DE7439878U - FASTENING DEVICE - Google Patents

Description

Conventional screws or bolts are known whose head or body have a hexagonal cross-section. With this type of screw or bolt, the so-called "driving angle" is large and can be 60 °, for example. The "drive angle" is defined by a radial line that runs through a force-acting point with a
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The object of the present invention was to create a fastening device such as a wrench, by means of which fastening elements or screws can be attached and tightened or loosened and removed, as claimed, for example, in the parallel application.

The fastening device according to the present invention consists of a body provided with a cylindrical fitting opening and a plurality of engaging ribs arranged on the peripheral wall of this opening, each of these ribs being in cross-section a partial circle extending from the cross-sectional circle of the fitting opening extends inside and where the center of this partial circle is so selected readable>

These tangential lines are arranged tangential to the cross-sectional circle of the fitting opening at second intersection points at which the pitch circle of the rib intersects the cross-sectional circle of the fitting opening.

If the fastening device according to the invention is used to transmit a rotational force, for example to the screw head of a screw or a fastening element, which has a corresponding cross-section to the fitting opening of the fastening device, then such a force component which would cause the fastening device to slide off is not caused and excellent contact is achieved between the fastening device and the head of the fastening element. This means that the turning force is almost completely transmitted from the fastening device to the head of the fastening element or the screw. In addition, there is no damage and no wear in the fastening element and in the fastening device.

If the center of the pitch circle is arranged radially outside the first intersection point as in the conventional fastening devices, then the "drive angle" shows a value greater than
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with regard to the drive direction of the fastening device and this results in the disadvantages outlined above.

The center of the pitch circle of the rib is preferably arranged between the first point of intersection and a chord which connects the second points of intersection. In cases where the center of the pitch circle is located within the tendon with respect to the center of the cross-sectional circle of the fitting opening, the base of the rib becomes narrower and can thereby break off and also the attachment of the fastening device in relation to the fastener becomes more difficult.

Typically the fastener has four to eight ribs and preferably six ribs. If the fastener has fewer than four ribs, it is difficult to properly position the fastener on the screw head. If more than eight ribs are used, then the individual ribs are relatively narrow and are subject to faster and easier wear, and errors in the dimensions and arrangement of the ribs can also occur during manufacture of the fastener.

The ribs are preferably arranged at equal distances from one another along the inner peripheral wall of the fitting opening and the diameter of the pitch circle of the rib cross-section is defined by the following equation:

Here n is the number of ribs, dtief1 the diameter of the pitch circle of the rib cross-section and Dtief1 the diameter of the larger circle of the opening cross-section. If the diameter of the pitch circle is determined as above, then no damage occurs either to the fastening device or to the head of the fastening element or the screw. The reasons for this are described below.

Usually the material from which a screw, bolt or nut is made is standardized so that a compressive strength of is in a range of 45 to 180 kg / mm high2, while the material from which the fastening device is made is standardized so that it has a tensile strength of of 120 180 kg / mm high2. Since the shear or shear strength of these types of material, and in particular of steel, can be regarded as proportional to the tensile strength of these materials, the ratio of the shear or shear strength of the fastening element to the fastening device is in the range from 1.5: 1 to 1: 4 Furthermore, since the shear or shear strength of the fastening element is normally not greater than the shear or shear strength of the fastening device, the ratio is in the range from 1: 1 to 1: 4 The nose or the projection receive the same shear or shear strength if the ratio width of the force-applying part (ie the rib of the concave portion of the fastening device) to the force-transmitting part (ie the nose of the screw head, which engages in the recess between two adjacent ribs ) is in the range from 1: 1 to 1: 4.

The width of the rib approaches the diameter dtief1 of the semicircular cross-section and the width of the recess which is formed between two adjacent ribs is essentially equal to the width of the nose or the projection of the screw head. thats why

In the above equation, ltief1 is the width of the recess of the opening

Fastening device.

On the other hand, the width ltief1 of the recess of the fastening device is substantially equal to the length of the arc part of the larger inner peripheral wall section circle which forms the inner periphery of this recess and can be expressed by the following equation:

Accordingly, the equation (1) is derived from the equations (2) and (3). For example, if the number of ribs is set to six, then the ratio between the diameter of the rib semicircle and the diameter of the larger inner peripheral sectional circle is expressed by the following equation:

0.1 Dlow1 less than or equal to dlow1 less than or equal to 0.25 Dlow1

Typically, large-scale fasteners and fasteners are used that have tensile strengths in the ratio range of 1: 2 to 1: 3. Taking into account the practical usability and economy, the diameter of the semicircular cross-section is accordingly preferably defined by the following equation:

The fitting opening of the fastening device
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At an angle of 1 ° to 10 ° with respect to the central axis of the fastening device and is less tapered with respect to the central axis than the corresponding fastening element. The cross section of the lower end of the opening of the fastening device is designed so that it corresponds to a cross section somewhat above the lower end of the fastening element. This shape of the fastening device allows easy detachment of the fastening device from the form of manufacture and easy engagement of the fastening device on the fastening element. When the fastener is attached to the fastener, it always tightly engages the fastener at a point slightly above the lower end of the fastener. For this reason, the fastening element or the screw cannot fall out of the fastening device due to its weight. This is a particular advantage when fastening elements have to be attached in places that are difficult to reach by hand.

The fastening device according to the invention is explained in detail in the following description with reference to the accompanying drawings.

Fig. 1 is a perspective view of an embodiment of the fastening device according to the invention.

2 and 3 are perspective views of a nut and a screw, respectively, which can be attached by means of the fastening device according to the invention shown in FIG.

Fig. 4
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The illustrated in Fig. 1 fastening device 10 according to the invention consists of a body 11 with a fitting opening 12 formed therein and a handle 13 which extends radially from the body and in
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Kind is trained with this. The fitting opening 12 has a cross section of a larger circle 27 (see Fig. 4), and six ribs 14 are formed on the inner peripheral wall of the fitting opening, which are equally spaced from each other and along this wall. There are recesses 15, which have an arcuate cross-section, between adjacent ribs. The rib 14 is of constant width along its length and extends from the upper surface of the body 11 to the lower surface along the central axis of the body. The cross-section of the ribs is essentially semicircular
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be educated.

2 shows a nut and FIG. 3 shows a screw which can be attached or removed by means of the fastening device 10 according to the invention. Various embodiments of these screws and nuts are described in detail in parallel applications. The nut 16 has a circular cross section, and notches 17, the cross section of which has a semicircular shape, are formed on the outer peripheral wall. The notches 70 are designed to match the ribs 14 of the fastening device, while the lugs or projections 18 formed between two adjacent notches 17 are shaped to match the recesses 15 of the fastening device. In the central part of the nut there is a screw opening 19 coaxial with the central axis of the screw. The head 21 of the screw 20, like the nut 16, has notches 22 and lugs 23. The screw head 21 has on its lower surface a flange-like washer 24 which has a larger diameter than the screw head. A shaft 25 provided with a screw thread extends coaxially from this disk.

4 and 5 show how the corresponding ribs 14 of the fastening device engage in the notches 17 of the nut 16, while the corresponding recesses 15 of the fastening devices engage in the lugs 18 of the nut 16. The threaded shaft 25a is screwed into the nut opening 19. When the fastener is rotated in the direction indicated by arrow A, the effective transmission of the rotational force of the fastener from the rib 14 of the fastener to the nose 18 of the nut required for the "drive angle" must be
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This "drive angle" is defined by
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passes through a point (this is a force-applying point at which the fastener presses the screw head when the screw is tightened or loosened, with a tangential length in the contour of the recess of the fastener at that force-applying point. If the "drive angle" is positive with respect to the direction set by the fastening device, then a force component is generated which leads to insufficient torque being transmitted to the screw head and furthermore to the fastening device sliding off the outer wall of the screw head. Because of this sliding, the possibility is increased On the other hand, if the "drive angle" is 0 ° with respect to the direction set by the fastening device, then the above-mentioned sliding cannot take place and thus an extremely effective over is possible causes the torque to be carried and a good engagement of the fastening device on the screw head or on the nut is obtained. Due to this fact, the aim of the present invention was to design the shape of the ribs 14 of the fastening device in such a way that the "drive angle" is at 0 °, taking into account the direction caused by the fastening device.

FIGS. 6A and 6B schematically show the relationship of a "drive angle" with different central positions of the semicircles in rib cross-sections. The cross-sectional configuration of the fitting opening 12 can be regarded as substantially the same as that of the nut 16. Therefore, in FIGS. 6A and 6B, the contour of the opening and the contour of the nut through the
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It can be seen from FIG. 6A that the central point 0tief1 of the cross-sectional semicircle 26 of the notch 17 of the nut and accordingly of the rib 14 of the fastening device is arranged on the intersection of the tangential lines 28 and 28a, which are tangential to the large circle 27 (the center is indicated with 0) of the fitting opening cross-section are arranged at the intersection points P and Ptief1, the semicircle 26 intersecting the larger circle 27. In this case the point of intersection P is regarded as the force-acting point F when the nut is rotated in the direction indicated by the arrow A and the tangential line to the rib 14 at point P with a radial line together. Therefore, the "drive angle" is 0 ° as in the case of the above example.

If the central point 0tief1 of the semicircle 26 is arranged as described above, then the "drive angle" shows a value of 0 ° with respect to the direction caused by the fastening device. For this reason, the torque transmission efficiency becomes extremely strong
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hinders.

If the central point 0tief1 of the semicircle 26 is located within the circular or bowstring 29, specifically with respect to the central point 0 of the larger circle 27, then the "drive angle" is 0 ° with respect to the direction caused by the fastening device, but the Corners that are defined between the semicircle 26 and the larger circle 27 are very close to the force-acting point, so that the fastening device can be damaged.

In the present invention, in addition to the precise setting of the center of the rib semicircle, attention is also paid to the material quality of the fastening element and the fastening device, so that damage to both the fastening element and the fastening device can be prevented, even if the torque is completely exerted by the fastening device on the fastening element is transmitted.

If the shear or shear forces of the materials used to make the fasteners and fasteners are taken into account, then the ratio of the width of the rib 14 of the fastener to the width of the nose 18 of the nut must be in a range of 1: 1 to 1: 4 or preferably in a range 1: 2 to 1: 3 in order to compensate for the shear or shear resistance of the fastening device and the nut in the vicinity of the force-acting points. From Fig. 4 it can be seen that the ratio between the width 1 of the nose 18 of the nut and the diameter dtief1
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On the other hand, the nose width 1 is substantially equal to the width ltief1 of the recess 15 of the fastening device and this width ltief1 is substantially equal to the arc length of the inner periphery of the recess 15. Therefore, the following equation applies:

Substituting the latter equation in the previous equation gives the following equation:

Since in this embodiment of the fastening device according to the invention the number n of ribs 14 is equal to six, the diameter dtief1 of the semicircle 26 must be defined as follows with respect to the diameter Dtief1 of the larger circle 27:

0.1 D low 1 less than or equal to d low 1 less than or equal to 0.25 D low 1 or preferably

0.12 Dlow1 less than or equal to dlow1 less than or equal to 0.17 Dlow1

If the corresponding diameters of the semicircle and the larger circle are set as above, then the corresponding

Shear strengths of the rib 14 of the
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From Fig. 5 it can be seen that the rib 14 of the fastening device and the recess 15 are inclined at an angle of small alpha and small beta with respect to the central axis o-o of the body 11 of the fastening device. The angles small alpha and small beta are the same and limited to the range of 1 ° less than or equal to small alpha = small beta less than 10 °.

On the other hand, the notches 17 of the nut and the nose 18 of the nut are respectively inclined at angles of small gamma and small theta with respect to the central axis o-o and there is the following relationship with the angles small alpha and small beta:

small alpha = small beta small small gamma = small theta

The maximum distance Ctief1 between the apex of the rib 14, the fastener and the central axis o-o is set as follows with respect to the maximum distance Ctief0 between the bottom of the notch 17 of the nut and the central axis o-o:

Clow1 = Clow0

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For this reason, when the fastener is firmly engaged with the nut, such engagement is effected slightly above the lower end of the nut to prevent the fastener from being easily slipped off or detached from the nut and to continue to engage the nut relatively smoothly Ensure fastening device on the nut.

A fastening device 110 as shown in Fig. 7 has in the central part of its upper portion a recess 30 which has a rectangular cross-section. In this recess, for example, a removable shaft 31 is inserted, which has the same cross section (see FIG. 8). This shaft can be by hand or by another
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Claims (1)

1. Fastening device consisting of a body with a fitting opening which is provided on its inner periphery with a plurality of ribs extending along the central axis of the fitting opening, and with a plurality of recesses located between adjacent ribs, the ribs and recesses of the Mating opening engage with the corresponding grooves and lugs or projections of the fastening element when the fastening device is adapted or used on a fastening element which has a similar cross section as the fitting opening, characterized in that the fitting opening (12, 112) forms a first circle (27) on its cross section, each of the ribs (14, 114) forms at its cross section a partial circle (26) which is curved within the first circle, and the center (Otief1) of the partial circle is located on a corresponding radial line extending from the center (0) of the first circle and within an area of the radial line defined between the latter center and a first intersection point at which the two meet intersect tangential lines (28, 28a), the tangential lines being arranged tangentially to the first circle at the second intersection points (P, Ptief1), at which the first circle intersects the partial circle.
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3. Fastening device according to claims 1 and 2, characterized in that the ribs (14) of the fitting opening (12) are arranged at equal intervals around the fitting opening and the diameter of the rib pitch circle is defined by the following equation: where Dtief1 is the diameter of the first circle, dtief1 is the diameter of the pitch circle and n is the number of ribs. 4. Fastening device according to claims 1, 2 and 3, characterized in that the ribs (14, 114) and the recesses (15, 115) of the fitting opening (12, 112) are inclined in accordance with the central axis (oo) of the fitting opening Angles defined by the following equations: 1 ° less than or equal to small alpha = small beta less than 10 ° small alpha = small beta smaller small gamma = small theta where small alpha represents the angle of inclination of the rib of the fastening device, small beta the angle of inclination of the recess of the fastening device, small gamma the angle of inclination of the notch (17) of the fastening element (10) and small theta the angle of inclination of the nose (18) of the fastening element.
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