WO2005103644A1

WO2005103644A1 - Control device for the quality control of a sheathed cable and suitable control method

Info

Publication number: WO2005103644A1
Application number: PCT/EP2005/004431
Authority: WO
Inventors: Heinrich Heller; Andreas Zapf
Original assignee: Daimlerchrysler Ag
Priority date: 2004-04-27
Filing date: 2005-04-26
Publication date: 2005-11-03
Also published as: DE102004020440B3

Abstract

The invention relates to a control device (1) for the quality control of a sheathed cable (4) comprising at least one traction rope (2) and a pressurised cover (3). Said sheathed cable (4) is fixed to a control frame (5) and is placed under tension by at least one tensioning device (6). Said tensioning device (6) comprises at least one base carrier (8) by which means the tensioning device (6) is fixed to the control frame, a tensioning element (9) for applying a tensile stress to the traction rope (2), a force-sensing device (10) for measuring a tensile stress in the traction rope (2), a position sensor (11), especially a position extension sensor, for measuring the extension of a free traction rope length during the control, and a socket (12) on which the pressurised envelope (3) is supported. The invention also relates to a suitable control method.

Description

Test facility for quality control of a cable pull and suitable test method

The invention relates to a test device for quality testing a cable and a suitable test experience.

In multi-lane motor vehicles without a compressed air brake system, the legally prescribed parking brake device, for example a handbrake, is usually actuated by the driver or an electric servomotor via cable pulls, also called Bowden cables. The driver actuates, for example, in a known manner by pulling a lever arranged on a center console of a motor vehicle or by depressing a corresponding pedal. After an operating time, the actuation path can be extended, so that readjustment of the system is provided. The extension of the actuation path can have two different causes: firstly, an extension of a pull cable of the Bowden cable and, secondly, a compression of a pressure sleeve of the Bowden cable surrounding the cable.

It is an object of the present invention to provide a test device of the type mentioned at the outset, by means of which, in particular, a realistic determination of relevant set-elongation parameters of a cable pull is made possible. It is also an object of the invention to propose a suitable test method.

The object is achieved by the subject matter of claim 1. Advantageous embodiments are the subject of the dependent claims.

The invention is based on the general idea of using a test device with a test frame, on which a course of the cable can be fixed, and with at least one tensioning device for tensioning a tension member and the associated tension rope for quality testing of a rope tension comprising at least one tension rope and a pressure sleeve. The tensioning device comprises a base support with which the tensioning device can be fixed or fixed on the test frame, and a tensioning element arranged at a first end of the base support for introducing a tensile force into a first end of the tension member. Such a clamping element can for example be a nut which is screwed onto a corresponding thread of the tension member.

Furthermore, the tensioning device according to the invention comprises a force measuring device for measuring the force correlating with the tensile stress and a displacement measuring device arranged on a second end of the base support for measuring the extension of the cable pull relative to the pressure sleeve during the test. The pressure sleeve of the cable is supported on a socket arranged at a second end of the base support, through which the cable is simultaneously passed. This support of the bushing can be used to introduce desired pressure forces into the pressure sleeve.

The test frame is made of aluminum profiles, for example, and offers the option of the cable to be tested to be fixed or guided in such a way that the resulting course is the same or at least very similar to an actual course, for example on a vehicle. Here, for example, different course radii and possibly also kinks can be experimentally recorded in a realistic manner. With the test device according to the invention, the cable pulls can be checked for their setting behavior in a practical and cost-effective manner. In this case, both prefabricated cable pulls, ie cable pulls with, for example, vehicle-specific sleeve end pieces, as well as yard goods can be tested with the test device according to the invention.

The test device according to the invention makes it possible to determine an elongation of the pull rope and a compression of the pressure sleeve. In particular, it has been almost impossible to determine parameters combined in this way. By determining the parameters responsible for the deformation behavior of the wire rope hoist, limit values for the setting behavior of the push sleeve can be specified, which are the cause of the required readjustment work, and secondly, quality specifications regarding a limit value for the setting behavior can be transmitted to suppliers. With knowledge of the setting / stretching parameters of the cable pull, the quality of, for example, a parking brake of a vehicle can also be increased, since these parameters can already be taken into account in the design and construction of the parking brake. At the same time, it is conceivable that appropriate instructions for adjusting the parking brake can be included in a checkbook and a maintenance routine can thereby be refined. In addition, such investigations can optimize the routing or routing geometries of the cable pulls, for example in a vehicle. Furthermore, it is conceivable to provide the cable suppliers with specifications regarding the quality of the cables to be supplied, starting with the tender, which makes it possible to compare the part price with the properties of the individual products that are relevant in the vehicle. At the same time, it is also possible to experimentally test a series production for compliance with the properties guaranteed by the supplier, whereby complaints about undesired setting behavior and the resulting costs can be reduced.

The tensioning device expediently has a compression spring which is supported on the one hand on a bearing block and on the other hand on the force measuring device and which is relaxed when the test tension is applied by the tensioning device. The compression spring therefore has no influence on a tension during the test, but prevents the tension cable from snaking in the pressure sleeve when the tensioning device is relaxed and thus falsifying the measurement of a free rope length. At the same time, long-term trials can also be carried out in a particularly realistic manner since, for example, in motor vehicles with a relaxed parking brake, the traction cable is always under a certain basic tension.

According to a preferred embodiment, a measuring head with a contact surface is arranged on a second end of the tension member, on which the displacement measuring device rests and thereby provides a defined reference point for the measurements. Additionally or alternatively, an exchangeable adapter head can be arranged on the measuring head, on which one end of the traction cable is fixed. The interchangeable adapter head offers the great advantage that the tensioning device can be converted in just a few simple steps and thus cable pulls with different trained traction rope ends can be checked. This enables the testing of wire rope hoists, for example of the most varied vehicle types or series, by means of one and the same test facility.

According to an advantageous development of the solution according to the invention, an orientation of the at least one clamping device on the test frame can be set in a test frame level. As a result, the orientation of the two cable ends relative to one another can be chosen almost arbitrarily and, for example, adapted to different courses in different vehicles. At the same time, a swiveling tensioning device also enables the testing of cables with angled cable end pieces. Overall, the flexibility of the test facility with regard to use for different cable pulls and installation situations is increased.

A radius of a curve of the cable can expediently be determined by at least one holder on the test frame. The at least one holder can be arranged in a manner similar to that on a vehicle and thereby generate a holder of the cable on the test frame that is identical or at least closely approximated to a vehicle. This offers the great advantage that testing can be carried out in a particularly practical manner and parameters of particularly high quality and reliability can be determined.

According to a particularly preferred embodiment, the displacement measuring device is designed as a strain gauge. Settling strain gauges make it easier, in particular, to read an elongation, since the change in length by the sagging strain gauge is converted, for example, into a pointer movement of a dial gauge becomes. However, digital setting strain gauges are also conceivable, which additionally increase the reading comfort.

Furthermore, the object is achieved by a test method with the features of claim 11. The test method is used for quality testing of a cable pull comprising at least one pulling rope and a pressure sleeve with a testing device according to one of claims 1 to 10 and is characterized by the following test steps:

Fixing the cable on the test frame in accordance with a predetermined course and connecting it to at least one tensioning device,

Conditioning of the cable pull by defined loading of the pulling rope with a conditioning pulling force and subsequent defined relief of the same pulling rope and / or by defined loading of the pressure sleeve with a conditioning pressure force and subsequent defined release of the same pressure sleeve,

Checking the cable pull by defined loading of the pull cable with a test pull force and subsequent defined relief of the same pull cable and / or by defined loading of the pressure sleeve with a test pressure force and subsequent defined relief of the same pressure sleeve, measurement of a first deformation of the cable pull immediately after complete application of the Conditioning tensile force and / or conditioning compressive force and / or test tensile force and / or test compressive force,

Measuring a deformation of the cable under a defined load and / or after the defined relief. The defined relief can take place completely or to a residual force.

This method makes it possible to achieve the advantages mentioned above in relation to the test device. To determine permanent deformation of the cable pull, a respective measured value is preferably determined after a defined relief time. According to a possible embodiment variant, after the conditioning force and / or the test force have been fully applied, the remaining conditioning force and / or test force remaining as a function of a deformation of the cable after a defined waiting time can be used as measurement parameters for an additional measurement of a further deformation of the cable. According to a further possible embodiment variant, after the conditioning force and / or the test force have been fully applied, the deformation of the cable pull that occurs after a defined waiting time, with the conditioning force and / or test force being kept constant, as measurement parameters for an additional measurement of a further deformation of the cable pull be used. The conditioning force and / or the test force is preferably not introduced suddenly into the cable pull and in particular under a constant force gradient. The cable can be conditioned several times in succession with a constant force or with forces of different sizes. Furthermore, the conditioning force can be the same or different than the test force.

Further important features and advantages of the invention emerge from the subclaims, from the drawings and from the associated description of the figures with reference to the drawings.

It goes without saying that the features mentioned above and those yet to be explained below can be used not only in the combination specified in each case, but also in other combinations or on their own without departing from the scope of the present invention. A preferred embodiment of the invention is shown in the drawings and is explained in more detail in the following description, the same reference numerals referring to identical or functionally identical or similar components.

Show:

1 shows a testing device according to the invention for quality testing of a cable pull,

2 shows a detailed view of the test device in the area of a clamping device,

Fig. 3 shows the tensioning device according to the invention.

According to FIG. 1, a test device 1 for quality testing a cable 4 comprising at least one pull cable 2 and a pressure sleeve 3 has a test frame 5 with which a course of the cable 4 can be determined. The test frame 5 is preferably made of interconnected aluminum profiles and is therefore light in weight. The essentially triangular test frame 5 according to FIG. 1 has a tensioning device 6 at the end of its hypotenuse for tensioning a tension member 7 and the tension cable 2 connected to it. The cable 4 runs from a tensioning device 6 along a first cathete and along the second cathete to the second tensioning device 6 '. The test frame 5 shown in FIG. 1 has the shape of a right-angled triangle, although another, preferably triangular, shape is also conceivable. In addition, it is conceivable that only such a clamping device 6 is arranged on the test frame 5 and the cable 4 on its Clamping device 6 facing away from the test frame 5 is fixed.

One end of the cable 4 is preferably arranged at right angles to the other end of the cable 4 on the test frame 5, a radius of a curve of the cable 4 being able to be defined by at least one holder 18 on the test frame. The holder 18 on the test frame enables the cable 4 to be laid on the test frame 5, which corresponds approximately to an actual laying radius on a motor vehicle. In this way, realistic test conditions are achieved, since the cable 4, which is normally used for a parking brake of a motor vehicle, is mounted on the motor vehicle in a shape similar to the course. The cable 4 can be brought into a forced position by the frame-side holder 18 according to FIG. 1 at the apex such that the resulting installation radius approximately corresponds to a minimum installation radius of the cable 4. In general, the at least one frame-side holder 18 can also be fixed elsewhere on the test frame 5, so that the course of the cable 4 can be individually adapted to different test conditions. The holder 18 can be fixed to the test frame 5, for example, by means of a screw connection or a clip closure.

In order to be able to determine the course of the cable 4 as flexibly as possible on the test frame 5, an orientation of the at least one tensioning device 6 on the test frame 5 can be set in a test frame plane. This also offers the advantage of being able to also test cables 4 with angled end pieces.

As mentioned above, the cable 4 to be tested is preferably a cable of a parking brake. With multi-track power vehicles without a compressed air brake system, the legally prescribed parking brake is generally actuated by such a cable 4, also called a Bowden cable, by the driver or an electric servomotor. Over the course of time, the actuation path may be extended, so that readjustment is provided, particularly in the case of a manually operated system. The extension of the actuation path can, in addition to wear of the respective brake body, have two further causes: on the one hand, the traction cable 2 can stretch due to the applied tensile stress and, on the other hand, the pressure sleeve 3, which surrounds the traction cable 2, can shorten. Both effects combined lead to an extension of a free cable length and thus to an extension of the actuation path.

2 and 3, the tensioning device 6 has a base support 8 with which the tensioning device 6 is fixed to the test frame 5. At a first end of the base support 8 there is a tensioning element 9 for applying a tensile force into a first end of the tension member 7. The clamping element 9 can for example be a threaded nut which can be screwed onto an associated thread of the tension member 7. The tension member 7 is thus displaced along its axis by a rotational movement of the tensioning element 9 and thereby expands the tension rope 2. The tensioning element 9 is supported here according to FIG. 3 at the first end of the base support 8.

A force measuring device 10 for measuring the tensile force correlating with the tensile stress is arranged in the further course of the tensile member 7. The force measuring device 10 is preferably integrated in the tension member 7. In the further course of the tension member 7, the tensioning device 6 has a compression spring 13, which is supported on the one hand on a bearing block 14 and on the other hand on the force measuring device 10 and is relaxed when the test force is applied by the clamping device 6. The bearing block 14 supports the tension member 7 axially displaceable transversely to the tension.

The compression spring 13 prevents the relaxed tension cable 2 from meandering into the pressure sleeve 3 and thus the measurement of the free tension cable length is falsified. In addition, the compression spring 13 ensures a particularly practical test of the cable 4, since even with cables 4 installed in the usual way, a certain basic tension remains on the cable 2 even when the parking brake is released.

At an end of the tension member 7 facing away from the tensioning element 9, a measuring head 15 with a contact surface 16 is arranged thereon, against which a sensor of a displacement measuring device 11 bears. The distance measuring device 11 itself is arranged at a second end of the base support 8 and is designed to measure the extension of the cable 4 or a free cable length during the test. The measurement of the length of the pull rope measured here results, as mentioned above, on the one hand from an extension of the pull rope 2 and on the other hand from a compression of the pressure sleeve 3. On the measuring head 15, an interchangeable adapter head 17 in the form of a fork head can be arranged, on which one end of the pull rope 2 is fixed and which allows a simple exchange of the clevis 17 to test different cable ends of different cable 4 with the test device 1 according to the invention.

At the second end of the base support 8, a bushing 12 is arranged in the region of the displacement measuring device 11, on which the pressure sleeve 3 is supported and through which the pull cable 2 is guided. The cable 4 is connected to the tensioning device 6 in the area of the bushing 12 similar to the connection of a Bowden cable to a parking brake.

The displacement measuring device 11 is preferably designed as a setting strain gauge, which makes it much easier to read the extension of the free cable length, since the setting strain gauge converts the extension into a pointer movement. Digital setting strain gauges are also conceivable, which output the determined strains in the form of numbers on a display.

With the test device 1 according to the invention, it is possible to experimentally record a combined setting elongation of the cable 4 and thereby to make specifications regarding the quality of the cables 4. The test device 1 can both prefabricated cables 4, d. H. Cable 4 with vehicle-specific sleeve end pieces, check, as well as unassembled yard goods. In general, this makes it possible to compare a part price with the properties of the individual products that are relevant to the vehicle and to carry out an experimental check of series production for compliance with certain quality characteristics. At the same time, it is also possible to take into account a specific setting behavior of the cable pulls 4, as determined by the test device 1, when manufacturing the parking brakes.

In the following, a test method is to be briefly explained, by means of which a set elongation behavior of the cable 4 on the test device 1 according to the invention can be determined.

In a first method step, the cable 4 is fixed on the test frame 5 in accordance with a predetermined course on a motor vehicle and connected to at least one tensioning device 6. This is followed by conditioning the Cable 4 by repeatedly introducing a tensile force into the cable 2 and a subsequent defined relief. The cable 4 is brought into a defined state by the load and relief, whereby the following measurements are reproducible. It is then determined by how much the free rope length increased during conditioning. This result can be used to predict whether conditioning the cables 4 after vehicle assembly with subsequent readjustment of the parking brake appears to make sense.

In a further method step, the cable 4 is loaded with a defined test force and the setting behavior of the pressure sleeve 3 or a loss of force is determined. It is also possible to measure a relation time. The cable 4 is then relieved and a return deformation is determined.

This is followed by renewed loading with a defined test force, from which a change in the setting behavior compared to the previous section is determined.

In general, the values determined in this way allow estimates to be made of how strong the cable 4 is capable of holding and how its deformation behavior in the vehicle will be. In this way, a cable 4 can be checked experimentally for the most important setting / stretching properties without the need for a vehicle. In addition, cable pulls 4 made of yard goods can be compared with one another in a standardized manner without having to refer to a specific vehicle type. This is particularly important for benchmark investigations and inquiries for new vehicle series, in which the corresponding slump / elongation measures have not yet been defined. In summary, the essential features of the solution according to the invention can be characterized as follows:

The invention relates to a testing device 1 for quality testing of a cable 4 comprising at least one traction cable 2 and a pressure sleeve 3. The cable 4 is fixed to a test frame 5 and tensioned by means of at least one tensioning device 6. The tensioning device 6 comprises at least one base support 8, with which the tensioning device 6 is fixed to the test frame, a tensioning element 9 for applying a tensile force to the pulling rope 2, a force measuring device 10 for measuring a pulling force in the pulling rope 2, a displacement measuring device 11, in particular a setting strain gauge , to measure the extension of a free cable length during the test and a socket 12 on which the pressure sleeve 3 is supported.

The test device 1 can be used to determine specific slump dimensions for the pressure sleeve 3 or elongation dimensions for the pull cable 2, and thereby to determine specific quality requirements for the cable pull 4. Both pre-assembled cable pulls 4 - that is, cable pulls that have been cut to length and have associated, possibly different end pieces for the corresponding pulling cable and the pressure sleeve - as well as goods by the meter can be tested, as a result of which the use of the test device 1 is particularly flexible. At the same time, the test frame 5 allows the cable 4 to be routed in a manner similar to a cable installed on the motor vehicle, so that the test device 1 and the associated method can be used to determine particularly realistic and reliable test results.

Claims

claims

Test device (1) for quality testing of a cable pull (4) comprising at least one pull cable (2) and a pressure sleeve (3),

- With a test frame (5), with which a course of the cable (4) can be determined,

- With at least one tensioning device (6) for tensioning a tension member (7) and the tension rope (2) connected to it,

- The tensioning device (6) comprises at least the following components:

a base support (8) with which the tensioning device (6) is fixed to the test frame (5),

a tensioning element (9) arranged at a first end of the base support (8) for applying tension to a first end of the tension member (7),

a force measuring device (10) for measuring the tensile force correlating with the tensile stress,

a displacement measuring device (11) arranged on a second end of the base support (8) for measuring the extension of the cable pull (4) relative to the pressure sleeve (3) during the test,

- A at the second end of the base support (8) arranged socket (12), on which the pressure sleeve (3) is supported and through which the pull cable (2) is passed.

2. Testing device according to claim 1, characterized in that the tensioning device (6) has a compression spring (13) which is supported on the one hand on a bearing block (14) and on the other hand on the force measuring device (10) and when applied by the tensioning device (6) Test voltage is relaxed.

3. Testing device according to claim 1 or 2, characterized in that - at a second end of the tension member (7), a measuring head (15) with a contact surface (16) is arranged, on which the displacement measuring device (11) rests, and / or - that an interchangeable adapter head (17) is arranged on the measuring head (15), on which one end of the traction cable (2) is fixed.

4. Test device according to one of claims 1 to 3, characterized in that the one end of the cable (4) is arranged substantially at right angles to the other end of the cable (4) on the test frame (5).

5. Test device according to one of claims 1 to 4, characterized in that a radius of a curve of the cable (4) can be determined by at least one test frame-side holder (18).

6. Test device according to claim 5, characterized in that - the cable (4) is a cable of a parking brake of a vehicle, - that the course and / or the radius of the curve of the cable (4) on the test frame (5) is approximately an actual one Verlegradius corresponds to the vehicle.

7. Test device according to one of claims 1 to 6, characterized in that an orientation of the at least one clamping device (6) on the test frame (5) is adjustable in a test frame level.

8. Test device according to one of claims 2 to 7, characterized in that the bearing block (14) supports the tension member (7) transverse to the tension.

9. Testing device according to one of claims 1 to 8, characterized in that the displacement measuring device (11) is designed as a strain gauge.

10. Testing device according to one of claims 1 to 9, characterized in that the force measuring device (10) is integrated in the tension member (7).

11. Test method for quality testing of a cable (4) comprising at least one traction cable (2) and a pressure sleeve (3), with a test device (1) according to one of claims 1 to 10, characterized in that the test method comprises the following test steps: 11.1 Specify of the cable (4) on the test frame (5) in accordance with a predetermined course and connecting to at least one tensioning device (6), 11.2 conditioning the cable (4) by applying a conditioning traction force to the traction cable (2) and subsequently defining it Relief of the same pull cable (2) and / or by applying a conditioning pressure force to the pressure sleeve (3) and then relieving the same pressure sleeve (3) in a defined manner,

11.3 Checking the cable (4) by applying a test tractive force to the pull cable (2) and then releasing the same pull cable (2) and / or by applying a test pressure force to the pressure sleeve (3) and then relieving it Pressure sleeve (3), 11.4 Measuring a first deformation of the cable (4) immediately after the conditioning tensile force and / or the conditioning compressive force and / or the test tensile force and / or the test compressive force have been applied completely, 11.5 Measuring a deformation of the cable pull (4) under a defined load and / or after the defined relief.

12. Test method according to claim 11, characterized in that in order to determine a remaining deformation of the cable pull (4), a respective measured value is determined after a defined relief time.

13. Test method according to claim 11 or 12, characterized in that after complete application of the conditioning force and / or the test force, the remaining conditioning force and / or test force remaining as a measurement parameter for an additional measurement depending on a deformation of the cable pull (4) after a defined waiting time further deformation of the cable (4) can be used.

14. Test method according to claim 11 or 12, characterized in that after complete application of the conditioning force and / or the test force, the deformation of the cable pull (4) which occurs after a defined waiting time, with the conditioning force and / or test force being kept constant, is used as a measurement parameter for an additional measurement of a further deformation of the cable pull (4).

15. Test method according to one of the preceding claims 11 to 14, characterized in that the conditioning force and / or test force are not introduced abruptly and in particular under a constant force gradient into the cable pull (4).

16. Test method according to one of the preceding claims 11 to 15, characterized in that the conditioning of the cable (4) is carried out several times in succession with a constant force or with forces of different magnitudes.

17. Test method according to one of the preceding claims 11 to 16, characterized in that the conditioning force is the same size or different size as the test raft.