CN217179868U - Vibration test tool clamp - Google Patents

Abstract

The application provides a vibration test frock clamp, relates to test device's technical field. Vibration test frock clamp includes: the frame body is provided with a first mounting station arranged along the horizontal direction of the frame body and/or a second mounting station arranged along the vertical direction of the frame body; the connecting assembly is at least partially configured to be connected with the first mounting station and/or the second mounting station, and the connecting assembly is provided with a third mounting station along the horizontal direction of the connecting assembly, so that the test piece is connected with the connecting assembly through the first mounting station, the second mounting station or the third mounting station. When different testpieces carry out vibration test, adjustable coupling assembling is for the ascending position of frame main part vertical direction, or adjusts coupling assembling for the ascending position of frame main part horizontal direction, or through the third installation station, adjusts the position that coupling assembling is used for connecting the testpiece to the realization carries out vibration test to different testpieces, has improved vibration test frock clamp's adaptability.

Description

Vibration test tool clamp

Technical Field

The application relates to the technical field of testing devices, in particular to a vibration test tool clamp.

Background

The vibration test of automobile parts is a medium-voltage guarantee for the reliability of an automobile, and aiming at different products and corresponding fatigue limit simulation conditions, vibration test equipment is loaded on the products to realize the reduction of the service life of the products.

The current test fixture can not be adapted to the fixing structure form of various automobile parts, which greatly limits the universality of the vibration fixture of the type.

SUMMERY OF THE UTILITY MODEL

An object of this application is to provide a vibration test frock clamp, aims at solving the technical problem that current test fixture can't adapt to multiple spare part.

In order to achieve the purpose, the following technical scheme is adopted in the application:

the application provides a vibration test frock clamp, include: the frame body is provided with a first mounting station arranged along the horizontal direction of the frame body and/or a second mounting station arranged along the vertical direction of the frame body; the connecting component is provided with a third mounting station along the horizontal direction of the connecting component, and a test piece is connected to the connecting component through at least two combinations of the first mounting station, the second mounting station and the third mounting station.

In the process of above-mentioned realization, through connecting coupling assembling in second installation station, or connect coupling assembling in first installation station, when different testpieces are connected on coupling assembling, adjustable coupling assembling is for the ascending position of frame main part vertical side, or adjust coupling assembling for the ascending position of frame main part horizontal direction, or through the third installation station, adjust coupling assembling and be used for connecting the position of testpiece, thereby the realization carries out vibration test to different testpieces, the adaptability of vibration test frock clamp has been improved.

In some embodiments, the frame body includes a supporting component and a mounting component, the supporting component is provided with the first mounting station along a horizontal direction of the supporting component, the mounting component is configured in a vertical direction of the supporting component, the mounting component and the first mounting station are distributed at intervals, and the mounting component is configured with the second mounting station along a vertical direction of the mounting component.

In the process of the implementation, the second installation station is arranged on the installation assembly, the position of at least one part of the structure of the adjustable connection assembly in the vertical direction relative to the installation assembly is adjustable, the first installation station is arranged on the support assembly, and the position of at least one part of the structure of the adjustable connection assembly in the horizontal direction relative to the support assembly is adjustable, so that different test pieces can be adapted on the connection assembly during vibration test.

In some embodiments, the support assembly includes a base plate and a connector, the base plate is connected to the connector, the connector is configured to be located on a side of the base plate close to the mounting assembly, and the connector is configured with the first mounting station.

In the process of the realization, the first installation station is arranged on the connecting piece, the connecting piece is connected with the bottom plate, and the bottom plate is used for being connected with vibration test equipment during vibration test, so that the stability of the whole structure can be ensured when the connecting assembly is connected with the connecting piece.

In some embodiments, the connecting piece is provided with a mounting groove in a concave manner along the horizontal direction of the connecting piece, and the side wall of the mounting groove is provided with the first mounting station.

In some embodiments, the mounting assembly includes a mounting column disposed on both left and right sides of the first column reinforcing rib and a first column reinforcing rib, the mounting column being disposed with the second mounting station along a vertical direction thereof.

In the process of above-mentioned realization, through will installing the second installation station of last configuration of stand, and install the left and right sides of stand configuration at first stand strengthening rib for when installation component connects on supporting component, can strengthen the connection stability between the installation stand through first stand strengthening rib, thereby improve overall structure's joint strength.

In some embodiments, the mounting assembly further comprises a second stud stiffener having a bottom portion configured to couple with the base plate, a side wall configured to couple with the mounting stud, and/or a side wall configured to couple with the first stud stiffener.

At the in-process of above-mentioned realization, through setting up the second stand strengthening rib, can realize the installation stand and the bottom plate between be connected the steadiness, and/or strengthen the first stand strengthening rib and the bottom plate between be connected the steadiness, alleviate overall structure's weight, reduced the energy consumption loss of test equipment and the operation degree of difficulty when the experimenter installation is built.

In some embodiments, the connecting assembly includes a first connecting beam, a pressing connecting block, and a holding connecting block, the third mounting station is disposed on the first connecting beam, the pressing connecting block is disposed on the third mounting station, the holding connecting block is disposed on the mounting groove and connected to the first mounting station, and the pressing connecting block and the holding connecting block are both connected to the test piece.

In the process of above-mentioned realization, through set up on the third installation station and push down the connecting block and set up on first installation station and hold in the palm the connecting block down for when carrying out vibration test, can adjust the position of pushing down the connecting block for the third installation station and hold in the palm the position of connecting block for first installation station down according to the connection size of test piece, thereby realize connecting test piece on pushing down the connecting block and holding in the palm the connecting block down.

In some embodiments, the connection assembly includes a first connection beam, a downward-pressing connection block, and a side-supporting connection block, the third installation station is disposed on the first connection beam, the downward-pressing connection block is disposed on the third installation station, the side-supporting connection block is disposed in the installation groove, the side-supporting connection block is connected to the first installation station, and the side-supporting connection block and the downward-pressing connection block are both connected to the test piece.

In the process of above-mentioned realization, hold in the palm the connecting block and set up the connection block that pushes down on the third installation station through setting up the side on first installation station for when carrying out vibration test, can be according to the connection size of test piece, adjust the side and hold in the palm the position of connecting block for first installation station and push down the position of connecting block for the third installation station, thereby realize connecting the test piece on the side holds in the palm the connecting block and pushes down the connecting block.

In some embodiments, the connection assembly includes a first connection beam, a second connection beam, a first lateral connection block and a second lateral connection block, the first connection beam and the second connection beam are distributed in parallel on the second installation station, the first connection beam and the second connection beam are all configured with the third installation station, the first lateral connection block and the second lateral connection block are all connected with the third installation station, the first lateral connection block is connected with the first connection beam, the second lateral connection block is connected with the second connection beam, and the first lateral connection block and the second lateral connection block are all connected with the test piece.

In the process of the realization, the first lateral connecting block is connected on the third installation station of the first connecting beam, the second lateral connecting block is connected on the third installation station of the second connecting beam, so that when the vibration test is carried out, the first lateral connecting block can be adjusted to be connected on the position of the first connecting beam and the position of the second lateral connecting block to be connected on the second connecting beam according to the connection size of the test piece, and the test piece can be connected on the first lateral connecting block and the second lateral connecting block.

In some embodiments, the second connecting beam is disposed below the first connecting beam, and the first connecting beam and the second connecting beam are spaced apart from each other.

In the process of the realization, the first connecting beam and the second connecting beam are distributed at intervals, and the distance between the first connecting beam and the second connecting beam can be passed, so that different test pieces can be connected on the first connecting beam and the second connecting beam through the third installation station, and the universality of the whole structure is improved.

Additional features and advantages of the present application will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by the practice of the embodiments of the present application. The objectives and other advantages of the application may be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and for a user of ordinary skill in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic structural diagram of a vibration test tooling fixture disclosed in an embodiment of the present application.

Fig. 2 is a schematic structural diagram of a frame main body of a vibration test tool fixture disclosed in an embodiment of the present application.

Fig. 3 is a schematic moving diagram of a connecting assembly of a vibration test tool clamp disclosed in an embodiment of the present application.

Reference numerals

10. A frame body; 11. a support assembly; 111. a base plate; 112. a connecting member; 1121. mounting grooves; 1122. a first mounting station; 12. mounting the component; 121. mounting the upright post; 122. a first column reinforcing rib; 123. a second column reinforcing rib; 124. a second mounting station; 20. a connecting assembly; 21. a first connecting beam; 22. a second connecting beam; 23. pressing the connecting block downwards; 24. a side support connecting block; 25. a lower supporting connecting block; 26. a first lateral connecting block; 27. a second lateral connecting block; 28. and a third mounting station.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. The components of the embodiments of the present application, generally described and illustrated in the figures herein, can be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present application, presented in the accompanying drawings, is not intended to limit the scope of the claimed application, but is merely representative of selected embodiments of the application. All other embodiments obtained by a user of ordinary skill in the art based on the embodiments in the present application without any creative effort belong to the protection scope of the present application.

In the description of the present application, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention are conventionally placed in use, and are only used for convenience of describing the present application and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present application. Furthermore, the terms "first," "second," "third," and the like are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance.

Furthermore, the terms "horizontal", "vertical" and the like do not imply that the components are absolutely horizontal or hanging, but may be slightly inclined. For example, "horizontal" merely means that the direction is more horizontal than "vertical" and does not mean that the structure must be perfectly horizontal, but may be slightly inclined.

In the description of the present application, it is further noted that, unless expressly stated or limited otherwise, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood in a specific case to a user of ordinary skill in the art.

Examples

The test fixture is an important component in the vibration test, and in the rigid connection with the vibration table, the three-axis conversion in a cartesian coordinate system is required to be met, and the practical use is limited based on the factors such as the strength, the light weight, the cost, the processing technology and the like of the fixture scheme, especially when the natural frequencies of the assembled test fixture and a sample are overlapped in a test frequency range, accurate energy transmission cannot be ensured, and the test effectiveness is also influenced.

The inventor finds that the fixing modes of a plurality of existing automobile parts (such as radiators, condensers and the like) are structurally divided into a pressing mode, a side support mode, a bottom support mode and a combination mode, and the test fixture needs to be designed and manufactured according to different structural forms of products on the basis of a main body frame and can only be matched with one part, so that the universality of the vibration fixture is greatly limited.

In view of this, as shown in fig. 1, fig. 1 is a schematic structural diagram of a vibration test tooling fixture disclosed in the embodiment of the present application; the application provides a vibration test frock clamp, include: frame main part 10 and coupling assembling 20, be configured with first installation station 1122 and/or second installation station 124 on the frame main part 10, coupling assembling 20 with second installation station 124 is connected for coupling assembling 20 follows the horizontal direction of frame main part 10 distributes, just be configured with third installation station 28 on the coupling assembling 20, when carrying out the vibration test, the accessible first installation station 1122, second installation station 124 or third installation station 28 realizes connecting different test pieces on the coupling assembling 20.

Specifically, the frame body 10 has a first mounting station 1122 provided along a horizontal direction thereof, and/or a second mounting station 124 provided along a vertical direction thereof; at least a portion of the connecting assembly 20 is configured to be connected to the first mounting station 1122 and/or to the second mounting station 124, and the connecting assembly 20 is provided with a third mounting station 28 along a horizontal direction thereof to connect a test piece to the connecting assembly 20 by at least two of the first mounting station 1122, the second mounting station 124, and the third mounting station 28 in combination.

For example, the first installation station 1122, the second installation station 124, and the third installation station 28 are provided with a plurality of installation stations, and the first installation station 1122, the second installation station 124, and the third installation station 28 include, but are not limited to, flexible elongated slot installation holes, so that a large-scale adaptive installation of the type of sample is achieved.

It should be noted that the vibration test tool clamp mainly undertakes connecting the vibration test equipment and the test piece, ensures effective transfer of energy, and provides a matrix for the matched test piece; the test piece may be directly mounted on the connecting assembly 20 corresponding to the second mounting station 124, or may be mounted on the connecting assembly 20 corresponding to the first mounting station 1122 and the second mounting station 124, and the connecting positions of the connecting assembly 20 at the first mounting station 1122 are different, so that different test pieces are connected to complete the vibration test of the test piece.

In the implementation process, the connecting assembly 20 is connected to the second mounting station 124, or the connecting assembly 20 is connected to the first mounting station 1122, when different test pieces are connected to the connecting assembly 20, the position of the connecting assembly 20 in the vertical direction relative to the frame main body 10 can be adjusted, or the position of the connecting assembly 20 in the horizontal direction relative to the frame main body 10 can be adjusted, or the position of the connecting assembly 20 used for connecting the test pieces is adjusted through the third mounting station 28, so that the vibration test on different test pieces is realized, and the adaptability of the vibration test tool fixture is improved.

As shown in fig. 2, fig. 2 is a schematic structural diagram of a frame body 10 of a vibration test tooling fixture disclosed in an embodiment of the present application, where the frame body 10 includes a supporting component 11 and a mounting component 12, the supporting component 11 is provided with the first mounting station 1122 along a horizontal direction thereof, the mounting component 12 is disposed in a vertical direction of the supporting component 11, the mounting component 12 and the first mounting station 1122 are distributed at intervals, and the mounting component 12 is disposed with the second mounting station 124 along a vertical direction thereof.

Illustratively, the frame body 10 is made of a material including, but not limited to, 7075 aircraft aluminum, the supporting component 11 is used for being connected to the vibration testing equipment in a vibration test, the distance between the mounting component 12 and the first mounting station 1122 is not particularly limited and may be set according to the actual situation of the test piece, and the mounting component 12 is fixedly connected to the supporting component 11, and the fixing manner may be a combination of welding and bolt fixing.

In the implementation process, by arranging the second mounting station 124 on the mounting assembly 12, the position of at least one part of the structure of the connecting assembly 20 in the vertical direction relative to the mounting assembly 12 can be adjusted, and by arranging the first mounting station 1122 on the supporting assembly 11, the position of at least one part of the structure of the connecting assembly 20 in the horizontal direction relative to the supporting assembly 11 can be adjusted, so that different test pieces can be adapted on the connecting assembly 20 when a vibration test is performed.

Referring to fig. 2, the supporting assembly 11 includes a bottom plate 111 and a connecting member 112, the bottom plate 111 is connected to the connecting member 112, the connecting member 112 is disposed on a side of the bottom plate 111 close to the mounting assembly 12, and the first mounting station 1122 is disposed on the connecting member 112; the connecting member 112 is provided with an installation groove 1121 in a recessed manner along the horizontal direction thereof, and the side wall of the installation groove 1121 is configured with the first installation station 1122.

For example, the connecting member 112 may be fixedly connected to the bottom plate 111 by welding, the connecting member 112 may be configured as a strip, the connecting member 112 may be directly integrated into a whole, or may be configured as two segments, the first mounting stations 1122 are configured on the left and right sides of the connecting member 112, and it should be noted that the width of the connecting member 112 may be set according to the thickness of a test piece.

In the implementation process, the first installation station 1122 is arranged on the connecting piece 112, the connecting piece 112 is connected with the bottom plate 111, the bottom plate 111 is used for being connected with vibration test equipment during vibration tests, and when the connecting assembly 20 is connected with the connecting piece 112, the stability of the whole structure can be guaranteed.

In some embodiments, the mounting assembly 12 includes a mounting column 121 and a first column reinforcing rib 122, the mounting column 121 is disposed on both left and right sides of the first column reinforcing rib 122, and the mounting column 121 is disposed with the second mounting station 124 along a vertical direction thereof.

For example, the mounting columns 121 may be arranged in a column shape, each of the mounting columns 121 is provided with a column of the second mounting stations 124, and the number of the second mounting stations 124 and the pitch of the second mounting columns 121 are not particularly limited.

It should be noted that, the first column reinforcing rib 122 may be provided in a panel type, or may be provided in a frame type, and as long as the stability of the mounting column 121 can be improved, the present invention is within the protection scope.

In the implementation process, the second installation stations 124 are configured on the installation upright columns 121, and the installation upright columns 121 are configured on the left side and the right side of the first upright reinforcing ribs 122, so that when the installation assembly 12 is connected to the support assembly 11, the connection stability between the installation upright columns 121 can be enhanced through the first upright reinforcing ribs 122, and the connection strength of the whole structure is improved.

Referring again to fig. 2, the mounting assembly 12 further includes a second upright reinforcing rib 123, a bottom portion of the second upright reinforcing rib 123 is configured to be connected to the bottom plate 111, a side wall of the second upright reinforcing rib 123 is configured to be connected to the mounting upright 121, and/or a side wall of the second upright reinforcing rib 123 is configured to be connected to the first upright reinforcing rib 122.

In the process of the implementation, by arranging the second upright reinforcing ribs 123, the connection stability between the mounting upright 121 and the bottom plate 111 can be realized, and/or the connection stability between the first upright reinforcing ribs 122 and the bottom plate 111 is enhanced, so that the weight of the whole structure is reduced, and the energy consumption loss of the testing equipment and the operation difficulty of the testing personnel during installation and construction are reduced.

Referring to fig. 1 again, the connecting assembly 20 includes a first connecting beam 21, a pressing connecting block 23 and a supporting connecting block 25, the third mounting station 28 is disposed on the first connecting beam 21, the pressing connecting block 23 is disposed on the third mounting station 28, the supporting connecting block 25 is disposed on the mounting groove 1121 and is connected to the first mounting station 1122, wherein the pressing connecting block 23 and the supporting connecting block 25 are both connected to the test piece.

In this embodiment, the test piece includes, but is not limited to, a heat sink, the downward pressing connection blocks 23 are disposed on the left and right sides of the first connection beam 21, the downward pressing connection blocks 23 are connected to the upper side of the test piece, the downward supporting connection blocks 25 are protruded from the mounting groove 1121, the downward supporting connection blocks 25 are disposed on the left and right sides of the connection piece 112, and the downward supporting connection blocks 25 are connected to the bottom of the test piece.

In the implementation process, the pressing connecting block 23 is arranged on the third mounting station 28, and the holding connecting block 25 is arranged on the first mounting station 1122, so that when the vibration test is performed, the position of the pressing connecting block 23 relative to the third mounting station 28 and the position of the holding connecting block 25 relative to the first mounting station 1122 can be adjusted according to the connection size of the test piece, and the test piece can be connected to the pressing connecting block 23 and the holding connecting block 25.

Referring to fig. 1 again, the connecting assembly 20 includes a first connecting beam 21, a downward pressing connecting block 23 and a side supporting connecting block 24, the third mounting station 28 is disposed on the first connecting beam 21, the downward pressing connecting block 23 is disposed on the third mounting station 28, the side supporting connecting block 24 is disposed in the mounting groove 1121, the side supporting connecting block 24 is connected to the first mounting station 1122, and the side supporting connecting block 24 and the downward pressing connecting block 23 are both connected to the test piece.

In this embodiment, the test piece includes, but is not limited to, a radiator with a fan, the downward pressing connection blocks 23 are disposed on the left and right sides of the first connection beam 21, the downward pressing connection blocks 23 are connected to the upper side of the test piece, the lateral supporting connection blocks 24 are disposed on the left and right sides of the connection piece 112, the lateral supporting connection blocks 24 are protrusively disposed on the installation grooves 1121, the left and right sides of the test piece are protrusively disposed with installation blocks, and the lateral supporting connection blocks 24 are located on the outer side of the test piece and are correspondingly and fixedly connected to the installation blocks.

In the process of the above implementation, by providing the side supporting connecting block 24 on the first mounting station 1122 and providing the pressing connecting block 23 on the third mounting station 28, the position of the side supporting connecting block 24 with respect to the first mounting station 1122 and the position of the pressing connecting block 23 with respect to the third mounting station 28 can be adjusted according to the connection size of the test piece during the vibration test, thereby implementing the connection of the test piece to the side supporting connecting block 24 and the pressing connecting block 23.

Referring to fig. 1 again, the connection assembly 20 includes a first connection beam 21, a second connection beam 22, a first lateral connection block 26 and a second lateral connection block 27, the first connection beam 21 and the second connection beam 22 are distributed in the second installation station 124 in parallel, the third installation station 28 is disposed on each of the first connection beam 21 and the second connection beam 22, the first lateral connection block 26 and the second lateral connection block 27 are connected to the third installation station 28, the first lateral connection block 26 is connected to the first connection beam 21, the second lateral connection block 27 is connected to the second connection beam 22, and both the first lateral connection block 26 and the second lateral connection block 27 are connected to the test piece.

In this embodiment, the test piece includes, but is not limited to, a condenser, the first lateral connecting block 26 is disposed on the left and right sides of the first connecting beam 21, the second lateral connecting block 27 is disposed on the left and right sides of the second connecting beam 22, mounting blocks are disposed on the left and right sides of the test piece, and the first lateral connecting block 26 and the second lateral connecting block 27 are located on the outer side of the test piece and are connected with the mounting blocks correspondingly; it should be noted that the first lateral connecting block 26 and the second lateral connecting block 27 may be configured in the same structure, so that the test piece can be maintained on the same vertical plane when being connected to the first lateral connecting block 26 and the second lateral connecting block 27, which is beneficial to the vibration test of the test piece.

In the implementation process, the first lateral connecting block 26 is connected to the third mounting station 28 of the first connecting beam 21, and the second lateral connecting block 27 is connected to the third mounting station 28 of the second connecting beam 22, so that when a vibration test is performed, the position where the first lateral connecting block 26 is connected to the first connecting beam 21 and the position where the second lateral connecting block 27 is connected to the second connecting beam 22 can be adjusted according to the connection size of a test piece, and the test piece is connected to the first lateral connecting block 26 and the second lateral connecting block 27.

In some embodiments, the second connecting beam 22 is disposed below the first connecting beam 21, and the first connecting beam 21 and the second connecting beam 22 are spaced apart from each other. For example, the first connecting beam 21 and the second connecting beam 22 may be arranged in the same structure, and the ends of the first connecting beam 21 and the second connecting beam 22 may be arranged in the same level or not; with first connecting beam 21 and second connecting beam 22 interval distribution, and the distance accessible between first connecting beam 21 and the second connecting beam 22 for through third installation station 28, can connect different test pieces on first connecting beam 21 and second connecting beam 22, improved overall structure's commonality.

As shown in fig. 3, in order to ensure the overall stability and strength of the product, a plurality of first mounting stations 1122, a plurality of second mounting stations 124 and a plurality of third mounting stations 28 are arranged at intervals, for example, when a heat sink is mounted, each of the hold-down connecting blocks 23 is connected to two of the third mounting stations 28, so that the hold-down connecting block 23 can be adjusted in position relative to the two third mounting stations 28, and correspondingly, each of the hold-down connecting blocks 25 is connected to two of the first mounting stations 1122, so that the hold-down connecting block 25 can be adjusted in position relative to the two first mounting stations 1122; similarly, when the radiator with fan or the condenser is installed, the position of the lower connecting block 23 and the side supporting connecting block 24 connected to the radiator with fan or the position of the first side connecting block 26 and the second side connecting block 27 connected to the condenser can be adjusted to complete flexible connection.

The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims (10)

1. The utility model provides a vibration test frock clamp which characterized in that includes:

the frame body is provided with a first mounting station arranged along the horizontal direction of the frame body and/or a second mounting station arranged along the vertical direction of the frame body;

the connecting component is provided with a third mounting station along the horizontal direction of the connecting component, and a test piece is connected to the connecting component through at least two combinations of the first mounting station, the second mounting station and the third mounting station.

2. The vibration test tooling fixture of claim 1, wherein the frame body includes a support assembly and a mounting assembly, the support assembly is provided with the first mounting station along a horizontal direction of the support assembly, the mounting assembly is configured in a vertical direction of the support assembly, the mounting assembly is spaced apart from the first mounting station, and the mounting assembly is configured with the second mounting station along a vertical direction of the mounting assembly.

3. The vibration test tooling fixture of claim 2 wherein the support assembly includes a base plate and a connector, the base plate being connected to the connector, the connector being configured on a side of the base plate adjacent to the mounting assembly, the connector being configured with the first mounting station thereon.

4. The vibration test tool clamp of claim 3, wherein the connecting piece is provided with a mounting groove in a recessed manner along the horizontal direction of the connecting piece, and the side wall of the mounting groove is provided with the first mounting station.

5. The vibration test tool clamp of claim 4, wherein the mounting assembly comprises mounting columns and first column reinforcing ribs, the mounting columns are arranged on the left side and the right side of the first column reinforcing ribs, and the mounting columns are arranged with the second mounting stations along the vertical direction of the mounting columns.

6. The vibration test tool holder of claim 5 wherein the mounting assembly further comprises a second stud stiffener having a bottom configured to couple to the base plate, a side wall configured to couple to the mounting stud, and/or a side wall configured to couple to the first stud stiffener.

7. The vibration test tool clamp of claim 5, wherein the connecting assembly comprises a first connecting beam, a pressing connecting block and a holding connecting block, the third mounting station is arranged on the first connecting beam, the pressing connecting block is arranged on the third mounting station, the holding connecting block is arranged on the mounting groove and connected with the first mounting station, and the pressing connecting block and the holding connecting block are connected with the test piece.

8. The vibration test tool clamp of claim 5, wherein the connecting assembly comprises a first connecting beam, a pressing connecting block and a side supporting connecting block, the third mounting station is arranged on the first connecting beam, the pressing connecting block is arranged on the third mounting station, the side supporting connecting block is arranged in the mounting groove, the side supporting connecting block is connected with the first mounting station, and the side supporting connecting block and the pressing connecting block are both connected with the test piece.

9. The vibration test tool clamp of claim 5, wherein the connecting assembly comprises a first connecting beam, a second connecting beam, a first lateral connecting block and a second lateral connecting block, the first connecting beam and the second connecting beam are distributed in the second installation station in parallel, the third installation station is arranged on the first connecting beam and the second connecting beam, the first lateral connecting block and the second lateral connecting block are connected with the third installation station, the first lateral connecting block is connected with the first connecting beam, the second lateral connecting block is connected with the second connecting beam, and the first lateral connecting block and the second lateral connecting block are connected with the test piece.

10. The vibration test tooling fixture of claim 9 wherein the second connecting beam is disposed below the first connecting beam and the second connecting beam are spaced apart.

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