CN214211571U - Cleaning device and detection equipment - Google Patents

Abstract

The utility model relates to a technical field is equipped in the test, especially relates to a cleaning device and check out test set. The utility model provides a cleaning device includes two sets of wheel components and adjusting part, and wherein, two sets of wheel components are used for the clean subassembly that awaits measuring, and two sets of wheel components are along the crisscross setting of the subassembly width direction that awaits measuring, and set up along the perpendicular to subassembly width direction interval that awaits measuring, and adjusting part can adjust two sets of wheel components along the position of the subassembly width direction that awaits measuring. When the width size of the to-be-tested part changes, the cleaning device does not need to be replaced for cleaning, and the positions of the two groups of roller assemblies along the width direction of the to-be-tested part can be adjusted only through the adjusting assembly, so that the testing time is saved, the testing efficiency is improved, and the testing cost is also reduced. The utility model provides a check out test set has saved test time through using above-mentioned cleaning device, has improved efficiency of software testing, has reduced the test cost.

Description

Cleaning device and detection equipment

Technical Field

The utility model relates to a technical field is equipped in the test, especially relates to a cleaning device and check out test set.

Background

At present, to not carrying out FPC (Flexible Printed Circuit Board)/PCB (Printed Circuit Board) and binding and not carrying out the display panel that IC (Integrated Circuit) bound, when carrying out signal detection, receive operational environment's influence, after the display module material loading, the surface of display module assembly can inevitably adsorb foreign matters such as dust, impurity, if directly detect this moment, foreign matters such as dust, impurity can produce the interference to the testing result, influence the accuracy that detects, lead to detecting the precision on the low side.

In order to make the check out test set detect to the piece that awaits measuring ground more accurately, set up cleaning device on check out test set usually, cleaning device can clean the surperficial foreign matter such as dust, impurity of the piece that awaits measuring to reduce the interference that foreign matter such as dust, impurity caused the testing result. However, the existing cleaning device can only be used for cleaning the piece to be tested with a fixed width, and after the width of the piece to be tested is changed, the cleaning device matched with the width of the piece to be tested can only be replaced for cleaning, so that the time is wasted, the working efficiency is reduced, and the testing cost is increased.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a cleaning device can match the piece that awaits measuring of clean different width dimensions, has saved test time, has improved efficiency of software testing, has also reduced the test cost.

Another object of the utility model is to provide a check out test set through using above-mentioned cleaning device, has saved test time, has improved efficiency of software testing, has also reduced test cost.

To achieve the purpose, the utility model adopts the following technical proposal:

a cleaning device, the cleaning device comprising:

the roller assemblies are configured to clean the components to be tested, and are arranged in a staggered mode along the width direction of the components to be tested and are arranged at intervals along the direction perpendicular to the width direction of the components to be tested; and

and the adjusting assemblies are configured to adjust the positions of the two groups of roller assemblies along the width direction of the to-be-measured part.

Preferably, the cleaning device further comprises: a support assembly, the support assembly comprising:

a support frame;

the two groups of sliding frames are respectively arranged on the supporting frame in a sliding mode, and each group of sliding frames is provided with one group of roller assemblies in a rotating mode.

Preferably, the adjusting assembly comprises:

retaining member, every group offer the edge on the sliding frame the spout that awaits measuring a width direction and extend, seted up on the support frame with the mounting hole that the spout corresponds, the retaining member passes in proper order and corresponds the setting the spout and the mounting hole, just the retaining member can be relative the spout slides, with will sliding frame's preset position is fixed on the support frame.

Preferably, the locking member is a rotating handle, and one end of the rotating handle penetrates through the sliding groove and is in threaded connection with the mounting hole.

Preferably, the adjusting assembly further comprises:

the guide piece comprises a guide rail and a sliding block which are connected in a sliding mode, the guide rail extends in the width direction of the piece to be tested, the guide rail is fixed on the supporting frame, and the sliding block is fixed on the sliding frame.

Preferably, the cleaning device further comprises:

the first driving assembly is configured to drive the roller assembly to move along the direction perpendicular to the width direction of the component to be tested.

Preferably, the first driving assembly includes:

a drive member; and

the conveying piece is connected with the output end of the driving piece, the conveying piece is in transmission connection with the supporting component, and the driving piece drives the conveying piece to drive the supporting component to move in the width direction perpendicular to the piece to be detected.

A detection apparatus comprising a cleaning device as described above.

Preferably, the detection device further includes:

a plugging device, the plugging device comprising:

the plug is in plug-in fit with the socket of the piece to be detected; and

the conveying mechanism is configured to drive the plug to move so as to enable the plug to be in plug-in fit with the socket and enable the plug to be electrically connected with the socket.

Preferably, the detection device further includes:

a positioning device, the positioning device comprising:

a carrier configured to carry the object to be tested; and

and the adjusting and positioning assembly is arranged on the carrier and is configured to position the piece to be detected.

The utility model has the advantages that:

the utility model provides a cleaning device includes two sets of wheel components and adjusting part, two sets of wheel components are used for the clean piece that awaits measuring, adjusting part can adjust two sets of wheel components along the position of the width direction of the piece that awaits measuring, when the width grow of the piece that awaits measuring, make two sets of wheel components move to the both sides of the width of the piece that awaits measuring respectively through adjusting part, when the width of the piece that awaits measuring diminishes, make two sets of wheel components remove to the centre of the width of the piece that awaits measuring jointly through adjusting part, guarantee that two sets of wheel components can cover completely on the width direction of the piece that awaits measuring. Therefore, when the width size of the to-be-tested part changes, the cleaning device does not need to be replaced for cleaning, and the positions of the two groups of roller assemblies along the width direction of the to-be-tested part can be adjusted only by the adjusting assembly, so that the testing time is saved, the testing efficiency is improved, and the testing cost is also reduced.

The utility model provides a check out test set through using above-mentioned cleaning device, has saved test time, has improved efficiency of software testing, has also reduced the test cost.

Drawings

Fig. 1 is one of schematic structural diagrams of a detection device in an embodiment of the present invention;

FIG. 2 is a second schematic structural diagram of a detecting apparatus according to an embodiment of the present invention;

FIG. 3 is a schematic view of an embodiment of the present invention with the first drive assembly removed from the cleaning device;

FIG. 4 is an enlarged view of a portion of FIG. 3 at A;

FIG. 5 is a schematic view of a cleaning device according to an embodiment of the present invention;

fig. 6 is a schematic diagram of a plugging device in an embodiment of the present invention;

fig. 7 is a schematic view of a positioning device in an embodiment of the invention;

fig. 8 is a schematic diagram of a detection device in an embodiment of the present invention.

In the figure:

100. a detection device; 200. a piece to be tested;

1. a cleaning device; 11. a roller assembly; 12. an adjustment assembly; 121. a locking member; 122. a guide member; 1221. a guide rail; 1222. a slider; 13. a support assembly; 131. a sliding frame; 1311. a first vertical plate; 1312. a first transverse plate; 1313. a second vertical plate; 13131. a chute; 132. a support frame; 1321. mounting holes; 14. a first drive assembly; 141. a drive member; 142. a conveying member; 1421. a rotating shaft; 1422. a drive roll; 1423. a driven roller; 1424. an endless conveyor belt; 1425. a synchronous conveyor belt;

2. a plugging device; 21. a plug; 22. a conveying mechanism; 221. a first conveying structure; 222. a second conveying structure; 223. a third conveying structure; 23. an alignment mechanism;

3. a positioning device; 31. a carrier; 32. adjusting the positioning assembly; 321. a positioning structure; 3211. a first slider; 3212. a second slider; 322. a clamping structure; 3221. a third slider; 3222. a fourth slider;

4. a detection device; 41. a detection component; 42. a second drive assembly; 421. a first drive structure; 422. a second drive structure; 423. a third drive structure;

5. a housing.

Detailed Description

In order to make the technical problem solved by the present invention, the technical solution adopted by the present invention and the technical effect achieved by the present invention clearer, the technical solution of the present invention will be further explained by combining the drawings and by means of the specific implementation manner.

In the description of the present invention, unless expressly stated or limited otherwise, the terms "connected," "connected," and "fixed" are to be construed broadly, e.g., as meaning permanently connected, detachably connected, or integral to one another; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In the present disclosure, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact between the first and second features, or may comprise contact between the first and second features not directly. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

In the description of the present embodiment, the terms "upper", "lower", "left", "right", and the like are used in the orientation or positional relationship shown in the drawings only for convenience of description and simplicity of operation, and do not indicate or imply that the device or element 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 invention. Furthermore, the terms "first" and "second" are used only for descriptive purposes and are not intended to have a special meaning.

As shown in fig. 1 to fig. 2, the detection apparatus 100 of the present embodiment is used for detecting the performance of a display module. Specifically, the detection apparatus 100 includes a cleaning device 1, a plugging device 2, a positioning device 3, a detection device 4, and a housing 5. The shell 5 has the function of protecting and supporting, wherein a supporting table is arranged in the shell 5, the supporting table separates the shell 5 into an upper cavity and a lower cavity, the positioning device 3, the cleaning device 1 and the detection device 4 are all located in the upper cavity inside the shell 5, and the plugging device 2 is arranged in the lower cavity inside the shell 5. The positioning device 3 is disposed on the supporting platform, and the to-be-tested object 200 is supported on the positioning device 3, so as to position and clamp the to-be-tested object 200 through the positioning device 3. Cleaning device 1 sets up in one side of positioner 3, and cleaning device 1 is used for the clean piece 200 that awaits measuring, and plug device 2 sets up at the back of the piece 200 that awaits measuring, can carry out the grafting with the piece 200 that awaits measuring after the cleanness and light to it detects to await measuring 200 to be located detection device 4 above the piece 200 that awaits measuring.

However, when the existing detection equipment detects the pieces to be detected with different width sizes, only the cleaning device matched with the width of the pieces to be detected can be replaced for cleaning, so that the time is wasted, the working efficiency is reduced, and the test cost is increased.

In order to improve the testing efficiency and reduce the testing cost, as shown in fig. 3, the embodiment provides a cleaning device 1, the cleaning device 1 includes two sets of roller assemblies 11 and an adjusting assembly 12, the two sets of roller assemblies 11 are used for cleaning the component 200 to be tested, the two sets of roller assemblies 11 are staggered along the width direction (X direction in fig. 3) of the component 200 to be tested, and are spaced along the width direction perpendicular to the component 200 to be tested, and the adjusting assembly 12 can adjust the positions of the two sets of roller assemblies 11 along the width direction of the component 200 to be tested. When the width of the to-be-measured component 200 that is changed becomes bigger, make two sets of roller assemblies 11 move to the both sides of the to-be-measured component 200 width respectively through adjusting part 12, when the width of the to-be-measured component 200 becomes smaller, make two sets of roller assemblies 11 move to the centre of the to-be-measured component 200 width jointly through adjusting part 12, guarantee that two sets of roller assemblies 11 can cover completely in the width direction of the to-be-measured component 200. Therefore, when the width size of the to-be-tested part 200 changes, the cleaning device 1 does not need to be replaced with a new one for cleaning, and the positions of the two groups of roller assemblies 11 along the width direction of the to-be-tested part 200 can be adjusted only by the adjusting assembly 12, so that the testing time is saved, the testing efficiency is improved, and the testing cost is also reduced.

By applying the cleaning device 1, the testing device 100 provided by the embodiment saves the testing time of the testing device 100, improves the testing efficiency, and reduces the testing cost.

In addition, as shown in fig. 3, the cleaning device 1 further includes a supporting assembly 13, the supporting assembly 13 includes two sets of sliding frames 131 and a supporting frame 132, the two sets of sliding frames 131 are respectively slidably disposed on the supporting frame 132, and each set of sliding frame 131 is rotatably disposed with one set of roller assemblies 11. The supporting component 13 can not only realize effective support of the roller component 11, but also ensure that the roller component 11 can move along the width direction of the component 200 to be measured.

In this embodiment, as shown in fig. 3, each group of sliding frames 131 includes two sliding support frames symmetrically arranged, and two ends of each group of roller assemblies 11 are respectively rotatably provided with one sliding support frame, so as to ensure stable support of the sliding frames 131 on the roller assemblies 11.

Now, a specific adjusting process of the adjusting roller assembly 11 of the adjusting assembly 12 moving along the width direction of the to-be-measured part 200 is described with reference to fig. 3 to 4, as shown in fig. 3 to 4, the adjusting assembly 12 includes a locking member 121, a sliding slot 13131 extending along the width direction of the to-be-measured part 200 is formed on each sliding frame 131, a mounting hole 1321 corresponding to the sliding slot 13131 is formed on the supporting frame 132, the locking member 121 can sequentially pass through the sliding slot 13131 and the mounting hole 1321, and the locking member 121 can slide relative to the sliding slot 13131. When the position of the roller assembly 11 along the width direction of the to-be-measured component 200 needs to be adjusted, the locking member 121 is loosened, the sliding frame 131 slides, the sliding frame 131 drives the roller assembly 11 to slide along the sliding groove 13131 relative to the support frame 132, and when the sliding frame 131 slides to a preset position, the locking member 121 is locked, so that the sliding frame 131 can be stably fixed on the support frame 132. Specifically, the locking member 121 is in threaded connection with the mounting hole 1321, and the sliding frame 131 and the supporting frame 132 can be locked or released by rotating the locking member 121.

Preferably, as shown in fig. 4, the locking member 121 is a rotating handle, one end of the rotating handle passes through the sliding slot 13131 and is in threaded connection with the mounting hole 1321, the rotating handle is L-shaped, so that an operator can hold the rotating handle and apply force to the rotating handle, and the rotating handle applies a lever principle, so that the operator can rotate the rotating handle to lock or unlock the sliding frame 131 and the supporting frame 132 with less effort.

Preferably, as shown in fig. 3 to 4, the adjusting assembly 12 further includes a guide 122, the guide 122 includes a guide rail 1221 and a slider 1222 slidably connected to each other, the guide rail 1221 extends along the width direction of the device under test 200, the guide rail 1221 is fixed to the supporting frame 132, and the slider 1222 is fixed to the sliding frame 131. When the position of the sliding frame 131 relative to the supporting frame 132 along the width direction of the object 200 needs to be adjusted, the sliding frame 131 is pushed to make the sliding frame 131 move along the guide rail 1221 on the sliding block 1222 relative to the supporting frame 132 along the width direction of the object 200, so that the sliding frame 131 can be prevented from shifting in the sliding process, and a guiding effect is provided for the movement of the sliding frame 131.

Specifically, as shown in fig. 4, the sliding support frame includes a first vertical plate 1311, a first horizontal plate 1312, and a second vertical plate 1313, the roller assembly 11 is rotatably disposed on the first vertical plate 1311, the first horizontal plate 1312 is horizontally fixed to an upper end of the first vertical plate 1311, the slider 1222 is fixed to an upper end surface of the first horizontal plate 1312, the second vertical plate 1313 is vertically fixed to a side wall of the first horizontal plate 1312, the second vertical plate 1313 is provided with a sliding groove 13131, and the locking member 121 fixes the second vertical plate 1313 to the support frame 132 through the sliding groove 13131. The sliding support frame is simple in structure and reasonable in layout, not only can stably support the roller assembly 11, but also can avoid interference with the guide part 122.

In addition, as shown in fig. 5, the cleaning device 1 further includes a first driving assembly 14, and the first driving assembly 14 can drive the roller assembly 11 to move in the direction perpendicular to the width direction of the component 200 to be measured, so as to ensure that the cleaning device 1 can clean the position of the component 200 to be measured perpendicular to the width direction. Specifically, two sets of roller components 11 can be through the mode of adhesion clean the foreign matter such as dust on the subassembly 200 that awaits measuring, impurity, can wrap up sticky dirt paper on roller components 11, and when first drive assembly 14 drive roller components 11 moved along the perpendicular to subassembly 200 width direction that awaits measuring, roller components 11 can take place to roll on the subassembly 200 that awaits measuring for sticky dirt paper adheres the foreign matter such as dust, impurity on the subassembly 200 surface that awaits measuring, in order to reach clean 200 mesh that await measuring.

Preferably, when the sticky paper is used for a long time, the adhesive property of the sticky paper is reduced along with the increase of the impurity and dust adhered to the sticky paper, in order to ensure the dust removing effect, the sticky paper is detachably connected to the roller assembly 11, for example, a double-sided adhesive tape is adhered to the roller assembly 11, the sticky paper is adhered to the roller assembly 11 through the double-sided adhesive tape, when the sticky paper needs to be replaced, the sticky paper is directly torn off from the roller assembly 11, the operation is simple, and the protection and the maintenance are convenient.

Referring to fig. 5, a specific structure of the first driving assembly 14 is described, as shown in fig. 5, the first driving assembly 14 includes a driving member 141 and a conveying member 142, the conveying member 142 is connected to an output end of the driving member 141, the conveying member 142 is connected to the supporting assembly 13 in a transmission manner, and the driving member 141 drives the conveying member 142 to drive the supporting assembly 13 to move in a direction perpendicular to a width direction of the to-be-tested member 200.

Specifically, as shown in fig. 5, the driving element 141 and the conveying element 142 are disposed at the lower end of the supporting component 13, the conveying element 142 includes a rotating shaft 1421, a driving roller 1422, a driven roller 1423, an endless conveyor belt 1424 and a synchronous conveyor belt 1425, the driving element 141 may be a rotating motor, an output end of the rotating motor is rotatably connected to the rotating shaft 1421 through the synchronous conveyor belt 1425, both ends of the rotating shaft 1421 are rotatably connected to the driving roller 1422, the driven roller 1423 is disposed at one side of the driving roller 1422, the driving roller 1422 and the driven roller 1423 jointly tension the endless conveyor belt 1424, and both ends of the supporting frame 132 are disposed on the endless conveyor belt 1424. When the supporting frame 132 needs to be driven to move along the direction perpendicular to the width of the device under test 200, the rotation of the rotating motor can transmit the torque to the driving roller 1422 through the synchronous conveyor belt 1425 and the rotating shaft 1421 in sequence, and then the annular conveyor belt 1424 and the driven roller 1423 are driven to move, so that the supporting frame 132 is driven to advance. Specifically, the synchronous conveyor belt 1425 is in meshing transmission, and has accurate transmission ratio, compact structure and high conveying precision. In other embodiments, the synchronous conveyor 1425 may also be a friction belt drive, which may perform overload protection, buffering, and shock absorption functions.

At the present stage, the detection equipment adopts manual plugging to plug and light the to-be-detected piece through the plugging device, so that the operation is inconvenient, and the test efficiency is also influenced.

In order to solve the problem that the manual plugging efficiency of the plugging device 2 is low, as shown in fig. 6, the plugging device 2 includes a plug 21 and a conveying mechanism 22, the plug 21 is plugged and matched with the socket of the to-be-tested piece 200, the conveying mechanism 22 can drive the plug 21 to move, so that the plug 21 is plugged and matched with the socket, and the plug 21 is electrically connected with the socket, so that the to-be-tested piece 200 is plugged and lighted. Compared with the manual plugging mode in the prior art, the automatic plugging device is simple to operate and convenient to use, reduces the labor intensity of operators, saves the operation time and improves the test efficiency.

Specifically, as shown in fig. 6, the plugging device 2 further includes an alignment mechanism 23 and a control mechanism, the alignment mechanism 23 is configured to detect a position of the socket 200 to be tested, the alignment mechanism 23 is electrically connected to the control mechanism, the control mechanism can control the movement of the conveying mechanism 22, the alignment mechanism 23 is disposed adjacent to the plug 21, the conveying mechanism 22 can drive the plug 21 and the alignment mechanism 23 to move together, the alignment mechanism 23 can transmit the detected position information of the socket to the control mechanism, and the control mechanism controls the conveying mechanism 22 to move according to a planned path by calculating a compensation distance between the alignment mechanism 23 and the plug 21, so as to ensure that the plug 21 is plugged into the socket.

Now, a specific structure of the conveying mechanism 22 is described with reference to fig. 6, as shown in fig. 6, the conveying mechanism 22 includes a first conveying structure 221, a second conveying structure 222, and a third conveying structure 223, the plug 21 and the aligning mechanism 23 are both disposed on the third conveying structure 223, the third conveying structure 223 can drive the plug 21 and the aligning mechanism 23 to move along a vertical direction, the third conveying structure 223 is disposed on the second conveying structure 222, the second conveying structure 222 can drive the third conveying structure 223 to move along a width direction of the to-be-tested piece 200, the second conveying structure 222 is disposed on the first conveying structure 221, and the first conveying structure 221 can drive the second conveying structure 223 to move along a width direction perpendicular to the to-be-tested piece 200, so as to ensure that the plug 21 is smoothly plugged into the socket.

In addition, the positioning device in the existing detection equipment is only suitable for clamping and fixing the to-be-detected piece with the same size, and when the detection equipment needs to detect the to-be-detected pieces with other sizes, the whole positioning device needs to be replaced, so that the test efficiency is reduced, and the test cost is also increased.

In order to solve the problem that the positioning device 3 cannot be applied to the to-be-measured pieces 200 with different sizes, as shown in fig. 7, the positioning device 3 includes a carrier 31 and an adjusting and positioning assembly 32, the carrier 31 is used for bearing the to-be-measured pieces 200, the adjusting and positioning assembly 32 is disposed on the carrier 31, and the adjusting and positioning assembly 32 can position the to-be-measured pieces 200 with different sizes.

Now, a specific structure of the adjusting and positioning assembly 32 is described with reference to fig. 7, as shown in fig. 7, the adjusting and positioning assembly 32 includes a positioning structure 321 and a clamping structure 322, the positioning structure 321 includes a first slider 3211 and a second slider 3212, the first slider 3211 and the second slider 3212 are both disposed on the carrier 31, and the first slider 3211 and the second slider 3212 can respectively abut against two adjacent side edges of the to-be-measured piece 200 to position the to-be-measured piece 200. The clamping structure 322 comprises a third slider assembly and a fourth slider assembly, both the third slider assembly and the fourth slider assembly can slide along a first slide rail which is arranged on the carrier 31 and extends along the width direction of the piece to be measured 200, the third slider assembly comprises a third slider 3221 and a second slide rail which is slidably connected to the first slide rail, the second slide rail extends along the width direction which is perpendicular to the piece to be measured 200, and the third slider 3221 is slidably arranged on the second slide rail; the fourth slider assembly comprises a fourth slider 3222 and a third slide rail slidably connected to the first slide rail, the third slide rail extends along a direction perpendicular to the width of the to-be-measured object 200, and the fourth slider 3222 is slidably disposed on the third slide rail, so that the positions of the third slider 3221 and the fourth slider 3222 in the width direction of the to-be-measured object 200 and in two directions perpendicular to the width direction of the to-be-measured object 200 are adjusted, so that the third slider 3221 and the fourth slider 3222 are respectively abutted against the other two adjacent side edges of the to-be-measured object 200, the clamping structure 322 and the positioning structure 321 jointly act to clamp and fix the to-be-measured object 200, and the adjusting and positioning assembly 32 can position the to-be-measured objects 200 with different sizes.

Preferably, as shown in fig. 7, a plurality of third sliders 3221 may be disposed on the second slide rail, and the plurality of third sliders 3221 may all slide along the second guide rail, so as to ensure that the side of the to-be-measured object 200 is fixed more stably.

Now, a specific structure of the testing device 4 is described with reference to fig. 8, as shown in fig. 8, the testing device 4 includes a detecting component 41 and a second driving component 42, the to-be-detected piece 200 is located above and below the detecting component 41 and is opposite to the to-be-detected piece 200, the second driving component 42 can drive the detecting component 41 to move along a vertical direction, so that the detecting component 41 is close to or away from the to-be-detected piece 200, thereby ensuring that the detecting component 41 can completely identify and detect the to-be-detected piece 200.

However, when the size of the to-be-detected piece is too large or too small, the second driving assembly is required to drive the detection assembly to move in the vertical direction in a large range so as to select the appropriate visual field range for detecting and identifying the to-be-detected piece, which may result in the oversized size of the second driving assembly in the vertical direction, and further increase the volume of the detection equipment.

In order to simplify the size of the whole machine, as shown in fig. 8, the second driving assembly 42 includes a first driving structure 421, a second driving structure 422 and a third driving structure 423 that are arranged side by side along the horizontal direction, the detection assembly 41 is arranged on the first driving structure 421, the first driving structure 421 can drive the detection assembly 41 to move along the vertical direction, the first driving structure 421 is arranged on the second driving structure 422, the second driving structure 422 can drive the first driving structure 421 to move along the vertical direction, the second driving structure 422 is arranged on the third driving structure 423, and the third driving structure 423 can drive the second driving structure 422 to move along the vertical direction. Through setting up the drive structure that the multiunit set up side by side, can be compatible the piece 200 that awaits measuring of different sizes better, simplify whole quick-witted size. In other embodiments, the second driving assembly 42 may also be provided with a fourth driving structure, a fifth driving structure, and the like, as long as the size of the whole machine can be simplified, and the compatibility of the second driving assembly 42 to the pieces 200 to be tested with different sizes can be improved, the number of groups of driving structures is not specifically limited in this embodiment.

For the convenience of understanding the detecting apparatus 100 disclosed in the present embodiment, the operation of the detecting apparatus 100 will now be described:

when the performance of the to-be-detected piece 200 needs to be detected, firstly, two side edges of the to-be-detected piece 200 are fixed on the carrier 31 through the positioning structure 321, the other two adjacent side edges of the to-be-detected piece 200 are fixed on the carrier 31 by adjusting the position of the clamping structure 322, then the cleaning device 1 is started, the cleaning device 1 cleans foreign matters such as dust and impurities on the surface of the to-be-detected piece 200 under the driving of the first driving component 14, then the conveying mechanism 22 drives the plug 21 to be plugged with the socket on the to-be-detected piece 200, and further the to-be-detected piece 200 is lightened, finally, the second driving component 42 drives the detection component 41 to identify and detect the to-be-detected piece 200, and therefore the performance detection of the to-be-detected piece 200 is achieved.

It is obvious that the above embodiments of the present invention are only examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.

Claims (10)

1. A cleaning device, characterized in that the cleaning device comprises:

the roller assemblies (11) are configured to clean the components to be tested (200), and the roller assemblies (11) are arranged in a staggered mode along the width direction of the components to be tested (200) and are arranged at intervals along the direction perpendicular to the width direction of the components to be tested (200); and

and the adjusting assemblies (12) are configured to adjust the positions of the two groups of roller assemblies (11) along the width direction of the component to be measured (200).

2. The cleaning device of claim 1, further comprising: a support assembly (13), the support assembly (13) comprising:

a support frame (132);

the roller wheel assembly comprises two groups of sliding frames (131), wherein the two groups of sliding frames (131) are respectively arranged on the supporting frame (132) in a sliding mode, and each group of sliding frames (131) is provided with one group of roller wheel assemblies (11) in a rotating mode.

3. The cleaning device according to claim 2, characterized in that said adjustment assembly (12) comprises:

retaining member (121), every group offer on the sliding frame (131) along spout (13131) that awaits measuring (200) width direction extends, offer on support frame (132) with mounting hole (1321) that spout (13131) correspond, retaining member (121) pass in proper order and correspond the setting spout (13131) and mounting hole (1321), just retaining member (121) can be relative spout (13131) slide, with will the preset position of sliding frame (131) is fixed on support frame (132).

4. The cleaning device as claimed in claim 3, wherein the locker (121) is a rotating handle having one end screwed with the mounting hole (1321) through the sliding slot (13131).

5. The cleaning device according to claim 3, characterized in that the adjustment assembly (12) further comprises:

the guide piece (122) comprises a guide rail (1221) and a sliding block (1222) which are connected in a sliding mode, the guide rail (1221) extends along the width direction of the piece to be tested (200), the guide rail (1221) is fixed on the supporting frame (132), and the sliding block (1222) is fixed on the sliding frame (131).

6. The cleaning device of claim 2, further comprising:

a first driving assembly (14) configured to drive the roller assembly (11) to move along a direction perpendicular to the width direction of the piece to be tested (200).

7. The cleaning device according to claim 6, characterized in that said first drive assembly (14) comprises:

a driver (141); and

conveying member (142), with the output of driving piece (141) is connected, conveying member (142) with supporting component (13) transmission is connected, driving piece (141) drive conveying member (142) drive supporting component (13) are along the perpendicular to the width direction motion of piece (200) awaits measuring.

8. A test device comprising a cleaning apparatus as claimed in any one of claims 1 to 7.

9. The detection apparatus according to claim 8, characterized in that the detection apparatus further comprises:

plug device (2), plug device (2) includes:

the plug (21) is in plug-in fit with the socket of the piece to be tested (200); and

a conveying mechanism (22) configured to drive the plug (21) to move so as to enable the plug (21) to be in plug fit with the socket and enable the plug (21) to be electrically connected with the socket.

10. The detection apparatus according to claim 8, characterized in that the detection apparatus further comprises:

a positioning device (3), the positioning device (3) comprising:

a carrier (31) configured to carry the piece under test (200); and

an adjusting and positioning assembly (32) is arranged on the carrier (31) and is configured to position the piece to be detected (200).

Images