DE102017007008A1 - Test device and method for testing and / or setting a proper installation position of a control arm in a vehicle - Google Patents

Abstract

The invention relates to a test device (1) for testing and / or setting a proper installation position of a control arm in a vehicle, with a base body (3), and one with the base body (3) along a test direction relative to the base body (3) displaceably connected Inspection element (5). It is provided that the test element (5) is biased into a test position, wherein on the base body (3) a first contact element (9) for abutment of the base body (3) is arranged on a first test object, and wherein on the test element (5 ) is arranged a second contact element (11) for abutment of the test element (5) on a second, different from the first test object test object.

Description

The invention relates to a test apparatus and a method for testing and / or setting a proper installation position of a control arm in a vehicle.

From the German patent application DE 10 2009 048 186 A1 a device for mounting a link member, in particular a transverse link of a vehicle is known. In particular upper wishbones are held by means of such a special assembly pliers in a desired, optimal installation position, which may correspond in particular to a sprung position of the control arm and is typically referred to as K0 position, with the assembly pliers are supported on bearing blocks for the wishbone laterally biased and simultaneously holds a screw, by means of which the wishbone is screwed to the bearing block by means of a screw, preferably a so-called hold and drive screwdriver. The assembly pliers is pushed to take their position of use along a Federbeindomes and is supported on a flat surface at a contact point of the Federbeindomes. In this case, it is subject by the associated with the sliding friction on the dome wall wear that deteriorates their dimensional stability and with progressive wear causes the wishbone is no longer held in the correct, predetermined position. It is therefore necessary to check the relative position of the control arm relative to the strut tower. For this purpose, known gauge bars are used, which are placed on the wishbone by hand, and with which a distance to a defined measuring point on Federbeindom near a passage opening of a shock absorber is checked by the Federbeindom. However, this test method is inaccurate, especially since due to the manual handling of these dipsticks a tolerance factor must be taken into account. To make matters worse, a worker checking the control arm must at the same time hold such a dipstick and the control arm, which results in further inaccuracies.

The invention has for its object to provide a test apparatus and a method for testing and / or setting a proper installation position of a control arm in a vehicle, said disadvantages do not occur.

The object is achieved by providing the subject matters of the independent claims. Advantageous embodiments emerge from the subclaims.

The object is achieved, in particular, by providing a testing device for testing and / or setting a suitable mounting position of a transverse link in a vehicle, which has a main body and a test element displaceably connected to the main body along a test direction relative to the main body. It is provided that the test element is biased in a test position. A first abutment element for abutment of the main body on a first test object is arranged on the main body, and a second abutment element for abutment of the test element on a second test object different from the first test object is arranged on the test element. Characterized in that the test element is biased into the test position, wherein at the same time the first contact element on the first test object and the second element can be applied to the second test object, it is possible to clamp the tester between the test objects, so that they automatically between the test objects tense and can be positioned there, without the need for a manual holding of the tester by the worker. The tester must therefore no longer be held by the operator by hand during the testing and / or setting the intended installation position of the control arm. This simplifies the test and in particular the adjustment of the control arm, whereby additional manual inaccuracies are avoided. In addition, the test and / or adjustment, which previously had to be performed with three different length limit bars and additionally an adjustment aid, now be carried out solely using the one tester.

The test device is preferably designed as a test gauge.

The test apparatus is in particular designed for testing and / or setting the intended installation position of an upper vehicle control arm.

A test direction is understood to mean a defined direction in which the test element displaceably connected to the main body can be displaced relative to the main body. This is preferably a longitudinal direction of the test element, which is preferably elongated, that is, has a length which is greater than a width and a height of the test element, wherein the test direction is preferably at the same time a longitudinal direction of the body, which preferably also elongated is formed, wherein it has a length which is greater than its width and its height. It is basically irrelevant in which directions the perpendicular dimensions of length, width and height are measured. The important thing is that the Base body and / or the test element along one direction has a greater extent / than along the two perpendicular to this one direction directions. This direction, in which the main body and / or the test apparatus has / has the longest extent, is referred to as the longitudinal direction and the extent along this longitudinal direction as the length, wherein the expansions perpendicular to this longitudinal direction are referred to as width and height. The test element on the one hand and the base body on the other hand therefore preferably have the same longitudinal direction.

Preferably, the test element is designed as a test rod or as a test rod.

A test position is understood to be a position of the test element in which it projects beyond a boundary edge of the main body; The test element is thus biased in particular in the direction of a maximum extended relative to the base body position. This makes it possible to clamp the test apparatus between the first test object and the second test object. The test element can be retracted, in particular relative to the base body against the bias, preferably displaced into the main body into it.

The first test object is preferably selected from a group consisting of the transverse link and a different from the wishbone vehicle part, in particular a strut tower. The second test object is preferably also selected from this same group, which is the other test object from this group, which is not the first test object. So is the first test object of the control arm, the second test object is the different from the wishbone vehicle part - and vice versa.

According to one embodiment of the invention, it is provided that the main body has a guide, in which the test element is guided along the test direction. This allows a particularly stable relative displacement of the test element exactly along the test direction relative to the main body. Preferably, the guide has a longitudinal recess in the base body, in which the test element is at least partially arranged and displaceable. It is possible that the longitudinal recess has an L-shaped edge, preferably two opposite, lateral, L-shaped edges, wherein the test element can be supported on the at least one L-shaped edge in two directions. If two-sided, L-shaped edges are provided, the test element can be supported on both sides in two directions, being displaceable along the third direction, namely the test direction. The guide can also be designed, for example, as a dovetail guide.

According to one embodiment of the invention it is provided that the base body and / or the test element has / have a measuring device, wherein the measuring device is arranged and arranged such that a dependent on a distance between the first contact element and the second contact element distance depending on a Relative position of the test element relative to the body readable or readable. If the first contact element on the first test object and the second contact element on the second test object, so a relative position between the first test object and the second test object can be determined at the same time, especially since the distance measure just correlated with the distance of the first test object of the second test object , Preferably, the distance between the first test object and the second test object can be determined directly as the distance between the first contact element and the second contact element. However, the distance measure does not have to correspond exactly to this distance, but rather it is possible for the testing device to be arranged at an angle to a direction along which a distance between the test objects is actually to be determined, in which case this angle is preferably taken into account accordingly in the measuring device becomes. The measuring device may, in particular, have a non-linear scale for the distance dimension which takes this angle into consideration, or it may take into account a functional relationship between the distance measure and the distance to be determined by a suitable transformation, in particular a linear or non-linear transformation.

The measuring device allows a precise determination of the desired, predetermined position of the control arm relative to the strut tower and can therefore be used in particular for adjusting the intended installation position in the assembly of the control arm. This does not rule out that the measuring device can also be used to quickly check the intended installation position.

According to a preferred embodiment, the measuring device is designed as an electronic device. It is possible that the distance measure - or directly the distance - in this case can be read digitally by a suitable display. Alternatively or additionally, the distance dimension - or directly the distance - can also be read out of the measuring device electronically, in particular via a wired connection or a wireless connection, preferably via a USB connection, an optical connection, in particular a Infrared interface, a wireless connection, in particular a Bluetooth connection, a WLAN connection or the like.

According to one embodiment of the invention, it is provided that the measuring device is designed as a measuring scale or has a measuring scale. In this case, the measuring device is preferably designed analogously. It may be a dial gauge, or a simple, linear scale attached, for example, to the body or the test element or printed on the body or the test element, embossed into the body or the test element, or in any other way on the body or the test element is provided. The element selected from the basic body and the test element, which does not have the measuring scale, preferably has a position mark, so that the relative position of the test element relative to the main body can be read by reading the position of the position mark relative to the measuring scale. The position mark may be, for example, a dash, a point, an edge of the test element, for example its end edge arranged in or on the main body, or another suitable element. With such a scale, it is easy to read whether and how precisely the test objects are aligned relative to each other, especially with regard to the position of the control arm to the strut tower, so if necessary, resulting from closure tolerances of a mounting device for mounting the control arm very precisely by standardized intermediate layers , Shims particular platelets, can be compensated, which then allows the setting of an optimal mounting position for the wishbone.

Particularly preferably, a vernier is additionally integrated in the measuring scale for an even more precise measurement.

According to one embodiment of the invention, it is provided that the main body or the test element has a plurality of adjacent adjacent, differently colored marked areas, wherein the other part selected from the test element and the base body, a position mark, the relative to a displacement of the test element to the body along the sequence of marked areas is displaced. The position mark may in particular be the same position mark already provided for reading the measurement scale. A coarse determination of the relative position of the test element to the main body is possible by means of the adjacent regions, which are marked in different colors, so that it is possible to quickly check whether the intended installation position of the transverse link is at least roughly maintained relative to the spring strut. The areas marked in different colors can be designed to be particularly intuitive if they are marked in the manner of a traffic light, with a green area indicating good agreement with the intended installation position, with a yellow area indicating, for example, a tolerance range in which the relative position of the transverse link relative to the Federbeindomnahe is at an upper or lower tolerance limit, and wherein a red area indicates an intolerable deviation from the intended installation position. The regions of different colors can be provided, in particular, alternatively or in addition to the measurement scale, separately from or superimposed on it.

According to one embodiment of the invention, it is provided that the test device has a locking device, wherein the locking device is arranged to set the test element relative to the main body. In particular, the locking device is arranged to fix the test element relative to the base body. The locking device may be formed in a preferred manner as a locking screw, which preferably cooperates with a thread in the body and can be screwed against the test element to clamp this in or on the body. Conversely, the locking screw can be removed from the test element, so that it is displaceable relative to the main body. The test element is preferably independent of its position, that is fixed in any relative position by the locking device. This makes it possible to use the test device at least optically to read the same inaccessible places, where it is placed only at such a location, in which case the locking device is actuated to fix the test element relative to the base body, and then the test device the optically inaccessible area again removed and evaluated outside the same, in particular read. The locking device can also be used in low light conditions or inappropriate ergonomics.

According to one embodiment of the invention, it is provided that at least one contact element, selected from the first contact element and the second contact element, has a planar contact surface on which the test direction is perpendicular. In this way, the contact surface can be arranged very accurately on a preferably flat surface or a measuring range of a test object provided for this purpose, in particular if the test object has no projections, recesses or the like, which could contribute to a defined positioning of the contact element. The planar bearing surface may be provided by the main body or the test element itself. But it is also possible that the flat contact surface is provided by a disc which - preferably releasably - with the main body or the test element is connectable. In particular, it is possible to provide a disk which can be attached, in particular clipped or clipped onto an abutment element otherwise provided on the main body or on the test element. At a contact element, which in itself has no flat contact surface, then a flat contact surface can be provided by means of the attached to the contact element disc.

Alternatively or additionally, the at least one contact element preferably has a holding element which is designed as a positive-locking element and / or as a magnetic holding element. With a form-locking element, the contact element can be arranged securely and accurately positioned on a test object, in particular if the positive-locking element is tuned to a correspondingly configured counter-form-fitting element on the test object. A magnetic holding element can be used in particular if the corresponding test object has magnetic properties, in particular can be magnetized. This is the case in particular with a closure lid of a ball joint arranged on the upper wishbone, which is made of steel. By means of the holding element, the contact element can interact positionally secure with the corresponding test object.

Alternatively or additionally, it is provided that the at least one contact element has a ball head. Such a ball head is a particularly favorable embodiment of a form-locking element, wherein the ball head can engage in a suitable recess on a test object, in this way the contact element can be arranged positionally secure to the test object. Particularly preferably, the second contact element, which is arranged on the test element, on such a ball head. This can preferably immerse in a blind hole of a spring leg dome, which forms a receptacle for the ball head. As a result, the test device is centered and can also be solved without hooking again.

Alternatively or additionally, it is preferably provided that the at least one contact element has a three-point support. Such a three-point support can also serve in a special way for the positionally reliable arrangement of the contact element on a test object.

Alternatively or additionally, it is preferably provided that the at least one contact element is detachably fastened to the base body or to the test element. In this way, a modular system can be provided, wherein different contact elements, in particular differently configured contact elements, can be optionally attached to the main body or to the test element, in particular to be able to use the test device in connection with different vehicles and / or different series of vehicles. An example of such an abutment element which can be fastened detachably to the main body or to the test element is the above-described disk, which is particularly preferably attached to a further abutment element or directly to the main body or the test element, in particular clipped or attached thereto.

Alternatively or additionally, it is preferably provided that the at least one contact element is mounted pivotably relative to the base body or relative to the test element. Particularly preferably, the first contact element is pivotally mounted relative to the main body. This allows pivoting of the abutment element from an abutment position in a rest position, wherein the test device with the arranged in the rest position contact element preferably folded flat in a simple manner and can be stored in a holster or case. In the contact position, the contact element is preferably aligned obliquely or perpendicular to the longitudinal direction of the base body and / or the test element, while in the rest position preferably at least substantially parallel, preferably parallel, aligned with the longitudinal direction of the base body and / or the test element, so the test device is designed to be particularly flat in the rest position of the contact element.

The abutment element is preferably pivotally connected by means of a hinge to the main body or the test element. Particularly preferably, the first abutment member is pivotally mounted relative to the base body on the base body, more preferably connected via a hinge pivotally connected to the base body.

The object is also achieved by providing a method for testing and / or setting an intended installation position of a control arm in a vehicle, the method comprising the following steps: A test device according to one of the embodiments described above is between a first test object and a second test object arranged. The test device is applied with the first contact element to the first test object and with the second contact element on the second test object, preferably supported, wherein the test device between the first test object and the second test object is braced. A distance measure between the first test object and the second test object is determined by means of the test device. This can be done in particular due to the tension of the test apparatus between the first test object and the second test object, without a worker must keep the test device permanently. In particular, the advantages that have already been explained in connection with the test apparatus are realized in connection with the method.

The distance measure, which in particular is the distance between the first test object and the second test object-measured along a predetermined direction-itself, or a distance arranged, for example, at an angle to this direction in which the distance is to be measured, may optionally be direct be read on the tester, especially if it has a suitable measuring device. However, it is also possible first to tension the test device between the first test object and the second test object, then to actuate the locking device of the test device, then to remove the test device again, and finally to disconnect the measuring device outside the first test object and the second test object or to take a suitable measure of the test device itself.

According to one embodiment of the invention, it is provided that a distance measure between an upper control arm of a vehicle and a predetermined location on a strut tower of the vehicle is checked and / or adjusted. In this case, the advantages already described are realized.

The invention will be explained in more detail below with reference to the drawing. The single figure shows a schematic representation of an embodiment of a test device for testing and / or setting a proper installation position of a control arm in a vehicle.

The single figure shows a schematic representation of an embodiment of a test apparatus 1 , which is set up for testing and / or setting a proper installation position of a control arm in a vehicle. The tester 1 is designed in particular as a test gauge. It has a basic body 3 and one with the main body 3 along a vertical in the figure test direction relative to the body displaceable connected test element 5 on. The test element 5 is - preferably biased by a spring element, not shown here - in the direction of a test position in which the test element 5 preferably at most far, in particular up to a stop, over an upper edge 7 of the basic body 3 out - in the figure up - is shifted. Against the bias is the test element 5 here in the main body 3 into relocatable.

At the base body 3 is a first investment element 9 arranged, which is adapted to the plant of the body 3 on a first test object, which is selected from the control arm and a different from the wishbone vehicle part, in particular a strut tower. On the test element 5 is a second investment element 11 arranged, which is arranged to create the test element 5 at a second, different from the first test object test object, which is in particular the other element selected from the different from the wishbone vehicle part, in particular the strut tower, and the wishbone, which is not the first test object.

The main body 3 has a guide here 13 on, in which the test element 5 guided along the test direction. The leadership 13 is here in particular as a longitudinal recess in the body 3 formed, in which the test element 5 is guided.

In the embodiment shown here, the main body 3 a measuring device 15 which is arranged and arranged such that one of a distance between the first abutment element 9 and the second abutment element 11 dependent distance as a function of a relative position of the test element 5 relative to the main body 3 is readable or readable. The measuring device 15 may alternatively or additionally also on the test element 5 be arranged. In the embodiment shown here, the measuring device 15 as a measuring scale 17 educated. It is possible that this additionally has a vernier scale for a higher accuracy. The measuring device 15 but can also be designed as electronic measuring device. It is also possible that the measuring device 15 has a dial gauge or other analog display instrument.

In the embodiment shown here, the main body 3 a plurality of areas adjacent to each other in different colors marked areas 19 on, with the test element 5 a position marker 22 which, upon a displacement of the test element 5 relative to the main body 3 along the sequence of marked areas 19 is relocatable. In this way, a coarse determination of the relative position of the control arm to the strut tower can take place without the measuring device 15 must be read exactly.

The position mark 22 can also be used at the same time to determine the position of the test element 5 on the measuring scale 17 read. In the embodiment shown here, the position mark 22 as the lower edge of the test element 5 educated.

The color coding of the different areas 19 may in particular according to Art a traffic light. This is how green areas can be marked 21 identify the intended installation position within a predetermined range, with yellow marked areas 23 a position in an optionally still tolerable, but preferably by means of a more accurate measurement, in particular by means of the measuring device 15 to represent area to be checked while red marked areas 25 Mark a no longer tolerable deviation from the intended installation position.

The tester 1 preferably has a locking device 27 , here in the form of a locking screw, on, with the locking device 27 is set up to position the item 5 relative to the main body 3 to fix, in particular to fix.

In the embodiment shown here, the second contact element 11 designed as a ball head, which is in particular adapted to engage in a corresponding recess, in particular a blind hole of a spring leg dome.

The first investment element 9 is here as a magnetic holding element 29 formed, in particular as a plate of a magnetizable material on which a plurality of magnets is arranged, here a total of three magnets 31 of which two magnets 31 facing the viewer and another magnet through the body 3 is covered. The first investment element 9 is preferably relative to the main body 3 pivotally mounted, in particular by means of a hinge, not shown here.

As an alternative to the specific embodiment shown here, it is possible that at least one of the contact elements 9 . 11 has a flat contact surface on which the test direction is vertical. It is also possible that one of the investment elements 9 . 11 a holding element designed as a positive-locking element. It is also possible that one of the investment elements 9 . 11 has a three-point support. At least one of the contact elements is preferred 9 . 11 detachable on the base body 3 or on the test element 5 fixable. In particular, it is possible to provide a modular system with different contact elements, depending on the specific design of the test objects on the body 3 and the test element 5 can be attached. In particular, it is possible to provide different discs, which on the second holding element designed as a ball head 11 attached, in particular clipped to this or can be clipped on this.

An embodiment of a method for testing and / or adjusting the intended installation position of the control arm in the vehicle provides that the test device 1 between a first test object and a second test object, namely in particular between the wishbone and the spring strut, is arranged, wherein the test device 1 with the first investment element 9 on the first test object, in particular on the transverse link, and with the second contact element 11 on the second test object, in particular on the spring strut, applied, in particular supported. The tester 1 is braced between the first test object and the second test object. It then becomes a distance measure between the first test object and the second test object by means of the test device 1 determined. In particular, on the basis of the thus determined distance measure, which can be determined continuously, the intended installation position of the control arm relative to the strut tower can be adjusted.

With the test device proposed here 1 and the method is a reliable and highly accurate examination of the mounting position of the control arm reachable.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102009048186 A1 [0002]

Claims (9)

Tester ( 1 ) for testing and / or setting a proper installation position of a control arm in a vehicle, having - a base body ( 3 ), and - one with the main body ( 3 ) along a test direction relative to the main body ( 3 ) displaceably connected test element ( 5 ), characterized in that - the test element ( 5 ) is biased in a test position, wherein - on the main body ( 3 ) a first investment element ( 9 ) for conditioning the body ( 3 ) is arranged on a first test object, and wherein - on the test element ( 5 ) a second contact element ( 11 ) for the installation of the test element ( 5 ) is arranged on a second test object different from the first test object. Tester ( 1 ) according to claim 1, characterized in that the basic body ( 3 ) a guided tour ( 13 ), in which the test element ( 5 ) is guided along the test direction. Tester ( 1 ) according to one of the preceding claims, characterized in that the basic body ( 3 ) and / or the test element ( 5 ) a measuring device ( 15 ) arranged and arranged so that one of a distance between the first contact element ( 9 ) and the second contact element ( 11 ) dependent distance measure as a function of a relative position of the test element ( 5 ) to the basic body ( 3 ) is readable or readable. Tester ( 1 ) according to one of the preceding claims, characterized in that the measuring device ( 15 ) is designed as a measuring scale, preferably with a vernier. Tester ( 1 ) according to one of the preceding claims, characterized in that the basic body ( 3 ) or the test element ( 5 ) a plurality of successive adjacent, differently colored areas ( 19 ), wherein the test element ( 5 ) or the basic body ( 3 ) a position marker ( 22 ), which in a displacement of the test element ( 5 ) relative to the body ( 3 ) along the sequence of marked areas ( 19 ) is displaceable. Tester ( 1 ) according to one of the preceding claims, characterized in that the test device ( 1 ) a locking device ( 27 ) arranged to receive the test element ( 5 ) relative to the body ( 3 ). Tester ( 1 ) according to one of the preceding claims, characterized in that at least one contact element ( 9 . 11 ) selected from the first investment element ( 9 ) and the second contact element ( 11 ), a) has a flat contact surface on which the test direction is vertical; and / or b) a holding element ( 29 ), which is designed as a positive-locking element and / or as a magnetic holding element, and / or c) has a ball head; and / or d) has a three-point support; and / or e) releasably on the main body ( 3 ) or on the test element ( 5 ) is attachable; and / or f) relative to the main body ( 3 ) or the test element ( 5 ) is pivotally mounted. Method for testing and / or setting a designated mounting position of a control arm in a vehicle, comprising the following steps: - arranging a test device ( 1 ) according to one of claims 1 to 7 between a first test object and a second test object, wherein - the test device ( 1 ) with the first contact element ( 9 ) on the first test object and with the second contact element ( 11 ) is applied to the second test object, wherein - the test device ( 1 ) between the first test object and the second test object, and wherein - a distance measure between the first test object and the second test object by means of the test device ( 1 ) is determined. A method according to claim 8, characterized in that a distance measure between an upper control arm of a vehicle and a predetermined location on a strut tower of the vehicle is checked and / or adjusted.

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