in claim 4, c h a r a c t e r i z e d I n that the approximately Lshaped or stepped arm is equipped with a rotatable fixation pin adapted for engagement with a ledge in said member.*& 6.
6. A means as disclosed in claim 4 or 5, c h a r a c t e r i z e d i n that the approximately L shaped or stepped straight arm is hinged to the cupshaped body at the uppermost open section thereof.*& 7.
7. A means as disclosed in claim 4, c h a r a c t e r i z e d i n that said approximately L or Ushaped arm is equipped with a ledge adapted for engagement with a fixation pin rotatably mounted in said member.*& 8.
8. A means as disclosed in claim 4 or 7, c h a r a c t e r i z e d i n that said approximately L or Ushaped arm is rotatably hinged to the cupshaped body near the bottom thereof.*& 9.
9. A means as disclosed in claim 8, c h a r a c t e r i z e d i n that the ends of the arm rotating shaft each move within an oblong bearing slot in the cupshaped body during the movement of the arm between its outer positions.*& 10.
10. A means as disclosed in claim 9, c h a r a c t e r i z e d i n that the oblong bearing slot has straight sides and rounded ends, and that its width corresponds to the diameter of the rotating shaft and its length corresponds to approxi¬ mately two times the diameter of the rotating shaft.
11. A means as disclosed in claim 9, c h a r a c t e r i z e d i n that the oblong bearing slot has the contour of a peanut shell, wherein the greatest width of the bearing slot corre¬ sponds to the diameter of the rotating shaft, and the narrowest width is slightly smaller than the diameter of the rotating shaft, for achievement of a snap function.*& 12.
12. A means as disclosed in claims 8, 9 and 11, c h a r a c t e r i z e d i n that the fixation pin is configured such that on its rotation, as it bears against said recess, it gradually brings the arm's rotating shaft down from the upper part of the bearing slot via the part of the slot having narrower width, and to the lower part.*& 13.
13. A means as disclosed in claims 7, 8, 9 and 10, c h a r a c t e r i z e d i n that the arm is extended past the rotating shaft with a first hooklike section which engages with the upper edge of an opening in the wall of the cupshaped body, and which, on rotation of the arm within the cupshaped body, causes the rotating shaft to move from an upper position in the bearing slot to a lower position therein, and a second hooklike section that engages with a lower edge of said opening and, on rotation of the arm out of the cupshaped body, causes the rotating shaft to move from the lower position to the upper position in the bearing slot.*& 14.
14. A means as disclosed in one or more of the claims 313, c h a r a c t e r i z e d in that the cupshaped body is fixedly insertable in a recess or bore in said sides, top or base by the body being provided with slots that sectorize the member circumference, the outside of said sectors adjacent to the respective slots being provided with grooves or the like, and the slot having a conical hole for coope ration with a screw or pin which, when rotated or forced into the hole, causes expansion of the slot and engagement between the wall of the recess/bore and said grooves/ribs.
Description:
CABINET MOUNTING METHOD AND ARTICULATED JOINT MEANS FOR USE WITH THE METHOD.

The present invention relates to a method for storing and mounting the body for a cabinet, furniture or the like consisting of two sides, a top and a base, and a means for forming an articulated joint between adjacent end sections of the structural parts, e.g., sides, top and base of a body for a cabinet, furniture, etc.

Cabinets, furniture or the like almost always consist of two sides plus a top and base which form a rectangle. These four units are connected together at the corners by means of methods such as mitring, edge joining or dovetailing. The latter method has all but disappeared from commercial products due to high costs and inefficient production. The mitring alternative is realistic only when a definitive jointing takes place at the factory.

Edge joining is therefore the totally dominant method of section joining today. If the joining is done at a factory, an enormous amount of space is required for warehousing and distribution, which thus become very expensive. Therefore, a significant share of the manufacturing is done according to the so-called "knock-down" system, i.e., the delivered goods consist of finished, surface-treated separate sections that are assembled by the customer. In order for such a system to function, detailed labeling and description must accompany the delivery. If the customer has had no exper¬ ience with such mounting, which is often the case, the customer will often have problems with the assembly and will use a great deal of time before the right parts are correctly assembled and the structure has the final form that is intended.

There are a number of different systems for joining the parts, e.g., screws with visible decorative heads or tension devices and lockable hooks. All known solutions, however, have the common feature that the four sides of which the structure consists are disconnected units.

According to the invention, these disadvantages have been eliminated by arranging to have the sides, top and base assembled at the factory.

The method according to the present invention is charac¬ terized in that adjacent end sections of the sides, top and base are provided with articulation devices to join the parts together, that said sides, top and base in their transport or storage state are arranged such that said top and one of the sides lie parallel with said bottom and the other side, and that the body is mounted by moving said two sides, together with the top and base, in mutually parallel relationship like a parallellogram until said two sides are vertical, whereafter at least one of the two sets of articulation devices situated diagonally in the body is releasably locked into position.

To attain further rigidity in the body, it will be expedient for all of the articulation devices to be locked into position. The body should be provided with a total of at least four articulation devices.

The means mentioned in the introduction for forming an articulated joint between adjacent end sections of struc¬ tural parts is characterized according to the invention by a cup-shaped body hinge- connected to an approximately L- shaped, U-shaped or stepped straight arm.

According to additional embodiment forms of the device, the approximately L-shaped or stepped arm is equipped with a rotatable fixation pin adapted for engagement with a ledge

in said member. Said arm may be hinged to the cup-shaped body at the uppermost open section thereof.

According to a variation of the device, said approximately L- or U-shaped arm may be equipped with a ledge adapted for engagement with a fixation pin rotatably mounted in said member. Said arm will preferably be rotatably hinged to the cup-shaped body near the bottom thereof. The ends of the arm's rotating shaft will each move within an oblong bearing slot in the cup-shaped body during the movement of the arm between its outer positions.

The oblong bearing slot, in a first embodiment form, has straight sides and rounded ends, where its width corresponds to the diameter of the rotating shaft.

In a second embodiment the oblong bearing slot has the contour of a peanut shell, wherein the greatest width of the bearing slot corresponds to the diameter of the rotating shaft, and the narrowest width is slightly smaller than the diameter of the rotating shaft, so that a snap function is achieved. The fixation pin, in this case, is configured such that on its rotation, as it bears against said ledge, it gradually brings the arm's rotating shaft down from its upper part of the bearing slot via the part of the slot having narrower width, and to the lower part.

According to the first embodiment of the bearing slot, the arm is extended past the rotating shaft with a first hook¬ like portion which engages with the upper edge of an opening in the wall of the cup-shaped body and which, on rotation of the arm into the cup-shaped body, causes the rotating shaft to move from an upper position in the bearing slot to a lower position therein, and a second hook-like portion that engages with a lower edge of said opening and, on rotation of the arm out of the cup-shaped body, causes the rotating

shaft to move from the lower position to the upper position in the bearing slot.

The cup-shaped body is adapted for fixed insertion in a recess or bore in said sides, top or base by the body being provided with slots that sectorize the circumference of the body, and the outside of said sector adjacent to the respec¬ tive slot being provided with grooves, and the slot having a conical hole for cooperation with a screw or pin which, by its rotation, causes expansion of the slot and engagement between the wall of the recess/bore and said grooves.

The invention will now be described in more detail with reference to the accompanying drawings.

Fig. 1 illustrates the principle for the method according to the invention.

Fig. 2, 3 and 4 illustrate the method and the device according to the present invention in further detail.

Fig. 5, 6 and 7 illustrate an articulated joint, according to the invention, in various functional positions, with Fig. 10 showing a composite of Fig. 5, 6 and 7.

Fig. 8 shows the view VIII-VIII in Fig. 6.

Fig. 9 shows the view IX-IX in Fig. 6.

Fig. 10 shows a combination of Fig. 5, 6 and 7.

Fig. 11 shows the view XI-XI in Fig. 7.

Fig. 12 illustrates the approximately L-shaped rotating arm in the articulated joint according to Figs. 5-7 and 10, seen from the side in Fig. 12a, from a front side (Fig. 12b) and

from a rear side (Fig. 12c), as well as in section (Fig. 12d).

Fig. 13a shows the cup-shaped body of the articulated joint in Fig. 5-7 and 10, and Fig. 13b shows the section Xlllb in Fig. 13a.

Fig. 14a shows a variant of the cup-shaped member in Fig. 13a, and Fig. 14b shows the section XlVb in Fig. 14a.

Fig. 15 shows a variant of the embodiment form in Fig. 5-7 and 10 where the arm has an approximately U-shape.

Fig. 16 shows the cup-shaped body seen from above. Fig. 17 illustrates the cup-shaped body seen from beneath.

Fig. 18 illustrates the cup-shaped member seen from the side and with alternative expansion producing members.

Fig. 19 shows the section XIX-XIX in Fig. 16.

In Fig. 1-4 are shown the basic principles of the present invention, i.e., a permanent corner jointing of four sides which, from a flat package, such as is shown in Fig. 1 and 2, may be raised up and locked into their right-angled, rectangular functional position. When the customer receives the body for, e.g., a cabinet, said body will be packed flat, as indicated in Fig. 1; i.e., it will consist of a top 1, a first side 2, a second side 3 and a base 4. When the customer has removed the wrapping around the package, he needs only to lift diagonally the top, with the sides connected thereto, into the functional position as indicated with reference numeral 5. As is shown in more detail in, among others, Fig. 4, the respective articulated joints 6, 7 and 8 may be provided with locking devices, 9, 9' and 10, respectively. Locking devices 9 and 9' are pivotable within the cup-shaped bodys 6 and 8 in the respective articulated

joints. Articulated joint 11 is shown without such a locking device to indicate an alternative, while locking device 10 is positioned in articulated arm 41.

When respective sides and top and base of the cabinet body are brought into the position as shown with reference numeral 5 or as indicated in Fig. 4, said locking device will be turned 90° with the aid of a screwdriver, which rotation will, in articulated joints 6 and 8, bring said locking means into abutment with a shoulder 6" on the arm 6' of the articulated joint 6 or the corresponding parts 8" and 8' in articulated joint 8. For the articulated joint 7, locking device 10 engages with a notch 7" in an extra' wall section 7' in the cup-shaped body 7.

In this manner the locking device will clamp and lock the arm of the articulated joint so that it cannot be moved in any direction. To provide a solution as outlined in Fig. 1-4, it is necessary to have diagonally placed, outward-swinging articulated arms for lifting, with opposing articulated arm being diagonally pivotable inwards, where the four joint centers at all times retain the same mutual spacing and provide a parallel, two-layer package in collapsed state. The very special and inventive feature is that the construc¬ tion enables installation between a floor 12 and ceiling 13 without a floor base. This is due to the fact that the body structure swings up in the form of a parallelogram from a packed state into functional position, where it is locked and may be moved into a space where there is little clearance to the floor and ceiling. This means that this type of body utilizes to the maximum the space between the floor and ceiling. Moreover, the edge joining method is rapid and simple, even for persons without any experience whatsoever.

To attach fitting is, e.g., the side of a cabinet, one normally applies screws directly into the underlying material. If the fittings are to be flush mounted or

recessed, this always entails drilling or milling operations in steps areas so that the screw will have some material to grip into. Alternatively, the part of the fitting where the screw is situated would be on the outside. The other existing method involves a cylindrical body having exterior hollow-like knurls which is pressed down into a drilled hole. The disadvantage of these known solutions is that the parts cannot be disassembled without damaging the surrounding material. The present invention requires no recess work for flush mounted fastening. As is apparent from Fig. 16-18, there is no need for recess treatment to insert the fittings. Mounting of the cup-shaped body is done by inserting the body in the hole 14 (see Fig. 14a) drilled to fit the diameter of said body. It should be noted that the cup- shaped body is not to be pressed into the hole, but is merely guided in. As will be apparent from Fig. 18, and also from Fig. 16 and 17, the cup-shaped body has two slots 15, 16 serving to form two sectors of the cup-shaped body parallel to each such slot. These sectors are numbered 17 and 18, respectively, and are each provided with grooves on the outward facing side. The reversible or dismountable anchoring takes place when the parts of the sides of the cup- shaped body that are provided with grooves or flutes are caused to expand against the wall of the recess 14. Parts 17, 18 thereby grip into the surrounding material formed by said wall 14 in structural part 19 and securely lock the cup-shaped body in place. In connection with said slots are provided holes 20, 21, preferably conical in shape, i.e., gradually decreasing in width toward the bottom of the cup. Into said holes 20, 21 are inserted expansion producing members 22 or 23, e.g. a screw 22 or a rotatable pin 23. Expansion is brought about when said screw or pin, generally designated as a cylindrical medium, is rotated or inserted down into the undercut recess or bore, thereby exerting force on said expanding parts. For disassembly, the cylindrical medium is removed, whereby the grip is released.

Here it should be pointed out that in both the inward- and outward-swinging corner joints the female body is secured by means of the side of the body, as described immediately above. The articulated joint 11 in Fig. 2-4, however, represents an exception to this. To ensure that the cup- shaped member shall not rotate within the bore hole, there is provided a crossing flange on said grooves or flutes, in Figs. 15-17 denoted by reference numeral 24.

To enable the cabinet/furniture side to move past the corner denoted with reference numeral 25 in Fig. 3, the outward- swinging articulated arm 8' must also be movable in the direction of depth. For this purpose the cup-shaped body has a recess 26 where the projection 27 on the articulated arm is steered against two oblique planes or chamfers 28 and 29, together with rotating shaft 30 and its bearing slot 31. The movement of the arm is steered out and in by means of the lever-arm principle. The configuration of projection 27 causes rotating shaft 30 to be retained in its position until hook-like part 32 takes hold of plane 28 and lifts the arm (with the aid of rotating shaft 30 in hole/slot 31), causing the cabinet edge 3' to abut in, under pressure, against the cabinet/furniture side. Together with locking device 9;11, which is brought into abutting contact with shoulder 6"; 8" on articulated arm 6'; 8', a two-point attachment is attained. If the furniture body is to be dismounted again, chamfer 29 acts on said projection lower part so as to lift rotating shaft. 30 in hole 31 In the opposite direction, whereby the curve of projection 27 moves in tangential contact across the bottom of the cup-shaped body's interior. The result of this combined function is that it permits the arm, despite its movement in the oval hole, to shift its center without axial play (slippage). A variant of the requisite principle of shifting the center of the rotating shaft is also found on Fig. 14. Instead of the projection lever-arm movement, the oval slot has been given the form of a peanut shell, i.e., an oval hole having a central narrow-

ing. This hole is shown in enlargement in Fig. 4b. As mentioned, hole 33 has the shape of a peanut shell contour, i.e., the opening is oblong with a narrowing 34 at its center section. This causes rotating shaft 30 to be held in place furthest out, i.e., in the uppermost part 33' of the hole or bearing slot 33. The upper section is indicated in Fig. 14b by reference numeral 33'. Similarly, the lower section of slot or hole 33 is indicated with reference numeral 33". It is common to both embodiments as shown, respectively, in Fig. 13 and 14', that the locking device 9; 9'; 10 has a locking flange 35 with a chamfer 36, which on being turned causes the flange 35 to slide into recess 6"; 8" for the articulated arm. The articulated arm is thereby pressed downward. On the variant shown in Fig. 14, rotating shaft 30 will then be forced past the narrowing 34, and will end up in the lowermost or innermost part of groove 33, denoted by reference numeral 33". Locking device 9; 9'; 10 is rotated with the aid of a screwdriver which engages with a slot 36, optionally a cross-slot, therein. As a counter-hold the locking means has a perpendicular projection 37 that moves into a contiguous recess 38, see Fig. 17. The rotational movement of the locking device is thereby limited to 90°. The locking device 9; 9'; 10 is guided down through a bore 39 in the cup-shaped member, where said bore has an milled groove 40 conforming to the dimension of said projection 37. There is preferably a tight fit between bore 39, 40 and locking device 9; 9'; 10. As an alternative to locking device 9; 9'; 10, a stop screw may be used in a preferred embodiment.

The design of the cup-shaped member with the bearing slot and rotating shaft for the articulated arm makes it possible to create free passage at the critical point 25, as shown in Fig. 3 and Fig. 5, 6 and 10.

As will be apparent from Fig. 4, the stepped straight arm may be fastened with the aid of screws 42 to the side 2 of the

cabinet/furniture body. In a similar manner, arm 43 in connection with articulated joint 11 may be secured with screws 44 to the cabinet body side 3. Articulated arm 8' is attached to the body 3 with screws 45. Similarly, articu- lated arm 6' is fastened to the body's wall 3 with the aid of screws 46.