CN116990620A

CN116990620A - CCS assembly vibration testing method

Info

Publication number: CN116990620A
Application number: CN202311242978.4A
Authority: CN
Inventors: 石珍; 颜章健
Original assignee: Jiangsu Xunlai Laser Technology Co ltd
Current assignee: Jiangsu Xunlai Laser Technology Co ltd
Priority date: 2023-09-26
Filing date: 2023-09-26
Publication date: 2023-11-03
Anticipated expiration: 2043-09-26
Also published as: CN116990620B

Abstract

The application relates to a vibration testing method of a CCS component, which comprises the following steps: s100, setting a clamping mechanism, wherein the clamping mechanism is used for taking and placing a detection plate, a plurality of probes are arranged on the detection plate, the clamping mechanism is driven to descend through a lifting mechanism, then the detection plate clamped by the clamping mechanism descends to the upper side of a tray, then the clamping mechanism is separated from the detection plate and enables the detection plate to be fixed with the tray through a plurality of locking mechanisms, a CCS component to be detected is fixed on the tray, each probe on the detection plate is in contact with a corresponding welded metal sheet on the CCS component, S200 vibrates the tray, the probes on the detection plate and the corresponding welded metal sheet on the CCS component vibrate synchronously, performance detection is carried out on the vibrating CCS component through a detection instrument, S300 the vibration of the tray is stopped, the locking mechanisms are unlocked, and the detection plate is separated from the tray. The method can test vibrating CCS components with probes.

Description

CCS assembly vibration testing method

Technical Field

The application relates to the field of CCS component detection, in particular to a CCS component vibration testing method.

Background

Chinese patent CN2023107493600 discloses a method for detecting CCS components. The CCS component is detected, and the welding quality of the palladium sheet or the nickel sheet is mainly detected to be in accordance with the requirement. For this purpose, the above-mentioned patent document performs a first type of test on the vibrating CCS assembly, including the NTC test, which requires no probes, and only the interconnection of PIN PINs at one end of the CCS assembly with corresponding connectors of the detecting instrument. After the first type of test is completed, the vibration assembly is closed, and the corresponding carrier plate does not vibrate any more. Then, the probe assembly is lowered by the lifting mechanism, each probe on the probe assembly is contacted with the palladium sheet and the nickel sheet of the corresponding CCS assembly, and then a second type of test is carried out and a test result is obtained, wherein the second type of test comprises: withstand voltage test, insulation resistance test, wire harness internal resistance test, wire harness on-off test and the like. In the above-mentioned detection method, the second type of test is performed in a static environment, that is, in a state where the vibration assembly is turned off. The vibration component is closed because the probe component is always connected with the lifting mechanism above, the probe component cannot vibrate synchronously with the CCS component below, if the CCS component is in a vibration state, the probe component above cannot ensure to be always contacted with the palladium sheet or the nickel sheet on the CCS component, that is, the probe on the probe component can be contacted with the palladium sheet or the nickel sheet or can be separated from the palladium sheet or the nickel sheet instantaneously, and therefore, whether the detection result caused by the infirm welding of the palladium sheet or the nickel sheet is inconsistent or the detection result caused by the separation of the probe and the palladium sheet or the nickel sheet is inconsistent cannot be judged. Therefore, the patent turns off the vibrating assembly and the second type of test is performed by the probe with the CCS assembly at rest.

However, the actual use environment of the CCS assembly is a vibrating environment, and the second type of test is performed on the CCS assembly through the probe in a static state, and the test result is not consistent with the actual use environment. Therefore, there is a need to develop a detection method that can perform the second type of test described above on vibrating CCS components through probes.

Disclosure of Invention

Based on this, a CCS assembly vibration testing method is provided. The method can test the vibrating CCS component through a probe, namely a voltage withstanding test, an insulation resistance test, a wire harness internal resistance test, a wire harness on-off test and the like.

A CCS assembly vibration testing method, comprising:

s100, arranging a clamping mechanism, wherein the clamping mechanism is used for taking and placing a detection plate, a plurality of probes are arranged on the detection plate, the clamping mechanism is driven to descend through a lifting mechanism, the detection plate clamped by the clamping mechanism is further descended above a tray, then the clamping mechanism is separated from the detection plate and is fixed with the tray through a plurality of locking mechanisms, a CCS component to be detected is fixed on the tray, each probe on the detection plate is contacted with a corresponding welded metal sheet on the CCS component,

s200, vibrating the tray to enable the probes on the detection plate and the corresponding welded metal sheets on the CCS component to vibrate synchronously, detecting the performance of the vibrated CCS component through a detection instrument,

s300, stopping vibrating the tray, unlocking the locking mechanism, and separating the detection plate from the tray.

In one embodiment, in S200, performance detection is performed by a detection apparatus, which specifically includes: withstand voltage test, insulation resistance test, wire harness internal resistance test or wire harness on-off test.

In one embodiment, in S100, contacting each probe on the probe card with a corresponding soldered metal sheet on the CCS assembly specifically includes: a portion of the probes are in contact with the nickel plate of the CCS assembly and a portion of the probes are in contact with the palladium plate of the CCS assembly.

In one embodiment, in S100, the locking mechanism includes a first component and a second component, where the first component is disposed on the detection board, the second component is disposed on the tray, and the second component is connected and fixed with the first component.

In one embodiment, the first component comprises a base, a sliding block, a first spring and driving columns, wherein the sliding block is provided with small holes and large holes which are mutually communicated, the sliding block is arranged in the base and is in sliding fit with the base, the first spring is arranged in the base, one end of the first spring is propped against the base, the other end of the first spring is propped against the sliding block, slots are formed in the base corresponding to the two sides of the sliding block, strip-shaped holes are formed in the inner side walls of the slots, one driving column is arranged at each strip-shaped hole, one end of each driving column is connected with the sliding block, the other end of each driving column is positioned outside the slot, the upper end of the base is provided with an upper end hole matched with the large hole, the lower end of the base is provided with a lower end hole matched with the large hole,

the second component comprises a guide pillar mounting seat, a guide pillar, a second spring, a spring cushion block, an upper positioning block and a lower positioning block, wherein the guide pillar is mounted on the guide pillar mounting seat, the upper end of the guide pillar is fixedly provided with the upper positioning block, the guide pillar is also provided with the spring cushion block, the spring cushion block is in sliding fit with the guide pillar, a second spring sleeved on the guide pillar is arranged between the spring cushion block and the guide pillar mounting seat, the lower positioning block is also fixedly arranged on the guide pillar, the lower positioning block is positioned between the spring cushion block and the upper positioning block, a gap is reserved between the lower positioning block and the spring cushion block,

the guide pillar is used for being matched with the small hole of the sliding block in a clamping way, the large hole is used for enabling the upper positioning block to pass through and enabling the upper positioning block not to pass through the small hole, the upper end hole of the base body is used for accommodating the upper positioning block, the lower end hole of the base body is used for accommodating the lower positioning block, and a stepped hole used for being matched with the spring cushion block is formed in the bottom surface of the detection plate.

In one embodiment, the base is provided with a mounting through hole, the sliding block is located in the mounting through hole, and two ends of the mounting through hole are respectively plugged through the cover plate.

In one embodiment, when the slider is located at the first position, the big hole of the slider, the upper hole of the seat body and the lower hole of the seat body are communicated with each other, and when the slider is located at the second position, the small hole of the slider is clamped with the guide post.

In one embodiment, the lifting mechanism is further provided with a clamping mechanism, the clamping mechanism comprises a clamp supporting plate, two clamping assemblies are arranged on the clamp supporting plate at intervals, each clamping assembly comprises a cylinder blocking block, a driving cylinder, a sliding rail assembly, a clamping claw frame, a strip-shaped mounting block and a plurality of U-shaped plug-ins, the cylinder blocking block is adjacent to the clamp supporting plate, the sliding rail assembly is connected with the clamp supporting plate, the clamping claw frame is connected with the sliding rail assembly, the driving cylinder is respectively connected with the cylinder blocking block and the clamping claw frame, the strip-shaped mounting block is arranged at the lower end of the clamping claw frame, each U-shaped plug-in unit is arranged on the strip-shaped mounting block at intervals, each U-shaped plug-in unit is provided with two plug-in blocks, each plug-in block is used for being plugged into a slot on a seat body, and then pushing the driving column is moved, and a connecting rod type synchronous assembly is arranged between the two clamping claw frames.

In one embodiment, the guide pillar mounting seat is provided with a plurality of first type long holes, the guide pillar mounting seat is detachably connected to the movable seat through bolts matched with the first type long holes, the movable seat is provided with a plurality of second type long holes, and the extending direction of the first type long holes is perpendicular to the extending direction of the second type long holes.

In one embodiment, the tray is disposed on a vibrating platform.

The beneficial effects of the application are as follows:

according to the application, the detection plate provided with a plurality of probes is fixed with the tray through a plurality of locking mechanisms, the CCS component to be detected is fixed on the tray, each probe on the detection plate is contacted with a corresponding welded metal sheet on the CCS component, the tray is vibrated, so that the probes on the detection plate and the corresponding welded metal sheet on the CCS component vibrate synchronously, and the performance of the vibrated CCS component is detected through the detection instrument. That is, in the application, the probe and the palladium sheet or the nickel sheet on the lower CCS component can always keep contact in the detection process, so the method can detect the vibrating CCS component through the probe, and the detection result accords with the actual use environment of the CCS component, and the detection result is more accurate. Moreover, the specific locking mechanism provided by the application is beneficial to enabling the detection plate to be quickly connected with and separated from the tray, and further is beneficial to improving the detection efficiency.

Drawings

FIG. 1 is a flow chart of a method of vibration testing a CCS assembly in accordance with an embodiment of the present application.

Fig. 2 is a schematic diagram of the overall structure of an apparatus to which the CCS assembly vibration testing method according to an embodiment of the present application is applied.

Fig. 3 is a schematic view of a U-shaped insert applying thrust to a drive column according to an embodiment of the present application.

FIG. 4 is a schematic view of a sensing plate and tray of an embodiment of the present application secured together.

FIG. 5 is a schematic view of a slider provided with large and small holes according to an embodiment of the present application.

FIG. 6 is a schematic view of a slider cooperating with a first spring according to an embodiment of the present application.

Fig. 7 is a schematic view of the lower end of the base of the embodiment of the present application provided with a lower end hole matching the large hole.

Fig. 8 is a schematic diagram of a side portion of a base provided with a slot, and a driving post extending out of the slot.

FIG. 9 is a schematic view of the alignment of the small hole of the slider with the upper end hole of the housing in accordance with an embodiment of the present application.

FIG. 10 is a schematic view of the large hole of the slider aligned with the upper hole of the seat in accordance with an embodiment of the present application.

Fig. 11 is a schematic diagram illustrating the positional relationship among the guide post, the upper positioning block, the lower positioning block, and the spring pad according to an embodiment of the present application.

Fig. 12 is a schematic view of a U-shaped insert according to an embodiment of the present application.

Fig. 13 is a schematic view of a detection plate with a stepped hole at the bottom thereof according to an embodiment of the present application.

Wherein:

110. a lifting mechanism; 120. a clamping mechanism; 130. a first component; 140. a second component; 150. a detection plate; 160. a tray; 170. a vibration mechanism; 151. a probe; 152. a stepped hole;

121. a clamp support plate; 122. a cylinder block; 123. a slide rail assembly; 124. a driving cylinder; 125. a claw holder; 126. a strip-shaped mounting block; 127. a U-shaped insert; 128. a link synchronization assembly; 127a, plug blocks;

131. a base; 132. an upper end hole; 133. a lower end hole; 134. a bar-shaped hole; 135. a slot; 136. a slide block; 137. a drive column; 138. a first spring; 139. a cover plate; 136a, small holes; 136b, macropores;

141. a guide post; 142. an upper positioning block; 143. a lower positioning block; 144. a spring cushion block; 145. a second spring; 146. a guide post mounting seat; 147. a movable seat; 146a, a first type of slot; 147a, a second elongate aperture.

Detailed Description

In order that the above objects, features and advantages of the application will be readily understood, a more particular description of the application will be rendered by reference to the appended drawings.

As shown in fig. 1, an embodiment of the present application provides a CCS assembly vibration testing method, including:

s100, a clamping mechanism 120 is arranged, the clamping mechanism 120 is used for taking and placing a detection plate 150, a plurality of probes 151 are arranged on the detection plate 150, the clamping mechanism 120 is driven to descend through a lifting mechanism 110, then the detection plate 150 clamped by the clamping mechanism 120 descends to the position above a tray 160, then the clamping mechanism 120 is separated from the detection plate 150, the detection plate 150 and the tray 160 are fixed together through a plurality of locking mechanisms, a CCS component to be detected is fixed on the tray 160, and each probe 151 on the detection plate 150 is contacted with a corresponding welded metal sheet on the CCS component.

And 200, vibrating the tray 160 to enable the probes 151 on the detection plate 150 and the corresponding welded metal sheets on the CCS assembly to vibrate synchronously, and detecting the performance of the vibrated CCS assembly through a detection instrument.

S300, stopping vibrating the tray 160, unlocking the locking mechanism, and separating the detection plate 150 from the tray 160.

The application drives the clamping mechanism 120 to move up and down through the lifting mechanism 110, and the detection plate 150 is clamped on the clamping mechanism 120. When the CCS assembly-fixed tray 160 is transported under the detection plate 150, the lifting mechanism 110 drives the clamping mechanism 120 to descend, so that the detection plate 150 descends to the target position. Then, the holding mechanism 120 is separated from the detection plate 150, and the detection plate 150 with the probes 151 is fixed to the tray 160 by the locking mechanism. Each probe 151 on the sensing plate 150 is in contact with a corresponding soldered metal sheet on the CCS assembly, e.g., probe 151 is in contact with a nickel sheet on the CCS assembly. Because sensing plate 150 is separate from clamping mechanism 120, sensing plate 150 is secured to tray 160 only, and the CCS assembly is secured to tray 160, which also secures sensing plate 150 to CCS assembly. Thus, when the tray 160 vibrates, the CCS assembly and the probes 151 on the sensing plate 150 vibrate synchronously, and the probes 151 are not instantaneously separated from the nickel plate on the CCS assembly. The probe 151 will always remain in contact with the nickel plate, thus, if the test result is not satisfactory, it means that the quality of the soldering of the nickel plate with other components on the CCS assembly is problematic, rather than the test structure being unsatisfactory because the probe 151 is instantaneously separated from the nickel plate. Thus, each nickel sheet with unsatisfactory welding quality can be detected rapidly.

In one embodiment, in S200, performance detection is performed by a detection apparatus, which specifically includes: withstand voltage test, insulation resistance test, wire harness internal resistance test, wire harness on-off test and the like. It will be appreciated that in particular testing, probes 151 on test plate 150 are connected to a test instrument, and the CCS assembly is also connected to the test instrument.

In one embodiment, if the metal sheets welded to the CCS assembly have a plurality of nickel sheets and a plurality of palladium sheets, a portion of probes 151 on sensing plate 150 are in contact with the corresponding nickel sheets of the CCS assembly and a portion of probes 151 are in contact with the corresponding palladium sheets of the CCS assembly. It will be appreciated that if the only metal sheets welded to the CCS assembly are nickel sheets, each probe 151 will be in contact with the corresponding nickel sheet. A probe 151 contacts a soldered metal sheet.

In one embodiment, as shown in fig. 2 to 4, in S100, the locking mechanism includes a first component 130 and a second component 140, where the first component 130 is disposed on the detection board 150, the second component 140 is disposed on the tray 160, and the second component 140 is used to connect and fix with the first component 130.

Specifically, in one embodiment, as shown in fig. 5 to 10, the first assembly 130 includes a base 131, a slider 136, 2 first springs 138 and 2 driving posts 137, the slider 136 is provided with a small hole 136a and a large hole 136b that are mutually communicated, the slider 136 is disposed in the base 131 and slidingly engaged with the base 131, the base 131 is provided with the first springs 138, one end of each first spring 138 abuts against the base 131, and if a mounting through hole is disposed on the base 131, and a cover 139 is disposed at an end of the mounting through hole, one end of each first spring 138 abuts against the cover 139. The other end of the first spring 138 abuts against the sliding block 136, the socket 135 is formed in the corresponding base 131 on two sides of the sliding block 136, strip-shaped holes 134 are formed in the inner side walls of the socket 135, a driving column 137 is arranged at each strip-shaped hole 134, one end of each driving column 137 is connected with the sliding block 136, the other end of each driving column 137 is located outside the corresponding socket 135, an upper end hole 132 matched with the corresponding large hole 136b is formed in the upper end of the base 131, and a lower end hole 133 matched with the corresponding large hole 136b is formed in the lower end of the base 131. As shown in fig. 11, the second assembly 140 includes a guide pillar mounting seat 146, a guide pillar 141, a second spring 145, a spring pad 144, an upper positioning block 142 and a lower positioning block 143, the diameter of the upper positioning block 142 is larger than that of the guide pillar 141, the diameter of the lower positioning block 143 is larger than that of the guide pillar 141, the guide pillar 141 is mounted on the guide pillar mounting seat 146, the upper end of the guide pillar 141 is fixedly provided with the upper positioning block 142, the guide pillar 141 is further provided with the spring pad 144, the spring pad 144 is in sliding fit with the guide pillar 141, a second spring 145 sleeved on the guide pillar 141 is arranged between the spring pad 144 and the guide pillar mounting seat 146, the guide pillar 141 is further fixedly provided with the lower positioning block 143, the lower positioning block 143 is located between the spring cushion block 144 and the upper positioning block 142, a part of guide pillar 141 area is located between the lower positioning block 143 and the upper positioning block 142, a gap is left between the lower positioning block 143 and the spring cushion block 144, the guide pillar 141 is used for being in clamping fit with the small hole 136a of the sliding block 136, the large hole 136b is used for allowing the upper positioning block 142 to pass through and the upper positioning block 142 cannot pass through the small hole 136a, the upper end hole 132 of the base 131 is used for accommodating the upper positioning block 142, the lower end hole 133 of the base 131 is used for accommodating the lower positioning block 143, as shown in fig. 13, a stepped hole 152 used for being matched with the spring cushion block 144 is arranged on the bottom surface of the detection plate 150, and one stepped hole 152 is arranged on each spring cushion block 144 in a matching manner. The first and second components 130 and 140 of the above-described embodiments may achieve quick connection and quick disconnection.

Specifically, a plurality of the first assemblies 130 described above, for example, 4, may be disposed on the detection plate 150, that is, 2 first assemblies 130 are disposed on one side of the detection plate 150, and 2 first assemblies 130 are disposed on the other side. Correspondingly, 4 of the above-described second assemblies 140 are provided on the tray 160. Each first component 130 is matched for use with one second component 140.

Specifically, the driving post 137 on the slider 136 is pushed to move the slider 136, when the slider 136 is located at the first position, the first spring 138 is compressed, and the large hole 136b of the slider 136, the upper hole 132 of the base 131 and the lower hole 133 of the base 131 are communicated with each other, at this time, the upper positioning block 142 may pass through the lower hole 133 and the large hole 136b and enter the upper hole 132, the lower positioning block 143 is located in the lower hole 133, and the spring pad 144 is located in the stepped hole 152 on the bottom surface of the detection plate 150. Then, the pushing force applied to the driving post 137 is removed, the slider 136 moves toward the second position under the action of the first spring 138, and when the slider 136 is located at the second position, the small hole 136a of the slider 136 is clamped with the guide post 141, and the upper positioning block 142 abuts against the upper end surface of the slider 136. At this time, the detection plate 150 is fixed relative to the tray 160. When the detection plate 150 needs to be separated from the tray 160, the driving column 137 is pushed to drive the slider 136 to move, the small hole 136a on the slider 136 is gradually far away from the guide pillar 141, the guide pillar 141 gradually enters the large hole 136b on the slider 136, and when the slider 136 is located at the first position, the large hole 136b of the slider 136, the upper end hole 132 of the base 131 and the lower end hole 133 of the base 131 are communicated with each other, at this time, the detection plate 150 can be lifted, so that the detection plate 150 is separated from the tray 160.

In one embodiment, the base 131 is provided with a mounting through hole, the slider 136 is located in the mounting through hole, and two ends of the mounting through hole are respectively plugged by a cover 139.

In one embodiment, as shown in fig. 2 and 3, the lifting mechanism 110 may be comprised of an air cylinder, a guide assembly, or the like. The lifting mechanism 110 is provided with a clamping mechanism 120, the clamping mechanism 120 comprises a clamp supporting plate 121, and a cylinder and a guide assembly of the lifting mechanism 110 are connected with the clamp supporting plate 121. The clamp comprises a clamp support plate 121, and is characterized in that two clamping assemblies are arranged on the clamp support plate 121 at intervals, each clamping assembly comprises a cylinder blocking block 122, a driving cylinder 124, a sliding rail assembly 123, a jaw frame 125, a strip-shaped mounting block 126 and a plurality of U-shaped inserts 127, the cylinder blocking blocks 122 are adjacent to the clamp support plate 121, the sliding rail assemblies 123 are connected with the clamp support plate 121, the jaw frames 125 are connected with the sliding rail assemblies 123, the driving cylinders 124 are respectively connected with the cylinder blocking blocks 122 and the jaw frames 125, the strip-shaped mounting blocks 126 are arranged at the lower ends of the jaw frames 125, each U-shaped insert 127 is arranged on the strip-shaped mounting block 126 at intervals, each U-shaped insert 127 is provided with two insert blocks 127a, each insert block 127a is used for being inserted into an insert groove 135 on a seat 131, and then pushing a driving column 137 to move, and a connecting rod type synchronization assembly 128 is arranged between the two jaw frames 125. The link synchronization assembly 128 is set to synchronize the moving distance of the two jaw frames 125.

Specifically, as shown in fig. 2 and 12, the two insert blocks 127a of the U-shaped insert 127 are configured to be inserted into the slot 135 on the base 131 and push the driving post 137 on the slider 136 to move, thereby driving the slider 136 to move. When the two inserting blocks 127a of the U-shaped inserting member 127 are inserted into the inserting grooves 135 on the base 131 and push the driving post 137, so that the sliding block 136 moves to the first position, the U-shaped inserting member 127 can support and position the detecting plate 150, at this time, the lifting mechanism 110 is lifted, so that the clamping mechanism 120 is lifted, and the detecting plate 150 supported and positioned by the U-shaped inserting member 127 is lifted. Eventually separating the sensing plate 150 from the tray 160. It will be appreciated that the lifting mechanism 110 drives the clamping mechanism 120 to descend, so that the detection plate 150 supported and positioned by the U-shaped insert 127 descends, and the upper positioning block 142 at the upper end of the guide post 141 on the tray 160 passes through the lower end hole 133 and the large hole 136b and enters the upper end hole 132, then the two claw brackets 125 of the clamping mechanism 120 are separated from each other under the driving of the corresponding driving cylinder 124, so that the U-shaped insert 127 is withdrawn from the slot 135 on the corresponding base 131, the driving post 137 on the slider 136 loses the thrust action of the U-shaped insert 127, and the slider 136 moves toward the second position under the action of the first spring 138, so that the small hole 136a of the slider 136 is clamped with the guide post 141. At this time, the detection plate 150 is fixed to the tray 160.

In one embodiment, the guide pillar mounting seat 146 is provided with a plurality of first type long holes 146a, the guide pillar mounting seat 146 is detachably connected to the moving seat 147 through bolts matched with the first type long holes 146a, the moving seat 147 is provided with a plurality of second type long holes 147a, and the extending direction of the first type long holes 146a is perpendicular to the extending direction of the second type long holes 147 a. The movable mount 147 may be secured to the tray 160 by a mating connection of bolts and the second elongated holes 147 a. The extending directions of the first long hole 146a and the second long hole 147a are perpendicular to each other, so that the position of the guide post 141 in two directions can be conveniently adjusted.

In one embodiment, the tray 160 is disposed on a vibrating platform. The vibration table is used to vibrate the tray 160. The vibrating platform may employ an existing vibrating mechanism 170.

The above examples illustrate only a few embodiments of the application, which are described in detail and are not to be construed as limiting the scope of the application. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the application, which are all within the scope of the application. Accordingly, the scope of protection of the present application is to be determined by the appended claims.

Claims

1. A CCS assembly vibration testing method, comprising:

2. The CCS assembly vibration testing method according to claim 1, wherein in S200, performance detection is performed by a detection instrument, specifically including: withstand voltage test, insulation resistance test, wire harness internal resistance test or wire harness on-off test.

3. The CCS assembly vibration testing method according to claim 1, wherein in S100, each probe on the test board contacts a corresponding soldered metal sheet on the CCS assembly specifically comprises: a portion of the probes are in contact with the nickel plate of the CCS assembly and a portion of the probes are in contact with the palladium plate of the CCS assembly.

4. The CCS assembly vibration testing method according to claim 1, wherein in S100, said locking mechanism includes a first assembly and a second assembly, the first assembly is disposed on the detection plate, the second assembly is disposed on the tray, and the second assembly is connected and fixed with the first assembly.

5. The CCS assembly vibration testing method according to claim 4, wherein the first assembly includes a base, a slider, a first spring and a driving column, the slider is provided with a small hole and a large hole which are mutually communicated, the slider is disposed in the base and is in sliding fit with the base, the first spring is disposed in the base, one end of the first spring is abutted against the base, the other end of the first spring is abutted against the slider, the base corresponding to two sides of the slider is provided with a slot, the inner side wall of the slot is provided with a strip hole, each strip hole is provided with a driving column, one end of the driving column is connected with the slider, the other end of the driving column is located outside the slot, the upper end of the base is provided with an upper end hole matched with the large hole, the lower end of the base is provided with a lower end hole matched with the large hole,

6. The CCS assembly vibration testing method according to claim 5, wherein said base is provided with a mounting through hole, said slider is located in said mounting through hole, and both ends of said mounting through hole are respectively blocked by cover plates.

7. The CCS assembly vibration testing method according to claim 5, wherein when said slider is in a first position, said large hole of said slider, said upper hole of said seat and said lower hole of said seat are in communication with each other, and when said slider is in a second position, said small hole of said slider is engaged with said guide post.

8. The CCS assembly vibration testing method according to claim 5, wherein the clamping mechanism includes a clamp support plate, two clamping assemblies are disposed on the clamp support plate at intervals, each clamping assembly includes a cylinder block, a driving cylinder, a sliding rail assembly, a jaw frame, a bar-shaped mounting block and a plurality of U-shaped inserts, the cylinder block is adjacent to the clamp support plate, the sliding rail assembly is connected to the clamp support plate, the jaw frame is connected to the sliding rail assembly, the driving cylinder is respectively connected to the cylinder block and the jaw frame, the bar-shaped mounting block is disposed at a lower end of the jaw frame, each U-shaped insert is disposed on the bar-shaped mounting block at intervals, the U-shaped insert has two inserts, and the inserts are used for being inserted into slots on the base body to push the driving column to move, and a connecting rod type synchronization assembly is disposed between the two jaw frames.

9. The CCS assembly vibration testing method according to claim 5, wherein a plurality of first long holes are formed in the guide pillar mounting seat, the guide pillar mounting seat is detachably connected to the moving seat through bolts matched with the first long holes, a plurality of second long holes are formed in the moving seat, and an extending direction of the first long holes is perpendicular to an extending direction of the second long holes.

10. The CCS assembly vibration testing method according to claim 1, wherein said tray is disposed on a vibration platform.