SYSTEM

DESCRIPTION

Field of the invention

The invention relates to a screw with a variable locking angle into the plate and a corresponding locking system. In a broader sense this invention belongs to the field of surgical instruments, aids and procedures specially designed for application on bones and joints, for example for osteosynthesis, where utilized plates and screws are specifically designed for such purposes. More specifically, the field of invention can be described as a locking system in which the screw head is locked into a bore on the bone plate in such a way that the element that performs the locking itself is the thread machined in the bone plate .

Technical problem

The basic technical problem that is solved by every locking system used in practice is that such a system delivers a simple and effective locking of the screw head inside the plate while simultaneously anchoring the screw body inside the bone. This is also the case with the present invention which allows a variable locking angle, in the range of -20° to 20°, to be achieved measured in relation to the base, i.e. the axis of the bone plate bore in all allowable directions.

The bone plates are made of titanium, titanium alloy with aluminum, and/or vanadium and/or niobium, or with any other suitable biocompatible material and each plate is equipped with at least two bores where screws are inserted into. The screws, to be used for variable locking of the screw head into plates, are also made of the same or very similar materials. However, the bone plates come with various geometries to be adaptable to any situation the surgeon may be confronted with and for very specific applications. Also, depending on the site and type of fracture - multiple dimensions of the same geometry suit for a diverse patient population. In the case of osteosynthesis plates, each such plate is equipped with multiple bores. So, an average plate contains 4-20 bores in which an average of 4-10 screws will be inserted during an operation. Usually some bores on the plate remain unused.

In addition to the formation of geometry which corresponds with the application of the plate to a particular bone, the plate machining process therefore includes also the process of cutting threads in multiple bores. As we will see in the prior art elaboration, these threads are sometimes very specific. Therefore, every bore that is processed in a non-standard way; here under a non-standard way we understand a method that is different from the usual tapered threading or parallel threading - represents an additional cost of production. If a screw bore remains unused in the application, since only a certain number of specifically machined bores on the plate are actually used in surgical intervention, this significantly increases the price of the locking system. Such locking systems are well known in the art. They consist of a bone plate which is softer than the used material to form the screw with thread on its head. During the application, said screw head is carved into the specifically machined bores formed in the bone plates and then said screw is "locked" into the plate and a firm bond between the screw head and the said plate is formed.

The first technical problem addressed by the present invention is the observed surplus of complexly manufactured but unused bores on the bone plate, as not all bores are necessary. Namely, the proposed new locking system shifts the machining process complexity exclusively to the newly designed screw, while the plate and its bores are subjected to the conventional and simple standard bore formation equipped with ordinary tapered threading or parallel threading. In the disclosed invention, a screw head is made from a softer material than the used bone plate material. During the locking process, the plate causes damages to the specifically designed screw head and lock it within the said plate. It has been mentioned already that not all bores on the standard plate are used in practice, so the production of this system is significantly more economical, and consequently, the surgical procedure is more cost-effective. As will be seen, this first technical problem has been solved by implementing a novel and specific screw head geometry yielding the same locking or even better locking results than inverse systems with a plate made of a softer material and the screw head made of a harder material.

In addition to its use with a bone plate with standard threads, the newly designed screw can be used in systems with non-standard threads without any modification. The only requirement is that the hardness of the non-standard threaded plate is higher than the hardness of the used screw, i.e. the screw head. The latter fact contributes to the possibility of combining parts of different locking kits in the cases or conditions such as natural disasters or wartime conditions, when the availability of plate sets and compatible screws may be limited.

The newly designed screw is easy to manufacture due to the fact that it does not contain a thread on its head, only simple machined surfaces. Such geometry is considerably simpler compared to similar screws in the art, without compromising the quality of its locking capabilities. Of course, the application of the newly designed system is not limited to its use in medicine only, but this system can also be applied in a variety of industries, where it is necessary to lock the screw into a structural element, and where this screw tightens the surface of one element to any regular or irregular geometry of another structural element and when a firm connection needs to be created between them.

The prior art

Numerous technical solutions of specifically designed screw heads that are locked into bone plates have been disclosed in the prior art. US patent application published as US2017/0319248A1 for the invention: "Variable-angle locking screws, and bone plate systems that include variable-angle locking screws", filed in the name of Cardinal Health 247 Inc., discloses a specifically designed screw that locks into the plate. The similarity with the present invention lies in the fact that the aforementioned screw is designed with specifically shaped segments on the screw head which is not circular but segmented. However, this screw head has additional threads that are carved into the plate, which is not the case with the present invention. A screw designed in the way presented in this patent application can be used with plates with bores that have or do not have a thread. However, it is clear from this document that the material used for making such a screw is harder than the material of the plate itself and that the process of making such a screw is significantly more complex than the process of making the screw presented in the present invention.

US patent application published as US2010/0312285A1 for the invention: "Bone Plate Assembly", filed in the name of Greatbatch Ltd., discloses, inter alia, a screw that locks into a plate at a certain angle. The head of the screw is produced in segments that have a thread which is carved into the bone plate bores. Said bores are irregular in shape and are equipped with thread that accept the thread of the screw head. The complexity of making the plate with such bores is the essential technical characteristic that is avoided by the technical solution according to the present invention, without compromising the locking abilities .

US patent application published as US2017/0042595A1 for the invention: "Polyaxial Locking Mechanism", filed in the name of Rightholder Zimmer Inc., discloses a screw that locks with its head into the bone plate. As in the previous technical solution, the screw head is equipped with a thread which interlocks with the plate thread. As with the previous invention, the screw head is segmented, but also additionally fitted with a thread; this is not the case in the present invention described in this application and this further complicates the production of such a screw head considerably as well as the corresponding bone plate .

A very similar solution to the previous one is found in the US patent application US2007 /0083207A1 for the invention: "Variable angle bone fixation assembly", filed in the name of Ziolo Tara et al . The need for complicated machining of the screw head and every bore in the corresponding plate makes this invention inferior to the solution described in this invention application.

Following the same concept of screws with special head geometries there is also another technical solution disclosed in the US patent application US2015/0190185A1 for the invention "Variable Angle Bone Fixation Device", filed in the name of Depuy Synthes Products Inc. This document discloses a specifically designed screw that allows its head to be locked into a plate that is equipped with very complex bores whose manufacturing is certainly very complex. Thus, this invention suffers from weaknesses which are eliminated by the solutions achieved by the present invention.

US patent application published as US2015/0142063A1 for the invention: "Systems and Methods for Using Polyaxial Plates", filed in the name of Smith & Nephew Inc., discloses a specifically designed screw head with wings that interact with the thread created in the plate bore . The screw head is of a rather complicated design; thus, this invention suffers also from weakness compared to the simple head design of the present invention.

All previously mentioned technical solutions define general prior art for the hereby disclosed invention. However, it seems that a technical solution published in the form of international PCT patent application WO2015 /020789A1 for the invention: "Orthopedic Screw Fastener System including Screws", filed in the name of Flower Orthopedics Corp. Inc., represents the closest prior art. This document discloses the locking system of screw and plate to which we herein refer. The said prior art is shown in Figures 1, 2, 2A, 3, 4A and 4B with a caption "Prior art". Figures 1 and 3 depict a bone plate (90) with multiple bores (91) for receiving a screw head (101) with a thread (105) . Each bore (91) is cone-shaped, with a cone slope d' as indicated in Figure 4A and extends from the upper edge (92) to the bottom edge (93) of the plate (90), where said bore (91) is machined in a way that forms curved sections (94) . The sections are machined in a way that they are inclined at an angle d' relative to the bore axis. Two neighboring curved sections are interconnected by the intersection line (95) which grows into a contact surface (96) near the bottom edge (93) of the bore (91) . The plate is made of the material that is softer than the material of the screw (100) shown in Figure 2. The screw (100), which locks its head into the bore (91) of the bone plate (90), consists of a screw head (101) with a thread (105), tip of the screw (102) made on the screw body (103) on which there is a self-cutting thread (104) . The screw head (101) and the screw body (103) meet at the joint (106); see Figure 2 and Figure 2A, where Figure 2A represents detail S from Figure 2.

The way the locking system functions is shown in detail in Figures 4A and 4B. Figure 4A illustrates the case when the screw is inserted at an angle of 0° relative to the bore (91) axis. A portion of the plate (90) is shown through the bore (91) cross-section, which is located behind the screw head (101), illustrated for reference below the said cross-section. The thread (105), carved into the screw head (101) damages the intersection lines (95) of the curved sections (94) in the locking process in the way shown in Figure 4A. The damage (99) resulting from the thread (105) cutting follows the length of the screw as shown by the line of damage (98) . Figure 4B shows another case where the screw is screwed at an angle of 10° relative to the bore (91) axis. The thread (105), carved into the screw head (101) damages the intersection lines (95) of the curved sections (94) in the locking process as shown in Figure 4B. The damage (99) resulting from the thread (105) cutting follows the length of the screw as shown by the line of damage (98) . By comparing Figures 4A and 4B the damages (99) of locking the screw head (101) with the thread (105) in a position inclined relative to the bore (91) axis is evident. This invention represents an inverse technical solution with respect to the solution disclosed hereby. The screw, according to this invention, contains a number of curved surfaces, while a standard or non-standard thread is carved into the bone plate. The new technical solution according to the present invention will be qualitatively and quantitatively compared with the solution from the invention WO2015 /020789A1 of the prior art.

The mechanical testing of the inverse technical solutions shows that the new technical solution is at least as good as the solution presented in the document WO2015 /020789A1 of the prior art, while being simpler to produce.

Summary of the invention

The present invention discloses a novel screw design with a variable locking angle into the bone plate. The said screw consists of:

a screw head with curved surfaces and contact surfaces, as well as a centrally placed star-shaped socket for receiving a fastening tool, located on the upper side of said head; and

a screw body ending with a tip that enters the bone first; where the said screw body is equipped with a self-cutting thread which extends from the joint between the screw head and the screw body along to the tip of the screw.

The said screw is characterized by the following features:

said screw head is formed from a rotationally symmetric truncated cone of height h, with a base radius Rout on which said star shaped socket is centrally positioned and where the cone side is inclined at an angle Y relative to the axis of said cone which coincides with the screw axis;

where n equally curved surfaces, n ³ 4, are carved into said cone and extend from the upper edge of the screw head to the bottom edge of the said head and where each of the said surfaces forms a portion of the cylindrical surface with the curvature Rc, where the longitudinal axis of said cylindrical surface lies on the straight line P which is parallel to the cone surface and inclined at an angle Y relative to the axis of the screw, and where the intersections of all straight lines P of the said n cylindrical surfaces with the plane perpendicular to the screw axes form vertices of a regular polygon with n sides;

where the said curved surfaces are interconnected with the identical contact surfaces of the truncated cone, both extending from the upper edge to the bottom edge of the screw head;

where the upper edge is partly formed from the points of contact surfaces that lie on the radius Rout with the center on the axis of the screw, and from the upper edges of the curved surfaces in a way that the highest point of each said surface lies on the radius Rin in a plane parallel to the plane containing the base of the radius Rout, provided that Rin < Rout; and

where the bottom edge is formed from the ends of contact surfaces and the curved surfaces so that it enters the joint between the head and the screw body.

According to the invention, the preferred values are selected to be: a) n = 6, 8, 10 or 12;

b) 0.3 < Rin : Rout : Rc < 3.0; and

c) 5° < Y < 30° .

According to the invention, the preferred angle Y is 9°, which selection allows the locking process wherein the maximum applicable locking angle is 20° measured with respect to the screw axis in all directions .

A locking system of screws into the plate, according the invention, consists of:

one or more screws whose head hardness is lower than the hardness of the material used to form the bone plate; and

a bone plate with a geometry adapted for bone fixation, with at least two bores located within said geometry, where each bore has a thread of a conical shape with the slope d in relation to the bore axis and which is capable of receiving the conically - shaped screw head.

The selected height h is greater than the thickness of the bone plate. The bore thread slope d is greater or equal to the slope Y of the screw head and the corresponding contact and curved surfaces. The insertion of the screw at a selected angle in the range from -20° to 20° relative to the bore axis, causes the bore thread to be cut into the contact and curved surfaces of the screw head. Said cutting causing damages on the screw head surfaces which keep the said screw locked into the corresponding plate.

According to the preferred embodiment, the height h is selected to be from 0.5 to 1.6 of the plate thickness and d is selected to be from 5° to 30° .

Said technical solution is applicable for the bone plates where bores have a continuous thread, as well as where each bore has a thread which is not continuous but has threaded segments and segments where the thread is absent. Such a locking system is very useful in veterinary and human medicine.

A brief description of the figures

Figures 1 and 3 illustrate a bone plate constructed according to the closest prior art solution, disclosed in W02015/020789A1. Figure 2 depicts a screw that locks into the said plate, while Figure 2A illustrates the detail S of the screw head shown in Figure 2. Figures 4A and 4B depict damage that occurs in the plate bores, shown in Figures 1 and 3, when the screw head is screwed at angles 0° and 10° in relation to the bore axis made in the bone plate according to the prior art solution W02015/020789A1.

Figure 5A represents the detail P from Figure 5C and depicts the newly designed screw head that is locked into the bore made in the bone plate shown in Figure 5B. Figure 5B is a cross-section of the bone plate detail, marked with Q, in Figure 5C.

Figure 6A illustrates the position of the locked screw in the case when the screw head is fixed at an angle of 0° in relation to the bore axis. Damage resulting to the screw head is shown in Figure 6B.

Figure 6C illustrates the position of the locked screw in the case when the screw head is fixed at an angle of 10° in relation to the bore axis. Damage resulting to the screw head is shown in Figure 6D.

Set of figures 7A, 7B, 7C, 7D, 7E and 7F depict the screw head design in the case when n is selected to be equal to 8, 10 and 12 curved surfaces on the screw head, for a screw of the same head radius Rout with variations in the size of the curved surfaces.

A detailed description of the invention

The present invention relates to a screw (10) with a variable angle of locking into a bone plate (30), where the head (20) of the said screw is locked into a bore (31) of the plate (30) . The present invention also discloses a corresponding locking system of screw (10) - plate (30) as illustrated in Figure 5C. The plate (30) may be formed of an arbitrary geometry, but for simplicity reasons the plate (30) is illustrated in Figure 5C with a series of evenly spaced bores (31) . The spacing of each bore (31) should be such to allow optimum plate (30) fixation to the desired bone. In the present invention, each of the bores (31) is made with a continuously machined thread (32), with a slope that is designed in a conventional way, well documented in the prior art, as shown in Figure 5B. Figure 5B shows one continuous thread (32), carved conically at an angle d relative to the bore (31) axis where the side of the cone accompanying the thread (32) is marked with straight line D. It is desirable that the angle d be greater than or equal to angle Y, which defines the cone of the screw head (20) which is best locked by the corresponding thread (32) when the value is about 2Y. In practice, the value d is chosen in the range from 5° to 30° as shown in Figures 5A and 5B.

The present invention is not limited to tapered threads (32) illustrated in Figure 5B, but also to standard cylindrical threads of a constant cross-section (d = 0) . However, a due care is necessary when choosing dimensions of a corresponding screw (10) whose head (20) is locked by said thread (32) . In addition to the already mentioned continuous conical and cylindrical geometry, the thread (32) can be machined in a way which is not continuous but has segments which are threaded and segments where the thread is absent, i.e. with the thread made only on segments of the bore (31) . Such discontinuous threads (32) are cited in the prior art documents, disclosed hereby. If there is a need for such a technical solution, it is also possible to imagine a plate (30) which combines bores (31) with several different types of previously mentioned threads (32). Such a plate (30), regardless of the chosen geometry and the type of thread, i.e. continuous or discontinuous, represents the standard in the prior art. For machining simplicity and for obtaining optimum locking performances, the processing of all bores (31) of the bone plate (30) is recommended in such a way that all threads (32) are selected to be of conical type where d 2Y, which significantly reduces the production costs of such plates (30) . According to the present invention, the plate (30) should be made of a material exhibiting hardness higher than the hardness of the screw head (20), preferably of titanium used for medicinal purposes, e.g. grade 5, and for the corresponding screw (10) or screw head (20) of titanium grade 2. Figure 5C illustrates such a screw (10) before insertion into the plate (30) .

In the present invention, the screw (10) consists of a screw head (20) with machined curved surfaces (24) and contact surfaces (25), as well as a centrally placed socket shaped like a star (26) for receiving the fastening tool into, located on the upper side of said head, as shown in Figure 7A. The star-shaped socket (26) can be of an arbitrary geometry suitable for receiving a fastening tool tip and made in a way which prevents the tools from popping out of this socket, e.g. a Phillips or an Allen type tool which enables accurate handling by the operator. The screw body (13) ends with a tip (12) of the screw (10) that enters the bone first. The screw body (13) is equipped with a self-cutting thread (14) which extends from the joint (16) between the screw head (20) and the screw body (13) to the said screw tip (12) . This kind of screw (10) is therefore different from other screws already known in the prior art .

However, the head (20) of the screw (10), illustrated in Figure 5A as a detail in Figure 5C, represents the main difference of the present invention from the prior art. As mentioned before, fewer screws (10) are often used in surgical interventions than there are bores (31) with threads (32) made on bone plates (30) . Bearing this in mind, a locking system that has more bores (31) created in a simpler and more economical way on plates (30), while the more demanding machining is required for the screws (10) only - has obvious advantages in the art, rendering the locking system cheaper.

The screw head (20), according to the invention, is formed from a rotationally symmetric truncated cone of height h, see Figures 5C and 5A as well as Figures 7A-7F. This truncated cone is directed with its missing tip towards the tip (12) of the screw (10) . The base of this rotating cone is designed with radius Rout, see Figures 7A-7F, and is projecting slightly outwards in a way that the star-shaped socket (26) is situated within the said cone. The side of the cone is inclined at the angle Y in relation to the longitudinal axis of the said cone, as indicated in Figures 7C and 5A. The straight line nc is a line that lies on the side of the cone in at least two different points and cuts the cone rotational axis in just one point. Consequently, each such straight line nc is inclined at Y angle in relation to the longitudinal axis of the said cone, see, for example, Figure 5A.

In order to obtain a screw head shape according to the present invention, it is important to consider the manufacturing process . Screws (10) are most often produced using CNC (Computer Numerical Control) technology and it is therefore useful to use tool trajectories that are compatible with the production technology. The screw head (20) according the invention, when viewed from the upper perspective, see Figures 7A-7F, is a part with side grooves, i.e. curved surfaces which have been machined out. According to the present invention, the head (20) is formed by milling curved surfaces (24) of the truncated cone as shown in Figure 5A. Each of the curved surfaces (24) is formed as a portion of the cylindrically shaped surface, where the cylinder itself has a radius Rc and where the axis of that cylinder lies on straight line P. The straight line P is inclined at an angle Y relative to the longitudinal axis of the cone into which curved surfaces (24) are carved as shown in Figure 5A. According to the invention, n equally curved surfaces (24) are carved into said cone, as illustrated in Figures 7A-7F. The bundle of straight lines P which are inclined at an angle Y forms vertices of a regular polygon with n sides, when these lines intersect the plane perpendicular to the longitudinal axis of the cone. It is desirable that n is equal or greater than 4, and in practice the best results are achieved when n = 8, 10 or 12. When curved surfaces (24) are carved, then the truncated cone surfaces that remain between them are portions of the side of the truncated cone that connect them and represent the contact surfaces (25). In this way, alternately shaped curved surfaces (24) and the contact surfaces (25) are extended from the upper edge (22) to the bottom edge (23) of the head (20), where said head (20) passes into the joint (16) between the head (20) and the screw body (13) .

Figures 7A-7F show projections of the characteristic radii Rout, Rin, and Rc' into the plane perpendicular to the longitudinal axis of the cone and the corresponding design of the screw head (20) with such a geometry disclosed in Table 1. The size of Rout represents the radius of the cone base, Rin is the smallest distance from the upper edge

(22), i.e. the highest point of the curved surface (24) on the screw head (20) to the screw (10) axis. Value Rc ' represents a projection cylindrical curvature Rc of the surfaces (24) into the plane perpendicular to the cone axis . L represents the largest distance between two contact surfaces (25) located closer to the bottom edge

(23) where the cylinder with radius Rc plunges deeper into the cone, and 1 represents the smallest distance between the contact surfaces (25) located closer to the upper edge (22) of the head (20) . D represents the maximum distance between two adjacent curved surfaces (24), and d is the smallest distance, close to the bottom edge (23) . Value A represents the area of contact surface (25) of the screw designed in this way. A side-by-side comparison of the screw head (20) performances was made for the constant values of Rout and Rin; only parameter Rc was varied by approx. 15% and the number of curved surfaces (24) is selected to be 8, 10 and 12. The parameters of such variations for 2.4 mm screw are shown in Table 1 below:

When designing the screw, it is necessary to take particular care of the surface A layout, specifically of the contact surface (25) area once the machining of the cone head (20) is finished, where said contact surfaces (25) have a key function in the locking process. The locking process is shown in a series of Figures 6A-6D. Figure 6A is a side view of the plate (30) into which the screw (10) is locked at an angle of 0°. Figure 6B shows damage (29) that occurs on the contact surfaces (25) and the curved surfaces (24) of said screw head (20) . The line of damage (28) ascent coincides with the thread (32) created in the bore (31) . In the same way Figure 6C represents a side view of the plate (30) into which the screw (10) is locked at an angle of 10°. Figure 6D illustrates damage (29) that occurs on the contact surfaces (25) and the curved surfaces (24) of said screw head (20) during locking at an angle of 10°. The damage occurs on the screw head (20) made of a material that is softer than the material of the plate (30) . In practice, two extremes are avoided, i.e. a too large contact surface (25) which prevents easy occurrence of damage (29), but locks the head (20) into the plate perfectly, and a very small contact surface (25) that locks the head (20) into the plate (30) poorly, but handling such a screw is relatively simple.

In modelling the screw (10) layouts and cutting-in forces that cause damages (29) the following values were found as optimal for the given screw head design in the present invention.

Table 2 shows the values for screws of 2.4 mm, 3.5 mm and 5.0 mm that are used in practice, with 8, 10 or 12 curved surfaces (24) and acceptable parameters D and d, defining the largest and the smallest spacing between the curved surfaces (24) and thus the amount of the contact surface (25) that participates in the locking process. It should be emphasized that the sizes D and d are directly related to the chosen range of the radius of curvature Rc and the values Rin and

Rout .

A comparison between the present invention and the locking system disclosed by the document WO2015 /020789A1 as the closest and the most similar technical solution is given below. The analysis was carried out by performing the cyclic testing of the locking features by bending the screw of 2.4 mm in diameter locked into a 1 mm thick plate with 4 bores by parallelly examining the solution presented in WO2015 /020789A1 and the present invention in a fatigue test (LFV 50- HH, Walter + Bai AG, Switzerland, production year 2006) . The selected angles of locking the screws into the plates were 0°, 10°, 15° and 20° in relation to the bore (31) or bore (91) axis, as shown in Table 3, which contains the test parameters:

where the following abbreviations are used:

Fsr - mean force,

Fa - force amplitude

F - force range Fsr +/- Fa,

f - frequency of cyclic loading,

N - number of load cycles, and

Fd - nominal force of the force transducer.

The results of the bending test, using 3 different samples in each experiment, with the screw locked into the plate under cyclic load are shown in the tables below, where the following notation is used:

Smax - maximum screw displacement,

Smin - minimal screw displacement,

As = Smax - Smin,

Fmax - maximum force at Smax,

Stiffness - Fmax/Smax ratio. The comparison of the technical solution presented in Figures 1-4B and the new locking system according to the present invention is elaborated side-by-side in the tables below:

The results show that the mean value of the maximum screw displacement and stiffness in both technical solutions are very similar for the locking angle of 0°, however, the system according to the present invention is significantly simpler to produce.

The results show that the mean value of the maximum screw displacement is lower in the present invention, and that stiffness, when the maximum force is taken into consideration for both technical solutions, exhibits similar values for a locking angle of 10°.

The results show once again that the mean value of the maximum screw displacement is the same, and that stiffness is similar in both technical solutions, taking the maximum force of a similar amount into account for a locking angle of 15°.

The obtained results show a comparison among the prior art and the present invention. The stiffness of the present invention is higher for a locking angle of 20° than in the case of prior art.

From the results shown in Tables 4, 5, 6 and 7 it is possible to conclude that, within the experimental error, the locking system of the present invention is at least just as good as the system in the prior art, and even better (stiffer) as the inclination of the screw head (20) increases in relation to the bore (31) axis, which is certainly an unexpected result for an average person skilled in the art. This unexpected result indicates an inventive step in the presented new technical solution. It is necessary to emphasize once again that the proposed new locking system transfers all the machining complexity or processing from the plate (30) to the screw (10), more specifically, to the screw head (20) . Industrial Applicability

Industrial applicability of the present invention is obvious as the invention discloses a whole new system of locking screws into the bone plate. The presented system can also be used for similar applications of connecting other structural elements using screws and threaded screw bores.

References

References of the new technical solution

10 screw for the plate 30

12 tip of the screw 10

13 screw body with a self-cutting thread 14

14 self-cutting thread

16 joint between screw head 20 and screw body 13

20 screw head

22 upper edge of the screw head 20

23 bottom edge of the screw head 20

24 curved surface formed in the screw head 20

25 contact surface between the curved surfaces 24

26 star-shaped socket for receiving a fastening tool

28 line of ascent of damage 29

29 damage caused by carving thread 32 into the contact surfaces 25 and curved surfaces 24

30 plate

31 bore for locking the screw head 20

32 thread in the bore 31

Rin the smallest radius of the upper edge 22 of the screw head 20 Rout the largest radius of the upper edge 22 of the screw head 20 Rc curvature radius of the machined surface 24 measured

perpendicular to the direction of the tool movement along the straight line P

Rc ' projection of Rc on the plane perpendicular to the screw 10 axis

L distance between two adjacent contact surfaces 25 along the edge 23

1 distance between two adjacent contact surfaces 25 along the edge 22

D contact surface 25 width along the edge 22

d contact surface 25 width along the edge 23

h screw head height

P straight line parallel to the cone sides of the screw head 20 lie straight line situated on the contact surface 25 Y inclination angle of the straight line P in relation to the screw 10 axis

D the slope line of the thread 32 in the bore 31

d angle of the slope line D in relation to the bore 31 axis n number of curved surfaces 24 on the head 20 of the screw 10

P, Q details

References of the prior art

90 plate

91 bore for receiving the screw head 101

92 upper edge of the bore 91

93 bottom edge of the bore 91

94 curved section of the bore 91

95 line of intersection of sections 94

96 contact area at the intersection of sections 94

98 line of ascent of damage 99

99 damage caused by screw head threading 105

100 screw for the plate 90

101 screw head with the thread 105

102 tip of the screw 100

103 body of the screw 100 with the self-cutting thread 104

104 self-cutting thread

105 thread of the screw head 101

106 joint between the screw head 101 and the screw body 103 d' inclination angle of curved sections 94 which is cone- shaped, in relation to the bore 91 axis

S detail