NL8500096A - SCREWS SUITABLE FOR ACCURATE TIGHTENING TORQUES. - Google Patents

Description

£: N.0. 32970 1 ^

Screws suitable for precise tightening torques.

The present invention relates to screws and in particular to screws suitable for use with precise tightening torques, having a head with an engagement surface for a wrench for tightening. According to the prior art, such an engagement surface can be formed by the external surface of the head of the screw or by the surface of an axial recess formed in the head of the screw. The main types of head used today are the hexagon head, square head, double hexagon head (ie with a profile in a plane perpendicular to the axis of the screw - which is limited by placing two above each other). concentric hexagons of the same type offset from each other by an angle of 30 °), double square head (a profile 15 bounded by two squares offset by 45 °), head with square cutout, head with hexagonal cutout, head with double square recess, head with a double hexagonal recess, head with a triangular recess (in which the profile of the recess, in a plane perpendicular to the axis of the screw, is delimited by placing two equilateral triangles with equal size offset by an angle of 60 ° to each other) and head with a cross-shaped recess.

With all known screws mentioned above, the hit and react! e-surfaces engaged by the key for tightening when using the screw have no radial surfaces containing the shaft of the screw. As a result, the forces generated in accordance with the bearing surfaces when tightening the screw are not perpendicular to these surfaces. The components of these forces that do not act perpendicular to the bearing surfaces lead to a deformation of the contact surfaces between the screw and the key for tightening and prevent the magnitude of the tightening torque from being accurately determined. In order to mitigate this drawback, it is forced to adopt manufacturing tolerances which are very small both with regard to the engagement surface of the head or the recess formed in the head and the engagement surface of the wrench for tightening to the area of the tangent surface as large as possible and limit the specific deformation load. In other words, the minimum and maximum play created by the difference between the dimensions of the key for the fastening 40 and the head of the screw, or the recess formed in the head, should be limited as much as possible. This limitation of manufacturing tolerances, on the other hand, makes it difficult to engage the key for tightening the head of the screw, especially when automatic screw systems are used. In addition, the above-mentioned impossibility of accurately determining the tightening torque prevents the use of screws in axial preload assemblies close to the pour point. In this case, in reality, any permanent deformation of the bearing surfaces of the key for tightening and the screw will render both the screw and key for fastening unusable for proper use in a short time.

It has also been proposed (for example, in the case of screws with cross-shaped recesses) to form surfaces for engagement with the key for tightening as part of a conical surface coaxial with the screw in order to insert the key for keying without the need for very narrow manufacturing tolerances. In this case, however, the above-mentioned drawbacks arising from the fact that the bearing and reaction surfaces of the screw and of the wrench for tightening are not subjected to forces that are purely perpendicular to the surfaces themselves during operation of the screw still exist.

Finally, it has been proposed (see British Patent Specification 1 032 144) to form a screw head with a circumferentially extending series of radial projections each of which has two sides present in radial planes passing through the axis of the screw. However, even this known application is not completely satisfactory because of the need to use very narrow manufacturing tolerances for the screw and for the key for tightening, with the ensuing drawbacks already mentioned above. Moreover, the last type of screw has a relatively complex and expensive construction.

It is an object of the present invention to provide a screw capable of avoiding all of the drawbacks outlined above.

In order to achieve this object, the invention provides a screw the main feature of which is the combination of the following two features: a) the head of the screw has an engagement surface for a spanner for tightening, which has a profile with several projections 40 in a plane perpendicular to the axis of the screw, comprising 8500096-4 3 a circumferentially extending array of equally angled protrusions projecting radially outward, each protrusion comprising two radial sides at least partially in two planes passing through the axis of the screw, and a central portion connecting the radially outer ends of the two sides of each projection, b) the parts of the surface for engagement with the key for tightening, which the central parts of the projections bounding the profile with several projections, lie on a single imaginary conical or pyramid-shaped surface, which is coaxial with the screw.

The surface for engaging the key for tightening may be formed by the side surface of an axial recess formed in the head of the screw or by the side surface of an axial additive having the head of the screw. Accordingly, the key for tightening will have a gripping surface of complementary shape to the gripping surface of the screw.

Due to these properties, the bearing and reaction surfaces 20 of the head of the screw and of the fastening key are at least partly formed by radial planes passing through the shaft of the screw, whereby the forces generated during the tightening are perpendicular to this planes, with the advantage that the disadvantages set out above which are present with the known shapes of the screw can be overcome. At the same time, the conical shape of the mutual engagement surfaces of the screw and of the wrench for tightening obviates the need for close tolerances in manufacture of the screw and of the wrench for tightening.

Preferably, moreover, the parts connecting a projection to the following of the multi-projection profile are disposed along the sides of a regular polygon with its center on the axis of the screw and are the portions of the engagement surface that these parts boundary, planes parallel to the axis of the screw.

This feature allows the propeller to be operated even with a conventional spanner in an emergency as will be described in more detail below.

Further features and advantages of the present invention will become apparent from the description below with reference to the accompanying drawings, which are presented only as non-limiting examples and wherein:

Fig. 1 is a perspective view of a screw, partly in section, according to the present invention,

Fig. 2 is a perspective view of a variant of FIG. 1, 5. 3 is a sectional view taken along line III-III of FIG. 1, FIG. 4 is a perspective view of a spanner used to turn the screw of FIG. 1, and

Fig. 5 is a schematic sectional view in a plane perpendicular to the axis of the screw and showing the key for tightening of FIG. 4 in its position in engagement with the screw.

In Fig. 1, reference numeral 1 designates a screw having a threaded stem 2 as well as a head 3 in the end surface 4 of which an axial recess 5 is provided for engagement by a key 6 for tightening (see Fig. 1). 4).

As shown in Fig. 3, the side surface of the recess 5, which forms a gripping surface for the key 6 for tightening, has a profile 7 having several projections, including a circumferentially extending series of equidistant radial projections each of which comprises two radial sides 8 present in two planes passing through the shaft 9 of the screw and comprising a central portion 10 connecting the radially outer ends of the two sides 8.

Reference numeral 11 in Fig. 3 denotes the parts connecting a projection of the profile 7 with several projections to the following.

It can be seen from Fig. 1 that the projections of the multi-projection profile are delimited by radial grooves 12 formed in the recess 5. Each groove 12 has a base wall 13 corresponding to the above-mentioned central portion 10 and two sides 14 corresponding to the sides 8 of the partial profile, at least partially lying, as mentioned above, in radial planes passing through the shaft 9 of the screw.

The base walls 13 of the groove 12 of the recess 5 all lie on a single imaginary conical or alternative pyramid-like surface coaxial with the screw.

Reference numeral 15 denotes the planes of the recess disposed between the grooves 12 corresponding to the sections 11 of the profile of the recess in a section perpendicular to the axis of the screw.

8500006 - * 1 5 4

According to the preferred embodiment, which is inclined in Fig. 1, the surfaces 15 lie in planes parallel to the axis of the screw and are all equidistant from the latter. In other words, according to this embodiment, the parts 11 (see fig. 3) of the profile 57 with several projections correspond to the sides of a regular polygon with the center thereof on the shaft 9 of the screw.

Due to this feature, in an emergency the screw can even be turned with a conventional tightening wrench (in the case of a hexagonal wrench for screws with a hexagonal recess in the head) suitable for engaging only the inner surfaces 15 of the recess 5 .

Alternatively, the faces 15 may form part of a single, imaginary conical or pyramid-like surface coaxial with the screw.

Near the end surface 4 of the head, the side surface of the recess has a bevel 5a, which extends over the entire circumference of the recess.

The locking key 6 shown in Fig. 4 intended to be inserted into the recess 5 to rotate the screw has a side surface with a shape complementary to the lateral surface of the recess 5. As a result, the active part of the wrench for tightening a shaft 16 with a series of radial teeth 17 to fit into the radial grooves 12 of the recess in the head of the screw. Each radial tooth 17 has two radial sides 18 which lie in planes passing through the axis 19 of the shaft 16 and an external surface 20. The outer surfaces 20 of the radial teeth 17 lie on a single imaginary conical or pyramid-like surface coaxial with the shaft 16 and equal to the imaginary surface that the base walls 13 of the radial grooves 12 of the recess in the head of screw. Reference numeral 21 indicates the parts of the surface of the shaft 16 between the teeth 17.

In a section lying in a plane perpendicular to the axis of the axis 16. (see fig. 5) the key 6 also has a profile with i

various protrusions including a circumferential extension J

Known array of equally angled protrusions bounded by the radial teeth 17. As shown in Figure 5, the angle between two sides 18 of each radial tooth 17 (indicated by G) is smaller than the angle between two sides 14 of each radial groove 12 indicated by B. In addition, the distance P (see fig. 5) between two diametrically opposed surfaces 40 is smaller than the distance between the opposed surfaces.

85 0 0 0 9 S

* 3 · 6

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Overlying planes 15 of the recess 5. Consequently, when the key 6 for insertion is inserted into the recess 5 of the head of the screw, spaces exist indicated by g and f in Fig. 5 between the front surfaces of the recess and of the key.

As shown in Fig. 4, each radial tooth 17 has two lateral chamfers 17a near the end of the smaller diameter key.

If it is necessary to tighten the screw, the key 6 for tightening is provided in the recess 5 formed in the head 10 of the screw and the desired torque is applied to the screw by means of the key 6. When gripping the shaft 16 of the wrench in the recess 5 is moved the shaft axially forward until the external surfaces 20 of the wrench are brought into contact with the base walls 13 of the grooves of the screw recess.

As can be clearly seen from Fig. 5, this can be accomplished without the need to use precise manufacturing tolerances for the screw and for the wrench. Once the axial engagement of the key in the recess of the head of the screw has been achieved, the key is rotated to contact one of the sides 18 of each radial tooth 17 with the radial side 14 of the screw directed thereto. corresponding groove 12. The force generated by the torque for tightening in accordance with these surfaces is perpendicular thereto, thereby enabling the above-mentioned advantages.

The invention has been described with reference to the accompanying drawings, referring to an example with a recess with six equally angled grooves. However, it goes without saying that any number of grooves and corresponding number of radial teeth on the wrench can be used for tightening. However, solutions with six or four grooves are preferred.

The angle of inclination of the base wall 13 of the grooves 12 relative to the axis 9 of the screw can also be of any size, although an angle between 5 ° and 7 ° is preferred so as not to unduly limit the size of the radial sides 14 which serve as support and reaction surfaces during fastening. The solution in which the base walls 13 are parts of a conical surface is also preferred over that in which the base walls are part of the faces of a pyramid with a regular base coaxial with the axis of the screw.

40 The angles A and B showing the width and distance of the grooves 12 8500096 i * 7 from. delimiting the recess of the screw may also differ depending on the spaces desired and the strength properties to be achieved for the teeth of the recess and for the teeth of the key for tightening.

5 The diameter of the smaller end of the key for tightening should be chosen to prevent this end of the key from contacting the bottom of the recess in the head of the screw.

The "conical" coupling between the key for tightening and the head of the screw during engagement of the key with the head allows perfect centering of the key to be achieved.

Fig. 2 shows a variant in which the head of the screw, instead of a recess, has an axial add-on 22 of a shape complementary to that of the recess 5 shown in FIG. 1.

Obviously, in this case, the key for tightening * must have a gripping surface complementary to that of the axial add-on 22.

In FIGS. 1 and 2, parts having the same function are indicated by the same reference symbols.

In summary, the features described above provide the following advantages: a) it is not necessary to use precise manufacturing tolerances for the screw and key for tightening, j 25 b) the engagement of the key for tightening with the screw head is facilitated by the possibility of the large * | spaces "g" and "f" shown in fig. 5, by the inlet chamfers 5a, 17a and by the conical shape of the engaging surfaces on the head of the screw and the key for tightening, 30 c) as soon as the key for the tightening is engaged with the head of the screw, mutual conical coupling allows perfect centering of the key relative to the screw to be realized, d) at the start and during screwing, the carrying and reac -35 tie surfaces on which the forces generated by the tightening torque act radial planes passing through the axis of the screw, the forces are therefore perpendicular to these surfaces and do not give rise to deformation beyond the elastic deformation limits, therefore it is also possible to determine the torque for 40 tightening with considerable precision; 8500056 * 1 '8 e) the possibility of loosening the tightened screw is ensured, both by means of the special key described above and with conventional keys suitable for engaging the internal surfaces 15 of the recess 4 or of the axial add-on 22. In the first case, a normal hex key is sufficient, while in the second, a conventional articulated tooth key can be used.

The present invention also relates to other embodiments which have the same utility and can be accomplished by those skilled in the art without going beyond the scope and scope of the present invention.

8500096

Claims (7)

1. Screw characterized by the combination of the following properties: a) the head (3) of the screw (1) has a gripping surface (5, 5 22) for a key for tightening, which comprises a profile (7) with various projections having a plane perpendicular to the axis of the screw comprising a circumferentially extending series of equidistant projections projecting radially outward, each projection comprising two radial sides (8), at least partially in two planes passing through the axis (9) of the screw, and a central portion (10) connecting the radially outer ends of the two sides (8) of each projection, b) the portions (13) of the surface for engagement with the spanner 15, which define the central portions of the projections of the multi-projection profile lie on a single imaginary conical or pyramid-like surface, which is coaxial with t the screw. Screw according to claim 1, characterized in that the engaging surface for the key for tightening is the side surface of an axial recess (5) formed in the head (3) of the screw (1). Screw according to claim 1, characterized in that the engagement surface of the key for tightening is the side surface of an axial add-on (22) of the head (3) of the screw (1). Screw according to claim 1, characterized in that the parts (22) connecting a projection and the following of the profile (7) are arranged along the sides of a regular polygon centered on the centerline (9) of the screw is on. Screw according to claim 4, characterized in that the parts 30 (15) of the engaging surface (5) of the key for tightening, the parts (11) which have one projection and the next of the profile (7) connect several protrusions, planes are parallel to the axis of the screw. A screw according to claim 1, characterized in that the portions 35 (15) of the wrench engaging surface (5) for tightening define the portions (11) defining a projection and the following of the profile (7 ) with multiple projections, lie on a single imaginary conical or pyramid-like surface coaxial with the screw. Locking wrench for operating a screw 8500096 according to any one of the preceding claims, characterized in that it has a gripping surface complementary to the corresponding gripping surface of the screw. • 1-1-1-MM 1 I i I I I I I 1 1 1 I 8 5 0 Θ 0 9 6