DE2749067A1 - Static testing device for screw combined with nut - has screw attached to dynamometer and also attached to adjustable spindle - Google Patents

Abstract

The device comprises a housing (8) an adjustable spindle (12) held in the housing bottom plate (11), a cage (6') connected to the spindle, with an axial bearing (13) in its top side and a dynamometer (3) connected with the axial bearing (13) and with an axial bearing (7b) in the upper cage (6). A nut (5) is non-rotatably mounted in the top part of the cage (6), and an insert (4) is non-rotatably mounted in the housing top (9), and provided with a hole for the shank of the screw of be tested.

Description

description

The invention relates to a device for testing a Nut screwed-in screw or a threaded bolt, the top of which can also be guaranteed by a mother.

Bolt testing is generally done from two perspectives carried out, namely optionally with static or dynamic loading.

The test under static load is usually carried out with simple and inexpensive devices in which the bias of the in a stationary Nut screwed in screw determined with hydraulically working power load cells will. Average values based on experience are used for the total coefficient of friction is used as a basis, although thread and head friction are not considered separately or can be measured. The measurement inaccuracy of such devices is approx. + 2 tO.

For more precise statements, however, more precisely working devices are required; for this purpose the measuring heads are usually equipped with strain gauges, with amplification and display of the specific value taking place electrically. Here Although the head friction torque can also be displayed directly, the test screws must however, remain in the device until it can take several hours Polymerization of the adhesive securing is complete and dismantling takes place can. The thread friction can be calculated. Although such devices are roughly that Four times the simple, above-mentioned and hydraulically operating load cells cost of the equipped test stand, their measurement inaccuracy is still approx. + 1 t.

For the sake of completeness, the check for dynamic Stress must be mentioned. Such so-called "vibration test stands " in principle also contain presetting zero gauges equipped with expansion gauges. At the same time, shaking movements are generated, so that the preload is more dynamic Stress can be measured.

The use of the in screw assembly and also in screw testing The underlying total coefficient of friction ges presupposes that the thread friction coefficient pgew which is often incorrectly referred to as S, is equal to the head friction coefficient pK, because only then is u tot = p = (see also supplement 1).

This basic requirement of screw assembly and screw testing however, experience has shown that this does not always apply.

Strong deviations arise, for example, when the thread is provided with an "adhesive fuse". This adhesive security can either through Filling the thread gap during blontage with a liquid, polymerizing agent Adhesive or by previously coating the thread with microencapsulated adhesive / binder mixtures take place, the capsules are broken open during assembly, so that the components can react with each other and polymerize.

Adhesive securing of this kind is always given in all branches of industry greater importance.

In the meantime, the Necessity of separate consideration and thus also measurement of head and thread friction recognized.

However, this is not possible with the conventional screw testing devices, in which either no coefficient of friction measurements at all or only very complex measurements head friction moments were possible.

The invention is therefore based on the object of a device to the static test of a screw or a threaded bolt of the specified type to create in which the above-mentioned disadvantages do not occur.

In particular, a device is to be proposed that despite a structurally simple structure, the determination of the coefficient of friction with high accuracy enables.

This is achieved according to the invention in that for measuring the bias a device is used which is characterized by a housing, a Adjusting spindle mounted in the base plate of the housing, one with the adjusting spindle connected cage, which has a thrust bearing in the upper part, a force measuring device, which are connected to the thrust bearing and the thrust bearing arranged in the upper cage is, one in the upper part of the cage fixed against rotation and one in the Upper end face of the housing rotatably arranged insert with a Bore is provided for the implementation of the shaft of the screw to be tested.

The advantage of the device according to the invention lies, for example, in the possibility of use known force measuring devices, since with such devices forces with high Accuracy can be determined. There are, for example, conventional tensile and / or compressive force measuring devices suitable for use in the device according to the invention. It is preferred Ring dynamometers, expansion and compression elements with strain gauges or mechanical ones or optical strain measurement, hydraulic or electrical load cells are used. The commercially available ring dynamometers usually have a measurement uncertainty, based on the final value, from '- + 0.2 X on. Despite this extremely high level of accuracy the force measurement such force measuring devices are relatively inexpensive, so that the device according to the invention can be manufactured at relatively low cost.

It is useful for maintenance and repair work as well to change the measuring range exchangeable and twist-proof in the longitudinal direction of the screw displaceable force measuring device between the end face of the screw, so the Shank end of the screw, and an abutment which is arranged by the screw can absorb forces exerted on the dynamometer.

According to a preferred embodiment, both for the support disc Axial bearings that can be fixed for the screw head as well as for the nut are provided, which are arranged in a manner to be explained, so that either the Total coefficient of friction added (see supplement 1) or the thread friction value pGew (see supplement 2) or the head friction coefficient pK (see supplement 3) without major changes in equipment can be determined.

The preload FV achieved in each case is determined by the Force gauge detected and a-shown while simultaneously showing the applied torque is determined. From the preload and the torque, the known Values of the screw then the individual coefficients of friction are calculated.

A removable "test insert" is expediently provided, which can be inserted in a non-rotating assembly table of the device. These Inserts preferably contain the support washer and the thrust bearing for the Screw head. By using several inserts you can use several screws at the same time Be prepared for the test, especially when using adhesive backings is zxieck-like, since a time saving can be achieved in this way.

Through suitable interconnection and movement of the individual parts Finally, other parameters of the screw as well as calibrating torque meters, as follows should be explained.

Preferred embodiments of the device according to the invention are compiled in the subclaims.

The invention is illustrated below with the aid of exemplary embodiments Referring to the accompanying schematic drawing explained in more detail, the only one Figure shows a section through the entire device for testing screws.

In a rigid, cylindrical housing 8 with viewing and operating openings 10 is provided, there is e.g. a commercially available one as the central measuring and display element Force measuring device. Such a single instrument usually has the shape of a closed, perfectly symmetrical ring. Its measuring principle is based on elastic deformation of the ring under the action of the compressive or tensile force to be determined. This deformation, which can be determined as the change in diameter of the ring is a measure of the size of the acting force, the change in diameter from zero to full load is generally on the order of 1 mm.

Such force gauges are available with a measurement uncertainty e.g.

from = - 0.2 7, based on the final value, available ..

The units displayed on a precision fine meter, for example, are unr evaluated using a calibration curve and table provided. Because the calibration curve is practical is a serade, all intermediate values can also be simply interpolated.

Such force measuring devices as well as the d2zug2hörigen joint heads for the coupling of the force to be measured are in different embodiments and in particular available for different measuring ranges, so that by replacing of the dynamometer, for example, covers a total measuring range of 50N to 0.1MN can be.

The dynamometer 3, shown only schematically in the figure, is over Pins 3c in elongated holes 8a secured against rotation, but mounted and axially displaceable between the test unit arranged at the top in the housing 8 and a lower adjustment device clamped.

The upper testing unit receives the screw 1 to be examined, whereby if necessary, the screw 1 is also prepared for the test outside the device can be. For this purpose, the upper end face c of the housing 8 is used as an assembly table formed, in which an opening 9a is provided.

In this opening 9a there is preferably a removable insert 4 secured against rotation.

The insert 4 is provided with a central, cylindrical bore 4a, through which the shaft lb of the screw 1 can be guided so that the landing of the Shank Ib does not bear against the bore 4a.

A lockable axial bearing 7a rests on the insert 4, which also provided with a hole for the passage of the screw shaft 1b is.

Between the fixable axial bearing 7a and the head or the top resting on it Mother la of the screw 1 is finally a support washer 2, which also has a hole for the implementation of the screw shaft lb.

By appropriate selection of the diameter of the holes in the insert 4, the fixable axial bearing 7a and the support washer 2, these parts adapt to different shaft diameters and thus different screw types.

The support plate 2 can be carried out depending on the type of Test can be exchanged, as will be explained in the following.

The preparation of the screws mounted with or without securing means 1 can by means of the removable test insert 4 outside of the actual device done so that the device is not blocked by gravel preparation.

I, ci use of several test inserts 4 including each other Axial bearings 7a and support washers 2 can be used to save considerable time creach. This is especially true when using adhesive backups that have a require a certain polymerization time.

The lower end of the screw shaft lb protrudes through an opening 6a in a cage 6. 1 this cage 6 st a replaceable tar 5 against rotation attached, the thread of which cntspricnt the thread of the screw to be tested 1.

The thread of the nut 5 is arranged so that upon introduction of the screw shaft Ib in the cage 6, the thread of the screw shaft ib in the thread of the nut 5 can be screwed in.

While the nut 5 is at the upper end of the cage 6 is at the lower end of the cage 6 a fixable, so fixable Thrust bearings 7b firmly connected to the cage 6.

The upper force surface 3a of the force gauge 3 lies on the axial bearing 7b on.

As you can see in the figure, there is the force surface 3a at the end of a projection which protrudes through an opening 6b into the cage 6, like this that its end lies with the force surface 3a on the fixable axial bearing 7b lower, deepest area of the dynamometer 3 is also provided with a projection, which protrudes through an opening 6'b into a further cage 6 '. The end of the ledge is designed as a lower force surface 3b, which rests on a thrust bearing 13 that is located in the cage 6 '.

Another opening 6'a is provided at the lower end of the cage 6 ', through which the upper end 12a of an adjusting spindle 12 protrudes into the cage 6 'and is firmly attached there.

In its central area, the adjusting spindle 12 is in one piece a screw head 12c for exerting a torque on the adjusting spindle 12 formed, while the lower end 12b of the adjusting spindle 12 is rotatable via a Thread is mounted in the bottom 11 of the housing 8.

When the adjusting spindle 12 is rotated by exerting a torque The adjusting spindle is thus displaced in its longitudinal direction via the screw head 12c up or down, which also creates a preload the screw 1 can be applied.

Depending on requirements, the adjusting spindle 12 can be both manual and can be operated by machine. This torque is indicated by arrow 15 in the figure indicated.

The torque indicated by the arrow 14 on the screw head la can be operated manually using a calibrated torque wrench or in the case of machine operation via a gearbox with a torque display.

The following are various possible uses of this device will be explained, whereby first the determination of the various above-mentioned Coefficients of friction should be described.

To determine the total coefficient of friction tot, the axial bearings 7a and 7b fixed. Furthermore, the screw 1 is through the holes in the support washer 2, the axial bearing 7a and the test insert 4 out. This operation can also be carried out separately from the device.

Finally, the screw 1 is thus in the thread fixed in the cage 6 the nut 5 is screwed in that the screw head la rests on the support washer 2. The necessary force fit for the test is thus achieved.

When performing the actual test, screw 1 tightened with a controlled torque 14.

The dynamometer 3 shows the pretensioning force FV achieved as a function from the tightening torque hIAan. From the values determined for the preload force FV and the tightening torque MA as well as the known values of the screw can then the total coefficient of friction is calculated from the formulas will the can be found on supplement 1. There is also a sample calculation for specified a specific screw.

Should be at a certain point in time of the exam, i.e. also during of tightening the screw 1, the thread friction pGew must be determined, then the Influence of the head friction K on the overall friction can be eliminated. To this Purpose, the fixed thrust bearing 7a is released, so that this bearing and thus can also rotate the support plate 2 with the screw head la. The one still missing Rolling element friction is so small that it is negligible in practice.

Since the axial bearing 7b remains fixed, the one determined on the dynamometer 3 is determined The preload Fy is influenced by the thread friction, so that the thread friction value pGe from the values for the preload Fy and the tightening torque MA using the formulas can be determined, which can be found in supplement 2. Here too is again an example calculation for a certain screw type is given.

Should determine the head friction at any point in time of the test the thread friction must be switched off. For this purpose, the fixed thrust bearings 7b released, so that when the shaft 1b rotates, the nut 5 and thus also the cage 6 can rotate.

Since the thrust bearing 7a remains fixed, caused by the dynamometer 3 indicated bias voltage FV in this case the head friction torque (MK), so that the head friction pK from the measured values for the preload FV and the tightening torque MA (= MK) can be calculated from the formulas that can be found on supplement 3 can. An example calculation for a specific screw is also given there.

If only the axial bearing 7b is fixed from the start of the test, this takes place assembly without head friction. i.e. only the thread friction on the determined above-mentioned way. At any point during the test, however, head friction can occur can be switched on again to also control the overall friction if required to calculate.

If in the way mentioned above the force fit for the test is achieved in which the screw head la on the replaceable support washer 2 rests, a torque 15 can be exerted on the adjusting spindle 12, whereby it is rotated and thus shifted in its longitudinal direction. To this A pretensioning force can be generated even though the screw 1 and the thread the mother 5 remain stationary. Now you can while in the manner described above any preload that depends on the rotation of the adjusting spindle 12 Fy the current thread friction value pGew or the current head friction value pK or the Total coefficient of friction tot without previous assembly stress on thread and head support be determined.

Furthermore, with the device according to the invention without and Mechanical or cohesive securing devices used with pre-tensioning, e.g. adhesive securing devices, with regard to their effects on head and thread friction, loosening (with mechanical Fuse) and breakaway torque (with adhesive fuse) must be checked.

As is well known, there are also calibration screws and nuts with associated ones Thread. Draw such high-quality, hardened and lubricated elements through a defined surface condition and a guaranteed thread friction value the end.

If the test screw 1 is such a calibration screw and a nut 5 used with the associated thread and the Nopfreib z. B. by selecting one suitable material for the support plate 2 switched off, it can be known from dc Thread friction value pOew and the determined preload FV the tightening torque at any time MA can be calculated from the determination equation in Supplement 2 and Supplement 3 is specified. In this way, a calibration, for example of torque wrenches, possible.

And finally, by using an additional variable speed drive for the adjusting spindle 12 different flange stiffnesses at constant Tightening torque MA can be simulated.

Calculation of the total coefficient of friction Uges The general equation is: 2. Provided that So that is calculated This means: MA = tightening torque (cnkp) Fv = pre-tensioning force (kp) P = thread pitch (cm) according to JSO da = flank # of the bolt thread (cm) Effective radius corresponding to the head friction where Da = Kcpf- (corresponding to 0.9 wrench size for hexagon head screws) D; = Through-hole 4th example for screw M 10 (according to DIN 933) with P = 0.15 cm, d2 = 0. 90 26 cm, D «= 1.7 cm and D; = 1.1 cn: Calculation of the thread friction value; tw The general equation is: accordingly: MA = M pitch + M thread + M head 2. If M head = 0 (because of the axial bearing under the head), then MA = FV '(O, 159.P) + FV .µGew. (C, 578.d2) 3. This results This means: MA = tightening torque (cmkp) Fv = preload force (kp) P = thread pitch (cm) according to JSO da = flank dosing bolt thread (cm) Example for screw M 10 (according to DIN 933) with P = 0.15 cm and da = 0.9026 cm: MA - FV.0.0238 µGew = Fv.0.5217 Calculation of the head friction coefficient UK 1. In the present case, the general equation (see supplementary sheet 1 and 2) omits both the torque components MS slope and M thread. Thus MA = MKhead 2. Thus DKm MA = Fv.µK. (2) can is This means: MA = tightening torque (cmkp) Fv = preload force (kp) Effective radius corresponding to the head friction where Da = head (corresponding to 0.9s5 wrench size for hexagon head screw) D; = Through hole.% 8 Example for screw M 10 (according to DIN 933) with Dα = 1.7 cm and D; = 1.1 cm: r = MA Fv.O, 7107 L eersite

Claims (23)

Device for static testing of screws Patent claims Device for testing a screw screwed into a nut or a threaded bolt, whose upper end can also be guaranteed by a nut, marked by a housing (8), an adjusting spindle mounted in the base plate (11) of the housing (12), a cage (6 ') connected to the adjusting spindle, the upper part of which is a Has axial bearing (13), a force measuring device (3) with the thrust bearing (13) and a thrust bearing (7b) arranged in an upper cage () is connected, a nut fixed against rotation in the upper part of the cage (6) (5) and one in the upper end face (9) of the housing arranged so that it cannot rotate Insert (4) with a hole for the implementation of the shaft to be tested Screw is provided. 2. Apparatus according to claim 1, characterized in that the force measuring device (3) is a compression and tensile force measuring device. 3. Apparatus according to claim 2, characterized in that. the force measuring device (3) a ring dynamometer, an expansion and compression element with strain gauges or mechanical or optical strain measurement, a hydraulic load cell or electrical load cell is. 4. Device according to claims 1 to 3, characterized in that that the force measuring device (3) between the end face of the screw (1) and the Abutment (13, 6 ', 12) is arranged. 5. Device according to one of the paints 1 to 4, characterized in that that the force measuring device (3) is replaceable. 6. Device according to one of claims 1 to 5, characterized in that that the force measuring device (3) is displaceable in the longitudinal direction of the screw (1), however, it is arranged so that it cannot rotate. 7. Device according to one of claims 1 to 6, characterized in that that the upper force surface (3a) of the force measuring device (3) on the thrust bearing (7b) rests. 8. Device according to one of claims 1 to 7, characterized in that that the lower force surface (3b) of the force measuring device (3) on the axial bearing (13) is present. 9. Apparatus according to claim 1, characterized in that the insert (4) is interchangeable. 10. Device according to one of claims 1 to 9, characterized in that that the fixable axial bearing (7b) between the end face of the screw (1) and the force measuring device (3) is arranged. 11. The device according to claim 10, characterized in that the fixable axial bearing (7b) is firmly attached in the cage (6). 12. Device according to one of claims 1 to 11, characterized in that that under the head (la) of the screw (1) there is a support washer (2). 13. The apparatus according to claim 12, characterized in that the Support washer (2) is replaceable. 14. Device according to one of claims 12 or 13, characterized in that that the support disc (2) is arranged on a fixable axial bearing (7a). 15. The device according to claim 14, characterized in that the Support washer (2) and the fixable axial bearing (7a) can be attached to the insert (4) are. 16. Device according to one of claims 1 to 15, characterized in that that the upper end face (6a) of the cage (6), the insert (4), the axial bearing (7a) and the support washer (2) has a hole for the implementation of the shaft (lb) of the have to be tested screw (1). 17. Device according to one of claims 1 to 16, characterized in that that the axial bearing (13) and the upper end (12a) of the adjusting spindle (12) in the Cage (6 ') are arranged. 18. Device according to one of claims 1 to 17, characterized in that that the lower end (12b) of the adjusting spindle (12). in the bottom (11) of the housing (8) is stored. 19. Device according to one of claims 1 to 18, characterized in that that the housing (8) has a cylindrical shape. 20. Device according to one of claims 1 to 19, characterized in that that in the side wall of the housing (8) operating and viewing openings (10) are provided are. 21. Device according to one of claims 1 to 20, characterized in that that in the side wall of the housing (8) elongated holes (8a) are provided in which pins (3c) attached to the force measuring device (3) are guided. 22. Device according to one of claims 1 to 21, characterized in that that the upper end face (9) of the housing (8) is removable. 23. Device according to one of claims 1 to 22, characterized in that that the opening (9a) in the end face (9) of the housing is at least as large as that the cages (6, 6 ') and the force measuring device (3) can be passed through.