WO2015110418A1 - Method for setting a blind rivet nut using a tolerance compensating element - Google Patents

Abstract

Method for setting a blind rivet nut (10), in which method the blind rivet nut is inserted into a hole (12) of a component (14) and compressed into a blind rivet using a screwed-in setting bolt (28). The blind rivet nut is inserted into the hole in a state in which the blind rivet nut is in threaded engagement with a tolerance compensation element (16) that has a drilled hole through which the setting bolt can be inserted through, and said hole has a friction element (36). The method is characterized in that during the screwing in of the setting bolt (28), a friction locking exists between the tolerance compensation element (16) and the setting bolt, and the tolerance compensation element is secured against rotating.

Description

 METHOD FOR SETTING A BLIND NUT WITH

 TOLERANCE COMPENSATION ELEMENT

The invention relates to a method for setting a blind rivet nut, in which the blind rivet nut is inserted into a hole of a component and compressed with a screwed-set pin to a blind rivet and in which the blind rivet nut in the state in which it is inserted into the hole with a Tolerance compensation element is in threaded engagement, which has a bore through which the setting bolt is push-through and which has a friction element.

Such blind rivet nuts with tolerance compensation element serve to connect two components with the help of an inserted into the blind rivet nut connecting bolt with each other. The tolerance compensation element makes it possible to bridge the distance between the components to be connected and to compensate for any distance tolerances. When the connecting screw is screwed into the blind rivet nut, the friction element ensures that the tolerance compensation element is rotated and thereby screwed out of the blind rivet nut, so that it meets the other of the components to be joined. When the tolerance compensation element abuts against this component, the friction element slips through, and the two components with the tolerance compensation element inserted between them can be clamped together.

Basically, in connection devices of this type has the problem that the setting bolt and the connecting screw are screwed one after the other into the same threaded bore of the blind rivet nut, but the friction element as possible only with However, the connecting screw should not cooperate with the setting bolt, because otherwise the tolerance compensation element would be prematurely, when screwing the setting bolt, adjusted in position. In the hitherto conventional methods, therefore, the blind rivet nut without tolerance compensation element is first fixed in one of the components to be connected, and only then is the tolerance compensation element screwed in.

From EP 1 510 701 a connecting device is known in which the friction element first assumes an inoperative position in which it does not interact with the setting bolt, and is transferred to an effective position only after the setting of the blind rivet nut. This allows the tolerance compensation element to be screwed into the blind rivet nut before it is fixed in one of the two components. The advantage is that the blind rivet nut with tolerance compensation element can be provided as a preassembled unit and thus the setting process can be carried out more efficiently.

The object of the invention is to provide further improved method for setting the blind rivet nut, in which in particular a higher tensile force can be exerted on the blind rivet nut to compress them to the blind rivet.

This object is achieved with the features specified in the independent claims. Advantageous developments and refinements of the invention emerge from the subclaims. In the method according to the invention, it is deliberately permitted that a frictional engagement between this setting bolt and the tolerance compensation element already exists when the setting bolt is screwed in. In the blind rivet nut and the tolerance compensation element, therefore, there must be no clearance in which the friction element can be received in an inoperative position. This allows, given a given outside diameter of the blind rivet nut, to increase the outside diameter of the setting bolt and the associated threaded hole in the blind rivet nut. Accordingly, the tensile force which increases during upsetting of the blind rivet nut by the mutually engaging inner and outer threads of the setting bolt and the blind rivet nut can be transferred. In this way, the strength of the blind rivet fastening can be increased or, given a given strength, the connecting device can be made more compact as a whole. In particular, it is possible to reduce the Mindesteinschraublän- ge of the setting bolt in the blind rivet nut, so that the blind rivet nut can be made correspondingly shorter.

However, it must be ensured in the method according to the invention that the frictional engagement between the setting bolt and the tolerance compensation element does not lead to an undesired adjustment of the tolerance compensation element.

According to one embodiment, this problem is solved in that the tolerance compensation element is secured against screwing when screwing the setting bolt. This rotation can be achieved for example by a corresponding design of the setting tool, in which the setting bolt is held rotatably drivable. In a particularly preferred embodiment, the setting tool has a support sleeve which is designed to exert an axial pressure on the tolerance compensation element when the set bolt is screwed in so that it is clamped to the blind rivet nut and / or the component connected thereto. When screwing the setting bolt thus slides through the friction element, so that the tolerance compensation element retains its position. If after setting the blind rivet of the setting bolt is unscrewed, the tolerance compensation element can also be held by means of the support sleeve clamped in position, so that it retains its axial position even when unscrewing the setting bolt and, if it is already in an end position in the Blind rivet nut is also not tightened so tight that it can not be solved later.

Since, as stated above, the invention enables a shortening of the screwing length of the setting bolt into the blind rivet nut, in many cases this screwing length can be selected so short that it is smaller than the required adjustment path for the tolerance compensation element. In that case, according to another embodiment of the invention, it is possible to simply allow the tolerance compensating element to rotate when the setting bolt is screwed in, with the result that the tolerance compensating element unscrews out of the blind rivet nut by a certain distance. If then, after the blind rivet nut was compressed by axially retracting the setting bolt, the setting bolt is unscrewed from the blind rivet nut, the tolerance compensation element is rotated again due to the frictional engagement, so that it screwed back into the blind rivet nut around the way it 5 previously unscrewed.

Depending on the embodiment, however, it is possible that the upsetting of the blind rivet nut leads to a corresponding displacement of the tolerance compensation element. However, this displacement can already be considered in the initial positioning of the tolerance compensation element, so that the tolerance compensation element is in the desired position when the setting bolt has been unscrewed from the blind rivet nut.

In an advantageous embodiment, however, the blind rivet nut and the tolerance compensation element can also be designed such that the axial sections of the blind rivet nut in which the thread engagement with the tolerance compensation element and the thread engagement with the setting bolt take place on opposite sides of the upset zone. This solution has the advantage that the compression has no influence on the axial position of the tolerance compensation element 20 and at the same time allows a very compact design of the entire connecting device.

In the following embodiments are explained in detail with reference to the drawing. Show it:

 OK

 Figures 1 to 5 show various steps of a method for setting a blind rivet nut and for establishing a connection between two components.

FIGS. 6 to 9 show different steps of a method according to another

embodiment; and 10 shows a combination of blind rivet nut and tolerance compensation element, which are designed to carry out a method according to a further embodiment. In Fig. 1, a blind rivet nut 10 is shown in an axial section, which is inserted into a hole 12 of a component 14 and into which a tolerance compensation element 16 is screwed. The tolerance compensation element 16 has the form of a sleeve which has a male thread 18 designed as a left-hand thread, which engages with a corresponding internal thread 20 of the blind rivet nut 10. At the upper end, the tolerance compensation element 16 has a flange 22, which is supported in the state shown in FIG. 1 via a collar 24 of the blind rivet nut 10 on the component 14.

In a smooth, central bore 26 of the tolerance compensation element 16, a setting bolt 28 of a setting device 30 is inserted. The setting pin 28 has in its lower end portion an external thread 32 (right-hand thread) with which it can be screwed into a corresponding internal thread 34 in the bottom of the blind rivet nut 10.

The tolerance compensation element 16 has in the inner surface of its bore 26, a friction element 36, which is formed in the example shown here by an inserted into an annular O-ring. The diameter of this O-ring is dimensioned so that the O-ring is easily squeezed by the outer circumference of the setting bolt 28 or the external thread 32 of the same and thus produces a frictional connection between the setting bolt 28 and the tolerance compensation element 16. The setting device 30 has a drive housing 38 from which a rotatably driven shaft 40 extends, which engages in the setting bolt 28 in a rotationally fixed and axially displaceable manner. A collar 42 of the setting bolt 28 is slidably guided in a cup-shaped support sleeve 44, on the bottom of a thrust bearing 46 is arranged. Between the support sleeve 44 and the drive housing 38, a sensor 48 is inserted, with which an axial pressure force can be measured, which exerts the drive housing 38 on the support sleeve 44.

In Fig. 1, the setting tool 30 has been lowered so far that the setting bolt 28 abuts with its lower end at the bottom of the blind rivet nut 10. If the drive housing 38 is further lowered, the drive housing and the support sleeve 44 alone continue to move down while the set pin 28 stops.

In Fig. 2, the state is reached, in which the support sleeve 44 rests on the flange 22 of the Tole- 5 ranzausgleichselements 16. By hand or by means of a suitable drive, for example a hydraulic or pneumatic drive, a downward force is exerted on the drive housing 38, so that the support sleeve 44 is pressed against the flange 22 and this clamps on the collar 24 of the blind rivet nut 10. The exerted force is measured with the Messaumehmer 48. When this force reaches a value large enough to prevent the tolerance compensation element 16 from turning, the setting tool shaft 40 is driven in a clockwise direction and the setting bolt 28 (which may be slightly biased downwards) is threaded into the internal thread 34 of the blind rivet nut.

In FIG. 3, the setting bolt 28 has been screwed in so far that it completely fills the internal thread 34 of the blind rivet nut. The collar 42 is now on the thrust bearing 46. If now the setting bolt 28 continues to be driven in a clockwise direction, an increased clamping force is exerted on the flange 32 of the tolerance compensation element via the collar 42, the thrust bearing 46 and the bottom of the support sleeve 44, and the same

20, a tensile force is exerted on the bottom of the blind rivet nut by the engagement of the external thread 32 of the setting bolt in the internal thread 34 of the blind rivet nut. Since the setting bolt 28 has a relatively large diameter relative to the blind rivet nut 10, a high tensile force can be transmitted without tearing the thread of the setting bolt and the blind rivet nut.

 OK

Since the upper end of the blind rivet nut 10 is held in place by the flange 22 of the tolerance compensating element supported on the support sleeve 44, the relatively thin-walled portion of the blind rivet nut 10 lying immediately below the component 14 yields to compressive stress and becomes in the position shown in FIG shown manner 30 compressed. In this way, the blind rivet nut 10 is "set", ie, it is tear-resistant fixed to the component 14. In another embodiment, the upsetting of the blind rivet nut 10 can also be effected in that the setting bolt 28 is not rotated, but is axially withdrawn with the aid of the setting device. However, the setting tool should be designed such that the support sleeve 44 thereby remains in contact with the flange 22.

In the next step, the setting bolt 28 is then driven counterclockwise and unscrewed out of the blind rivet nut 10 again. In this case too, the flange 22 of the tolerance compensation element preferably remains clamped between the support sleeve 44 and the collar of the blind rivet nut, so that even in this step, no change in the axial position of the tolerance compensation element 16 occurs. At the same time it is thus prevented that the torque transmitted by the friction element 36, which now due to the left-hand thread tends to screw the tolerance compensation element deeper into the blind rivet nut 10, leads to the tolerance compensation element being tightened too tightly.

When the setting bolt 28 has been unscrewed completely out of the blind rivet nut 10, the setting tool 30 can be pulled off with the setting bolt 28 upwards.

The arrangement of blind rivet nut 10 and tolerance compensation element 16 can then be used to attach another component 50 to the component 14 such that a certain distance is maintained between these two components, as shown in FIG. 5. For this purpose, a connecting screw 52 is screwed instead of the setting bolt 28 in the blind rivet nut 10, but this time the tolerance compensation element 16 is not secured against rotation. In the screwing process, therefore, the tolerance compensation element 16 is taken clockwise, so that it unscrews due to the left-hand thread from the blind rivet nut 10 and the component 50 comes opposite. As soon as the flange 22 abuts against the component 50, the axial movement and thus also the rotational movement of the tolerance compensation element 16 come to a standstill so that upon further screwing in of the connecting screw 52, the friction element 36 slips. Finally, when the head of the connecting bolt 52 abuts against the component 50, the components 14 and 50 are firmly clamped together with the tolerance compensation element 16 inserted between them. The described embodiment can be modified in many ways. For example, it is possible to secure the tolerance compensation element 16 during screwing and unscrewing of the setting bolt 28 not by clamping, but by positive engagement with a suitably trained part of the setting device 30 against rotation.

A further embodiment of the invention will now be explained with reference to FIGS. 6 to 9.

In Fig. 6, the blind rivet nut 10 is shown with a screwed tolerance compensation element 16 ', which differs from the above-described tolerance compensation element 16 especially in that its central bore in the upper portion (above the friction member 36) has an internal thread 54 (right-hand thread). In addition, the diameter of the flange 22 is reduced so far that this flange can be accommodated inside the blind rivet nut 10. Thus, the tolerance compensation element 16 'can sink relatively deep in the blind rivet 16.

A setting device 30 'has in this example a tubular housing 56 which can be placed on the component 14 so that it is supported with its lower end on the component 14 and / or the collar 24 of the blind rivet 10. The housing 56 receives a chuck 58 in which a setting bolt 28 'is rotatably driven and axially extendable and retractable. The setting bolt 28 'is formed in two stages and has an upper portion with an external thread 60 which is complementary to the internal thread 54 of the blind rivet nut 10 and a lower portion with a smaller diameter, whose external thread 32 is complementary to the internal thread 34 of the blind rivet nut.

In the example shown, the depth of engagement of the tolerance compensation element 16 'in the blind rivet nut and the geometry of the setting bolt 28' are matched to one another that the external thread 60 at the moment in the internal thread 54 sums in which the external thread 32 in the internal thread 34 summarizes. This state can be reproducibly produced, for example, by screwing the tolerance compensation element 16 all the way into the blind rivet nut 10, but without firmly attaching it. , C), then insert the set bolt 28 'enough to engage the friction member 36 but not yet reach the internal thread 34 of the blind rivet nut and then let the set pin 28' make a predetermined number of turns clockwise, so that the tolerance compensation element 16 'is unscrewed by a defined amount.

If, starting from the state shown in Fig. 6, the setting pin 28 is driven in a clockwise direction, it is screwed into the internal thread 34 of the blind rivet nut. If in the process the tolerance compensation element 16 'would be held against rotation, the upper section of the setting bolt with the external thread 60 would also be screwed into the internal thread 54 of the tolerance compensation element at the same axial speed. In the example described here, however, the tolerance compensation element 16 'is not secured against rotation, so that the friction element 36 can cause a certain turning of the tolerance compensation element, with the result that the tolerance compensation element is unscrewed from the blind rivet nut 10 and accommodates the upper portion of the setting bolt. The thread pitches of the outer thread 60 and the outer thread 32 of the setting bolt and the thread pitch of the external thread 18 (left-hand thread) of the tolerance compensation element can be selected so that the tolerance compensation element 16 'relative to the blind rivet nut 10 is rotated at a speed at which the axial movement of the setting bolt relative to Blind rivet nut 10, the axial movement of the tolerance compensation element relative to the blind rivet nut and the axial movement of the set pin relative to the tolerance compensation element add each other to zero. For example, the arrangement can be chosen so that the external thread 18 of the tolerance compensation element 16 'has the same pitch as the external thread 32 of the setting bolt, while the external thread 60 of the setting bolt has twice the pitch. The torque generated by the friction element 36 will then cause the tolerance compensation element 16 'rotates relative to the blind rivet nut 10 at a speed which is just one third of the speed of the set bolt 28. If the thread pitch of the external thread 32 is designated by s and the setting bolt 28 executes three full revolutions relative to the blind rivet nut 10, then the setting bolt moves deeper into the blind rivet nut by the distance 3 s. At the same time that leads Tolerance compensation element 16 'a full turn relative to the blind rivet 10, so that it unscrews the distance s from the blind rivet nut. The adjustment of the tolerance compensation element 16 'relative to the set bolt 28' is thus 4s. In this case, the setting bolt has just completed two full revolutions relative to the tolerance compensation element. Two turns multiplied by the thread pitch 2s of the external thread 60 just give the required axial relative movement of 4s.

FIG. 7 shows the state in which the setting bolt 28 'was screwed into the blind rivet nut 10 for the full depth of engagement. The tolerance compensation element 16 'has moved upwards by one third of this way and abuts the lower end face of the chuck 58. As a result, the further screwing-in movement of the setting bolt is counteracted by a resistance which can be detected with the aid of a sensor and then automatically triggers the setting process for swaging the blind rivet nut 10. In this example, the compression is effected by pulling the chuck 58 with the set bolt 28 'held therein upwards with a sufficiently high tensile force.

The transmission of the tensile force from the setting bolt 28 'on the portion of the blind rivet nut 10, which is below the compression zone takes place in this case not only by the engagement of the external thread 32 in the internal thread 34, but also by an additional parallel flow of force from the external thread 60 on the Tolerance compensation element 16 'and its external thread 18 which engages in the internal thread 20 of the blind rivet nut. In this way, a particularly high setting force can be generated.

In order to prevent the tolerance compensation element 16 being clamped too tightly between the blind rivet nut and the chuck 58 of the setting device, a rotation stop 62 (FIG. 6) can be provided on the underside of the chuck 28, which can be used during the last revolution of the tolerance compensation element 16 comes to rest on a corresponding counter-stop 64 in the end face of the flange 22 and so completes the rotation of the tolerance compensation element.

Fig. 8 shows the blind rivet nut 10 in the compressed state. The tolerance compensation element 16 'has moved up the way, which corresponds to the shortening of the blind rivet nut. The setting bolt 28 is then driven counterclockwise and out of the Blind rivet nut 10 unscrewed, whereby the tolerance compensation element 16 is again screwed by the same way in the blind rivet nut 10 to which it was unscrewed at the transition to FIG. 6 of FIG. 7. The result is shown in FIG. The external thread 32 of the setting bolt has emerged from the internal thread 34 and also the external thread 60 from the internal thread 54 of the tolerance compensation element, so that the setting device 30 'can be pulled off with the setting bolt 28' upwards. In a further step, not shown, then, as in FIG. 5, a connecting screw can be screwed into the internal thread 34.

In the initial position in Fig. 6, the tolerance compensation element 16 'has been set so that it lies opposite the collar 24 of the blind rivet nut 10 just about the way that this blind rivet nut is compressed. In this way it can be achieved that after completion of the setting process (FIG. 9), the upper side of the flange 22 is flush with the upper side of the collar 24.

Even if one works with the two-stage setting bolt 28 'according to FIGS. 6 to 9, of course, the tolerance compensation element 16' can be held in a rotationally fixed manner during the setting process. However, the external threads 32 and 60 of the setting bolt must then have the same pitch.

Another conceivable variation of the method is that it works with a setting bolt which corresponds only to the upper part of the setting bolt 28 'with the external thread 60 and has no lower part which passes through the friction element 36 and engages with the internal thread 34. The tensile force for stowing the blind rivet nut is then transferred exclusively via the tolerance compensation element 16 'to the lower part of the blind rivet nut, which has the internal thread 20. A frictional engagement between the setting bolt and the tolerance compensation element 16 'is caused in this case exclusively by the friction of the external thread 60 in the internal thread 54. Since the torque transmitted in this way is relatively small, it is sufficient to press the set screw when screwing into the internal thread 54 with moderate axial force down to prevent co-rotation of the tolerance compensation element. It is also sufficient later when unscrewing the setting bolt when this set bolt is pulled upwards with moderate axial force. Another possible variant of the method and a corresponding design of the blind rivet nut and the tolerance compensation element are shown in FIG. In this variant, a blind rivet nut 10 "is used, which is in the section located above the compression zone and the component 14 with a tolerance compensation element 16" in threaded engagement. The tolerance compensation element 16 "is formed in this case as a sleeve which surrounds the blind rivet nut 10" and designed as a left-hand thread internal thread 66 which is in engagement with a corresponding external thread 68 of the blind rivet nut. As a friction element 36 "a spring ring is provided, which is rotatably held in the flange 22 at the upper end of the tolerance compensation element and two protruding into the interior of the blind rivet nut clamping springs 70 which, when the connecting screw is inserted, frictionally invest on the circumference 10 shows by way of example an arrangement of the rotation stops 72 which prevent over-tightening of the tolerance compensating element on the blind rivet nut 14. As an alternative, on the right-hand side in Fig. 10 a stop ring 74 is shown which performs the same function fulfilled, but with an outwardly projecting flange protrudes beyond the external thread 68 of the tolerance compensation element and thus prevents the tolerance compensation element can be completely detached from the blind rivet nut 10 ".

When setting the blind rivet nut 10 ", the set bolt is inserted through the frictional element 36" serving spring ring and screwed into the internal thread 34 in the bottom of the blind rivet nut, wherein the friction element 36 "produces a frictional engagement with the tolerance compensation element 16". 6 and 9, the tolerance compensation element 16 "is unscrewed a certain way upwards when the setting bolt is screwed in. However, during later unscrewing of the setting bolt, this axial adjustment is reversed again, unlike the embodiment According to FIGS. 6 to 9, the compression of the blind rivet nut 10 "does not lead to a change in the axial position of the tolerance compensation element 16", since this tolerance compensation element is not in engagement with the part of the blind rivet nut located below the upset zone. The embodiment of FIG. 10 allows for a given axial displacement of the tolerance compensation element and for a given tensile strength of Blindnietbefestigung a very compact design, in particular a small axial length of the assembly of blind rivet nut and tolerance compensation element. Accordingly, the setting bolt need only travel a small axial distance, thereby enabling an efficient and energy-saving setting operation. Another advantage of this embodiment is that the blanks for the blind rivet nut and the tolerance compensation element can be made without cutting as drawing parts, in which only the threads need to be cut.

Claims

A method for setting a blind rivet nut (10), wherein the blind rivet nut in a hole (12) of a component (14) inserted and with a screwed-set pin

(28) is compressed to a blind rivet and in which the blind rivet nut in the state in which it is inserted into the hole in threaded engagement with a tolerance compensation element (16) having a bore through which the setting bolt is pushed through and having a friction element (36), characterized in that when screwing the setting bolt (28) has a frictional engagement between the tolerance compensation element (16) and the setting bolt and the tolerance compensation element is secured against turning.

2. The method of claim 1, wherein the tolerance compensation element (16) is thereby secured against turning, that it is clamped between a setting device (30) and the component (14) and / or the blind rivet nut (10) inserted therein.

3. The method of claim 1 or 2, wherein the tolerance compensation element (16) is secured against turning even when unscrewing the setting bolt (28).

4. A method for setting a blind rivet nut (10; 10 "), in which the blind rivet nut in a hole (12) of a component (14) inserted and with a screwed set pin (28 ') is compressed to a blind rivet and in which the blind rivet nut in the state in which it is inserted into the hole in threaded engagement with a Toleranzausgleichs element (16 '; 16 ") having a bore through which the setting bolt is hindurchsteckbar and having a friction element (36; 36") , characterized in that when screwing the setting bolt (28 '), a frictional engagement between the tolerance compensation element (16'; 16 ") and the setting bolt (28 ') and that the tolerance compensation element (16';16") both when screwing as well during later unscrewing of the setting bolt (28 ') can rotate.

5. The method of claim 4, wherein the rotation of the tolerance compensation element (16 ', 16 ") in at least one end position by rotation stops (62, 64, 72, 74) limited.

6. The method of claim 4 or 5, wherein the axial path, the tolerance compensation element (16 ') when screwing and unscrewing the setting bolt (28') travels controlled by one with an external thread (60) provided, screwed in diameter enlarged portion of the setting bolt (28 ') in a corresponding internal thread (54) of the tolerance compensation element (16'), while another portion of this setting bolt is screwed into the blind rivet nut (10).

7. The method of claim 4 or 5, wherein the threaded engagement of the setting bolt in the blind rivet nut (10 ") and the threaded engagement between the blind rivet nut and the tolerance compensation element (16") on opposite sides of a compression zone of the blind rivet nut (10 ").

8. Connecting device with a blind rivet nut (10) and a tolerance compensation element (16 '), for carrying out the method according to one of claims 4 to 6, characterized in that the tolerance compensation element (16') located at a deeper in the blind rivet nut (10) end the friction element (36) and at the opposite end an internal thread (54) into which a threaded portion of the setting bolt (28 ') can be screwed.

9. Connecting device with a blind rivet nut (10 ") and a tolerance compensation element (16"), for carrying out the method according to claim 7, characterized in that a compression zone of the blind rivet nut (10 ") has a portion of this blind rivet nut having an internal thread (34 ) for the setting bolt, separates from a portion having a thread (68) for the tolerance compensation element (16 ").

10. Connecting device according to claim 9, wherein the tolerance compensation element (16 ") is a sleeve with an internal thread (66) having an externally threaded portion of Blind rivet nut (10 ") surrounds and in which the friction element (36") is held on one end of the tolerance compensation element (16 "), which projects beyond the blind rivet nut (10").