CN113504468A - Detection equipment for key assembly - Google Patents

Abstract

The embodiment of the invention discloses a detection device for a key assembly. In one embodiment, the inspection apparatus includes a base plate and a support plate having an interior cavity; the conduction assembly is used for conducting with the key assembly; the compression joint component is used for moving up and down along the vertical direction so as to enable the key component to be communicated with the conduction component; the testing device comprises a displacement plate, a first testing device and a second testing device, wherein the displacement plate comprises a first structural part and a second structural part; the testing assembly comprises a testing head and a conducting piece arranged corresponding to the testing head; the test head is connected with the corresponding conducting piece through a lead in a signal mode; the detection equipment also comprises a first signal switching block which is used for being conducted with the conducting piece; the testing head is used for testing the key assembly by conducting the conducting piece with the first signal switching block. The detection equipment of the embodiment can effectively reduce the length of the lead, simultaneously prevent the lead from being wound in the detection process, and effectively improve the test efficiency.

Description

Detection equipment for key assembly

Technical Field

The invention relates to the technical field of automation equipment. And more particularly, to a detection apparatus for a key assembly.

Background

A mobile phone is a commonly used personal communication device, and generally has functions of shooting, taking a picture, browsing a webpage, and the like. In order to ensure normal use of various functions of the mobile phone, the test is required before the product leaves a factory, and particularly, the key assembly of the mobile phone needs to be tested.

In the existing key assembly testing process, it is usually necessary to perform compression-bonding and fixing on the key assembly and then perform detection of related functions. The detection equipment in the prior art is simple in structure and poor in automation degree, and the workload of testers is large, so that the test efficiency of the key assembly is seriously influenced.

Therefore, in order to overcome the technical defects of the prior art, a new detection device for a key assembly needs to be provided.

Disclosure of Invention

The invention aims to provide detection equipment for a key assembly so as to improve the test efficiency of the key assembly.

In order to achieve at least one of the above purposes, the invention adopts the following technical scheme:

an aspect of the present invention provides a detection apparatus for a key assembly, the detection apparatus including:

the key assembly comprises a substrate and a bearing plate which is positioned on the substrate and is provided with an inner cavity, wherein the inner cavity is used for bearing the key assembly;

the conduction assembly is used for conducting with the key assembly;

the compression joint component is used for moving up and down along the vertical direction so as to enable the key component to be communicated with the conduction component;

a test device positioned above the support plate, the test device comprising:

the displacement plate comprises a first structure part and a second structure part positioned beside the first structure part;

the testing assembly comprises a testing head positioned on the first structure part and a conducting piece which is accommodated and fixed in the second structure part and is arranged corresponding to the testing head;

the test head is in signal connection with the corresponding conducting piece through a lead;

the detection equipment further comprises a first signal transfer block which is used for being conducted with the conducting piece;

the testing head is used for testing the key assembly through the conduction piece and the first signal switching block.

Optionally, the test assembly includes a plurality of test heads located on the first structure portion and a plurality of conduction pieces arranged in one-to-one correspondence with the plurality of test heads;

the plurality of test heads are arranged in a direction perpendicular to an extending direction of the internal cavity in a plane.

Optionally, the test device comprises a pressure assembly located alongside the test head;

the pressure component is configured to apply pressure to the key assembly.

Optionally, the detection apparatus comprises a moving component connected to the testing device;

the moving assembly is configured to drive the testing device to reciprocate in a vertical direction;

is configured to drive the testing device to reciprocate in the extending direction of the inner cavity, an

Configured to drive the test device to reciprocate in a direction perpendicular to an extension direction of the lumen within a plane.

Optionally, the inner cavity comprises:

the first cavity corresponds to the key part of the key assembly;

the second cavity corresponds to the circuit board part of the key assembly; and

a third cavity corresponding to the electrical connector part of the key assembly;

the pass-through assembly includes:

the conductive piece is positioned in the first cavity and is used for being conducted with the key part of the key assembly;

the second signal switching block is positioned in the second cavity and is used for being conducted with the circuit board part of the key assembly; and

and the connector is positioned in the third cavity and is used for being conducted with the electrical connector part of the key assembly.

Optionally, the crimping assembly comprises:

the first pressing head part is arranged corresponding to the first cavity and comprises a hollow hole corresponding to the pressing part of the key assembly;

the second pressure head part is arranged corresponding to the second cavity; and

and the third pressure head part is arranged corresponding to the third cavity.

Optionally, the third pressure head part comprises a connecting plate with an opening, a cover plate fixedly combined with the connecting plate, and a lower pressing piece positioned in the through hole and fixedly connected with the cover plate through an elastic piece;

the lower pressing piece is used for pressing the electric connector part of the key assembly down so as to enable the electric connector part of the key assembly to be communicated with the connector.

Optionally, the detection device comprises a drive assembly;

the drive assembly is configured to drive the crimping assembly to reciprocate in a crimping direction of the crimping assembly and to drive the crimping assembly to reciprocate in a direction in a plane perpendicular to an extension direction of the internal cavity.

Optionally, a side plate body of the substrate, which faces away from the supporting plate, includes a lifting plate;

the conductive piece penetrates through the lifting plate;

a floating piece is arranged between the lifting plate and the base plate;

the lifting plate is configured to move relative to the substrate in the acting force direction of the floating piece so as to enable conduction between the conductive piece and the key part of the key assembly;

the head end of the conductive piece extends to the outer side of the top surface of the lifting plate, and the tail end of the conductive piece extends to the outer side of the bottom surface of the lifting plate;

the bearing plate comprises a through hole for the head end of the conductive piece to pass through.

Optionally, the support plate comprises a first plate body and a second plate body;

the first cavity and the second cavity are formed on the top surface of the first plate body;

the third cavity is formed in the top surface of the second plate body.

Optionally, the substrate includes a fixed plate for accommodating and fixing the connector, and a floating plate located above the fixed plate and capable of floating up and down;

the floating plate forms the second plate body, the third cavity is formed on the floating plate, and the third cavity penetrates through the upper surface and the lower surface of the floating plate.

The invention has the following beneficial effects:

in order to solve the technical problems in the prior art, embodiments of the present invention provide a detection apparatus for a key assembly, in which a test head, a conduction piece, and a first signal transfer block are matched, so that the conduction piece is connected to the first signal transfer block, and simultaneously, the test head tests the key assembly, thereby improving test efficiency, and meanwhile, the test head and the conduction piece are both fixed in a displacement plate, thereby effectively fixing a wire between the test head and the conduction piece, preventing the wire from being pulled back and forth during a test process and being easily separated from the conduction piece, ensuring smooth signal connection between the conduction piece and the test head, and ensuring normal test of test detection. In addition, through the cooperation between the conduction assembly, the crimping assembly and the testing device, under the effect of the crimping assembly, the key assembly is conducted while the key assembly is effectively fixed, the testing device is convenient to test, the manual operation of field testing workers is not needed, a large amount of workload of testing personnel is saved, the automation degree of the detection equipment is improved, the testing efficiency of the key assembly is enhanced, and the accuracy of a testing result is improved.

Drawings

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings.

Fig. 1 shows a front view of a detection apparatus according to an embodiment of the present invention.

Fig. 2 shows a schematic view of the open box structure of the detection apparatus of one embodiment of the present invention.

Fig. 3 shows an internal structural diagram of a detection apparatus according to an embodiment of the present invention.

Fig. 4 shows a schematic structural diagram of a test apparatus according to an embodiment of the present invention.

Fig. 5 shows a schematic structural diagram of a moving assembly of one embodiment of the present invention.

Figure 6 illustrates a front view of the structure of the base plate, the support plate, the conductance assembly, and the crimp assembly of one embodiment of the present invention.

Figure 7 illustrates a structural back view of the base plate, support plate, conductance assembly, and crimp assembly of one embodiment of the present invention.

Figure 8 illustrates a front view of a base plate and support plate configuration according to one embodiment of the present invention.

Figure 9 illustrates a structural back view of the base plate and support plate of one embodiment of the present invention.

Figure 10 illustrates a schematic structural view of a crimping assembly of one embodiment of the present invention.

Fig. 11 shows a schematic structural diagram of a drive assembly of an embodiment of the present invention.

Fig. 12 shows an exploded view of the structure of the third ram head of an embodiment of the present invention.

Detailed Description

In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of one or more embodiments. It may be evident, however, that such embodiment(s) may be practiced without these specific details.

In the description of the present invention, it should be noted that the terms "upper", "lower", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, which are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and operate, and thus, should not be construed as limiting the present invention. Unless expressly stated or limited otherwise, the terms "mounted," "connected," and "connected" are intended to be inclusive and mean, for example, that they may be fixedly connected, detachably connected, or integrally connected; 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 meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

It is further noted that, in the description of the present invention, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

To solve the problems in the prior art, as shown in fig. 1 to 12, an embodiment of the present invention provides a detection apparatus 1000 for a key assembly. In a specific example, the key assembly is, for example, a home key of a mobile phone, and the key assembly includes, for example, a key portion, a Circuit board portion and an electrical connector portion, wherein the Circuit board portion is respectively connected to the key portion and the electrical connector portion, and the Circuit board portion may be, for example, a Flexible Printed Circuit (Flexible Printed Circuit). In another specific example, the electrical connector portion may be, for example, a board-to-board connector (B2B).

The detecting apparatus 1000 in this embodiment includes a box 1010 and a top plate 1020 located above the box 1010, wherein the top plate 1020 is rotatably connected to the box 1010 through a rotating shaft and a supporting plate 1021, so that the top plate 1020 can be flipped upward and fixed relative to the box 1010. The housing 1010 contains a plurality of electrical components and a signal board. Through setting up embedded transport structure, hide electric elements and semaphore board in box 1010 to can effectively save the upper portion space on the roof 1020 mesa of check out test set 1000, reduce check out test set 1000's whole height, reserve assembly space for other test equipment, make check out test set 1000's whole size compacter, satisfying under the applicable not condition that the key subassembly of overall dimension detected, be favorable to check out test set 1000's structure miniaturization.

The top plate 1020 further includes a base plate 1030 and a supporting plate 1040 having an inner cavity 1041 on the base plate 1030, the inner cavity 1041 is used for carrying the key assembly, that is, the key assembly can be placed and fixed in the inner cavity 1041 of the supporting plate 1040. In addition, the detection device 1000 further includes a conduction component for conducting with the key component, and a crimping component 1050, where the crimping component 1050 is used for moving up and down along a vertical direction, so as to conduct between the key component and the conduction component.

In this embodiment, the inspection apparatus 1000 further comprises a testing device located above the support plate 1040, the testing device comprising a displacement plate 1060 and a testing assembly 1061, the displacement plate 1060 comprising a first structural portion 10601 and a second structural portion 10602 located beside the first structural portion 10601; the test assembly 1061 includes a test head 10611 disposed on the first structure portion 10601, and a conducting element 10612 disposed corresponding to the test head 10611 and received and fixed in the second structure portion 10602. The test head 10611 is used to press the pressing portion of the key assembly to contact with the pressing portion, so as to test the key assembly. The test head 10611 and the corresponding conducting element 10612 are connected by a wire 1062 for signal connection. The detecting apparatus 1000 further includes a first signal relay block 1063 for conducting with the conducting element 10612. The conducting element 10612 is electrically connected to the first signal adapting block 1063, and the testing head 10611 is used for testing the key assembly. In one particular example, a first signal relay block 1063 is formed on the substrate 1030, the first signal relay block 1063 being electrically connected to a signal substrate within the housing 1010.

In one specific example, the lead 10612 is an elastic substance. As shown in fig. 1-4, the bottom end of the test head 10611 is used to connect to the key portion of the key assembly, and the top end of the test head 10611 is electrically connected to the wire 1062. A switch hole through which the wire 1062 passes is provided in the first structure part 10601, and a connection hole through which the wire 1062 passes is provided in the second structure part 10602. The conducting wire 1062 passes through the upper portion of the first structure portion 10601, and extends into the connecting hole of the second structure portion 10602 to be connected to the head end of the conducting element 10612, and the tail end of the conducting element 10612 protrudes and extends to the outside of the bottom surface of the second structure portion 10602.

Compared with the prior art that one end of a wire is connected with a test head usually, the other end of the wire is wound to the rear side of a top plate and is connected with a signal substrate in a box body after entering the box body from the rear side of the box body, the structure of the implementation mode can effectively collect and fixedly connect the wire 1062 of the conducting part 10612 and the test head 10611, and the risk that the wire in the prior art is easily wound on other structures or separated from the test head to cause the fault of detection equipment or even damage in the test process is avoided. Furthermore, the detection device 1000 switches the signal of the test head 10611 to the conducting element 10612, the conducting element 10612 is conducted with the first signal switching block 1063 on the substrate 1030, and the first signal switching block 1063 is directly electrically connected to the signal substrate inside the box 1010, so as to implement a normal test of the test head 10611 on the key assembly, thereby greatly reducing the length of the wire 1062, and simultaneously implementing the switching on of the test head 10611 and the test on the key assembly, effectively improving the test efficiency and prolonging the service lives of the test head 10611 and the conducting element 10612. In addition, by housing and fixing the lead 10612 in the second structure 10602, the lead 10612 can be effectively protected and fixed, and the lead 10612 can be prevented from being deformed by force. Furthermore, depending on the model, the inspection apparatus 1000 of this embodiment can realize quick replacement of the test assembly (including the test head 10611 or the vias 10612) or the base plate 1030, the support plate 1040, or the crimping assembly 1050, thereby making the model-switching inspection more efficient.

The detection apparatus 1000 according to this embodiment, through the cooperation between the test head 10611, the conducting piece 10612, and the first signal transfer block 1063, while the conducting piece 10612 is connected to the first signal transfer block 1063, the test head 10611 tests the key assembly, so as to improve the test efficiency, and meanwhile, the test head 10611 and the conducting piece 10612 are both fixed in the displacement plate 1060, so as to effectively fix the wire 1062 between the test head 10611 and the conducting piece 10612, prevent the wire 1062 from being pulled back and forth during the test process and being easily disengaged, ensure smooth signal connection between the conducting piece 10612 and the test head 10611, and ensure normal test of test detection; in addition, through the cooperation between the subassembly that switches on, crimping subassembly 1050 and the testing arrangement to under crimping subassembly 1050's effect, when effectively fixing the button subassembly, realize switching on the button subassembly, the testing arrangement test of being convenient for need not on-the-spot tester manual operation, saves tester's a large amount of work load, improves check out test set 1000's degree of automation, strengthens the efficiency of software testing of button subassembly, promotes the accuracy of test result.

In one possible implementation, the testing component 1061 includes a plurality of testing heads 10611 located on the first structure portion 10601, and a plurality of conducting elements 10612 disposed in one-to-one correspondence with the plurality of testing heads 10611. A plurality of test heads 10611 are arranged in a direction perpendicular to the extending direction of the cavity 1041 in a plane.

In a specific example, as shown in fig. 1, the extending direction of inner cavity 1041, i.e., the extending direction of the key assembly, is the X direction in fig. 1, and the direction perpendicular to the extending direction of inner cavity 1041 in the horizontal plane is the Y direction (i.e., the front-back direction) in fig. 1. In addition, the Z direction perpendicular to the plane of the X direction and the Y direction in fig. 1 is a vertical direction.

As shown in fig. 4, a plurality of test heads 10611 are arranged in the Y direction, and the plurality of test heads 10611 are used to test different functions of the key part of the key assembly. Correspondingly, a plurality of conducting elements 10612 are also arranged along the Y direction, during the testing process, while the testing head 10611 is in contact with the key part of the key assembly, the conducting element 10612 corresponding to the testing head 10611 is in conduction with the first signal adapting block 1063, and the testing head 10611 tests the corresponding function of the key part of the key assembly. After the test is finished, the plurality of test heads 10611 can move along the Y direction, the second test head 10611 contacts the key part of the key assembly, and the second conduction piece 10612 corresponding to the second test head 10611 is conducted with the first signal switching block 1063, so as to test other functions of the key part of the key assembly.

In one possible implementation, the testing apparatus includes a pressure assembly 1064 located alongside the test head 10611. The pressure assembly 1064 is configured to apply pressure to the key assembly. As shown in fig. 4, in a specific example, the pressure assembly 1064 includes a fixed block 10641 fixed to the displacement plate 1060, a moving block 10642 movable relative to the fixed block 10641, and a lower pressing head 10643 fixed to the moving block 10642, the moving block 10642 is movable back and forth in a vertical direction to move the lower pressing head 10643 up and down, and the lower pressing head 10643 is configured to contact with the key portion of the key assembly and apply a downward pressure. In one specific example, pressure assembly 1064 may further include a pressure sensor for detecting a pressure value applied by pressing head 10643 on the key portion of the key assembly, and controlling movement block 10642 to stop moving downward when the pressure value reaches a set value. In another specific example, the fixed block 10641 is a slide rail extending in a vertical direction, the moving block 10642 is a slider located on the slide rail, and the slider is driven to move on the slide rail, for example, an F-axis cylinder, a driving motor, a ball screw, or the like.

In one possible implementation, as shown in fig. 5, the detection apparatus 1000 includes a moving component connected to the testing device. The moving assembly is configured to drive the testing device to reciprocate in the vertical direction; and is configured to drive the test device to reciprocate in the extending direction of the inner cavity 1041, and is also configured to drive the test device to reciprocate in a direction perpendicular to the extending direction of the inner cavity 1041 in a plane.

In a specific example, the moving assembly includes a moving plate 1070 fixed on the top plate 1020 and a moving rack 1071 located on the moving plate 1070, a Z-axis slide rail 1072 and a Z-axis electric cylinder 1073 are disposed on the moving rack 1071, and the testing device is slidably connected to the Z-axis slide rail 1072 through a fixed rack 1074 and is connected to an output end of the Z-axis electric cylinder 1073. The Z-axis electric cylinder 1073 is used to drive the fixing frame 1074 to move in the vertical direction, so as to drive the testing device (including the testing head 10611 and the conducting piece 10612) to move up and down, and when the testing head 10611 moves down and contacts with the key assembly, the conducting piece 10612 is conducted with the first signal transfer block 1063 on the substrate 1030, thereby realizing the test of the key assembly.

The moving assembly further includes an X-direction slide rail 1075 located on the front surface of the top plate 1020 and an X-axis cylinder 1076 located on the back surface of the top plate 1020, the moving plate 1070 is slidably connected to the X-direction slide rail 1075 and the output end of the X-axis cylinder 1076, respectively, and the X-axis cylinder 1076 is configured to drive the moving plate 1070 to reciprocate in the X direction (i.e., the extending direction of the inner cavity 1041). The moving assembly further includes a Y-direction slide rail 1077 and a Y-axis cylinder 1078 on the moving plate 1070, the moving frame 1071 is connected with the Y-direction slide rail 1077 in a sliding manner and with an output end of the Y-axis cylinder 1078, and the Y-axis cylinder 1078 is used for driving the moving frame 1071 to reciprocate in the Y-axis direction. This implementation is through setting up X axle electric jar 1076, Y axle electric jar 1078 and Z axle electric jar 1073 to drive testing arrangement reciprocating motion in X direction, Y direction and Z direction, thereby be applicable to the detection to the key assembly of different positions.

In the example including the plurality of test heads 10611 and the corresponding plurality of conducting elements 10612, after the first test head 10611 completes the test, the Y-axis electric cylinder 1078 drives the testing apparatus to move in the Y direction, so that the second test head 10611 corresponds to the key component, the Z-axis electric cylinder 1073 controls the second test head 10611 to move downward, and the conducting element 10612 corresponding to the second test head 10611 is conducted with the first signal adapting block 1063, so as to implement the test of the second function of the key component, and the test workflow of the other test heads is the same as above.

In one possible implementation, as shown in fig. 6-9, the inner cavity 1041 includes a first cavity 10411 corresponding to the key portion of the key assembly, a second cavity 10412 corresponding to the circuit board portion of the key assembly, and a third cavity 10413 corresponding to the electrical connector portion of the key assembly. In one specific example, the shape of the first cavity 10411 corresponds to the shape and size of the key portion of the key assembly, the shape and size of the second cavity 10412 corresponds to the shape and size of the circuit board portion of the key assembly, and the shape and size of the third cavity 10413 corresponds to the shape and size of the electrical connector portion of the key assembly, so that the key assembly is fixed in the inner cavity 1041 of the supporting plate 1040, and the key assembly is prevented from shifting back and forth or left and right.

In addition, the conducting assembly includes a conductive member 1080 located in the first cavity 10411 for conducting with the key portion of the key assembly, a second signal transfer block 1081 located in the second cavity 10412 for conducting with the circuit board portion of the key assembly, and a connector 1082 located in the third cavity 10413 for conducting with the electrical connector portion of the key assembly. In one particular example, the second signal transfer block 1081 is a metal block.

Specifically, when the button subassembly is placed at the inner chamber 1041 of bearing board 1040, crimping subassembly 1050 moves down along vertical direction, crimping subassembly 1050 contacts with the button subassembly and drives the button subassembly move down, make button subassembly button portion and electrically conductive 1080 contact, second signal switching piece 1081 contacts with the becket at the button subassembly circuit board portion back, button subassembly electrical connector portion contacts with connecing ware 1082, thereby realize when fixed the button subassembly crimping, with the button portion of button subassembly, circuit board portion and electrical connector portion switch on simultaneously, test device tests the button subassembly.

This implementation can be in effective fixed key assembly, realizes switching on key assembly button portion, circuit board portion and electric connector portion simultaneously, once only realizes the crimping and switches on, tests through testing arrangement afterwards, need not the manual crimping of field test workman or switches on, further reduces work load, improves this check out test set 1000's degree of automation, promotes efficiency of software testing and accuracy to key assembly.

In one possible implementation, as shown in fig. 8-9, a sensor 10414 is further included in the supporting plate 1040, and the sensor 10414 is configured to detect whether the key assembly is located in a predetermined position. In one specific example, the sensor 10414 can be, for example, an optical sensor or an infrared sensor, and when the key assembly is placed in the inner cavity 1041 of the supporting plate 1040, that is, the key assembly is located above the sensor 10414, light emitted from the sensor 10414 is blocked by the key assembly, so that it is determined that the key assembly has been placed in the preset position. In another possible implementation manner, the first cavity 10411, the second cavity 10412, and the third cavity 10413 are connected to each other, so as to ensure that the positions of the parts of the key assembly placed in the inner cavity 1041 do not shift, and ensure that the parts of the key assembly are normally connected and conducted with the conducting assembly.

In one possible implementation, as shown in fig. 8-9, the support plate 1040 includes an absorption structure for absorbing and fixing the key assembly. The adsorption structure includes air passages penetrating the upper and lower surfaces of the support plate 1040, and the air passages form adsorption holes 1042 on the top surface of the support plate 1040. In addition, the air vent channel is formed with a connection hole at the bottom surface of the support plate 1040, and connected with a vacuum suction nozzle 1043. This vacuum nozzle 1043 can be connected fixedly with external equipment, and the passageway of ventilating can set up to the vacuum adsorption pipeline for the vacuum suction that external equipment produced passes through vacuum nozzle 1043 and the direct action of passageway of ventilating is on the key assembly, thereby ensures to inject the key assembly in fixed position, ensures the key assembly and switches on the subassembly and forms stable electric connection, still can avoid gas leakage simultaneously. In one specific example, the adsorption holes 1042 may be long waist type holes as shown in fig. 8. In another specific example, the vent channel is formed, for example, at a location of the bearing plate 1040 corresponding to the second cavity 10412.

In a possible implementation manner, as shown in fig. 8-9, a side plate body of the base plate 1030, which faces away from the supporting plate 1040, includes a lifting plate 1031, a conductive member 1080 is disposed through the lifting plate 1031, a head end of the conductive member 1080 extends to an outer side of a top surface of the lifting plate 1031, a tail end of the conductive member 1080 extends to an outer side of a bottom surface of the lifting plate 1031, and the supporting plate 1040 includes a through hole for the head end of the conductive member 1080 to pass through. A floating member 1032 is included between the lifting plate 1031 and the substrate 1030, and the lifting plate 1031 is configured to be movable relative to the substrate 1030 in the acting force direction of the floating member 1032, so that the conductive member 1080 and the key portion of the key assembly are in contact with each other, thereby achieving conduction.

Specifically, after the key assembly is placed in the inner cavity 1041 of the supporting plate 1040, the lifting plate 1031 moves upward in the vertical direction relative to the base plate 1030, and the head end of the conductive piece 1080 on the lifting plate 1031 passes through the base plate 1030 and the through hole on the supporting plate 1040, so as to expose the top surface of the supporting plate 1040, so that the head end of the conductive piece 1080 contacts with the back surface of the key portion of the key assembly, thereby realizing the conduction of the key portion of the key assembly. After the test is completed, the lifting plate 1031 moves downward relative to the substrate 1030, so as to drive the head end of the conductive piece 1080 to move downward, and the head end of the conductive piece 1080 is disconnected from the key part of the key assembly. In the implementation mode, the lifting plate 1031 is arranged to drive the conductive piece 1080 to move up and down, so that the head end of the conductive piece 1080 can be protected, and the head end of the conductive piece 1080 is accommodated below the bearing plate 1040 under the condition that the test is not performed, so that damage caused by rubbing between the head end of the conductive piece 1080 and other parts is prevented.

In one possible implementation, the detection apparatus 1000 further comprises a lift assembly configured to drive the lift plate 1031 to reciprocate in the force direction of the floatation members 1032. In a specific example, as shown in fig. 6 to 9, the lifting assembly includes a fixed plate 1090 fixed to the base plate 1030, and a needle cylinder 1091 located on the fixed plate 1090, wherein an output end of the needle cylinder 1091 is connected to the lifting plate 1031, so that the needle cylinder 1091 drives the lifting plate 1031 to move in a vertical direction, so that a head end of the conductive member 1080 is connected to the key portion of the key assembly. In a specific example, the lifting plate 1031 further includes a plurality of guide shafts 1033, the guide shafts 1033 are disposed on the lifting plate 1031 through bearings, the head ends of the guide shafts 1033 are fixed on the base plate 1030, and by providing the plurality of guide shafts 1033, it is ensured that the conductive members 1080 do not shift in the vertical direction, and it is ensured that the key portion of the key assembly is normally connected to the conductive members 1080.

In one possible implementation, the support plate includes a first plate and a second plate, the first cavity 10411 and the second cavity 10412 are formed on the top surface of the first plate, and the third cavity 10413 is formed on the top surface of the second plate. In another possible implementation, the base plate 1030 includes a fixed plate 1034 for accommodating the fixed connector 1082, and a floating plate 1035 which is located above the fixed plate 1034 and can float up and down. The floating plate 1035 forms a second plate body, and the third cavity 10413 is formed on the floating plate 1035, and the third cavity 10413 penetrates the upper and lower surfaces of the floating plate 1035. In one particular example, the floating plate 1035 is attached to the fixed plate 1034 by a spring.

Specifically, when the key assembly electrical connector portion is placed in the third cavity 10413, the connector 1082 is positioned within the float plate 1035, and the key assembly electrical connector and the connector 1082 are not in contact. Along with the downward crimping of crimping subassembly 1050, drive cell-phone button electrical connector portion and move down to drive floating plate 1035 and move down, make button subassembly electrical connector portion and connect the ware 1082 with inserting and realize switching on. When the test is completed, the press-fit assembly 1050 moves upward, and under the force of the spring between the floating plate 1035 and the fixed plate 1034, the floating plate 1035 moves upward, so that the key assembly electrical connector portion is driven to move upward, and the key assembly electrical connector portion is separated from the connector 1082. The structure of this implementation can accommodate the connector 1082 in the floating plate 1035 under the condition that need not test to the connector 1082 plays the guard action, when needing to test, only needs the crimping subassembly 1050 to drive the button subassembly electrical connector portion downstream can realize button subassembly electrical connector and connector 1082 be connected and switch on.

In one possible implementation, as shown in fig. 10-12, the crimping assembly 1050 includes a first ram 1051 disposed in correspondence with the first cavity 10411, a second ram 1052 disposed in correspondence with the second cavity 10412, and a third ram 1053 disposed in correspondence with the third cavity 10413. In addition, the first pushing head 1051 includes a hollow 1054 corresponding to the pushing portion of the key assembly. When the crimp assembly 1050 moves downward in the vertical direction, the first press head 1051 is used to crimp the stationary key assembly key portion, the second press head 1052 is used to crimp the stationary key assembly circuit board portion, and the third press head 1053 is used to crimp the stationary key assembly electrical connector portion. Moreover, through setting up fretwork hole 1054, when first pressure head 1051 downstream, with the peripheral edge crimping of key subassembly button portion fixed, the splenium of pressing the button subassembly button portion exposes from fretwork hole 1054 to subsequent test head 10611 tests the button subassembly, both can guarantee the fixed of button subassembly button portion, can not cause the interference to subsequent splenium detection simultaneously.

In one possible implementation, as shown in fig. 10-12, detection apparatus 1000 includes a drive assembly 1100, drive assembly 1100 configured to drive a reciprocating motion of crimp assembly 1050 in a crimping direction of crimp assembly 1050, and to drive a reciprocating motion of crimp assembly 1050 in a direction in-plane that is perpendicular to an extension direction of inner cavity 1041.

In one possible implementation, the driving assembly includes a driving fixing plate fixed in combination with the substrate, and a first driving member and a second driving member fixed on the driving fixing plate. The first driving member includes a first fixing portion and a first moving portion movable relative to the first fixing portion, the first fixing portion may be, for example, a first slide rail, and the first moving portion may be, for example, a first slider located on the first slide rail. The extending direction of the first slide rail is the vertical direction, and the first slide block can move in the extending direction of the first slide rail, so that the crimping assembly is driven to reciprocate in the vertical direction. In addition, the second driving member includes a second fixing portion and a second driving portion movable relative to the second fixing portion, the second fixing portion may be, for example, a second slide rail, the second moving portion may be, for example, a second slider, and the second slider is fixedly coupled to the first fixing portion. The extending direction of the second slide rail is the front-back direction, i.e. the Y direction perpendicular to the extending direction of the inner cavity (or the extending direction of the key assembly) in the horizontal plane. The second sliding block moves on the second sliding rail, so that the crimping component can be driven to reciprocate in the front-back direction. It is understood that the first driving member and the second driving member may also be a linear module, a ball screw, a driving motor, an air cylinder, etc., which is not further limited in the present invention.

In one specific example, as shown in fig. 11, the driving assembly 1100 includes a compound cylinder 1102 fixed to the driving fixing plate 1101 in combination with the base plate 1030 and fixed to the driving fixing plate 1101, and a first pressing head 1051, a second pressing head 1052 and a third pressing head 1053 of the crimping assembly 1050 are connected and fixed to an output end of the compound cylinder 1102 through a pressing head connecting plate 1055, and the compound cylinder 1102 may drive the pressing head connecting plate 1055 and the crimping assembly 1050 to reciprocate in a vertical direction and in a front-rear direction. In one specific example, the drive assembly 1100 further includes a stop 1103, and the stop 1103 is used to limit the distance that the crimp assembly 1050 moves in the forward-rearward direction, and prevent the crimp assembly 1050 from moving forward too long to cause the crimp assembly 1050 to collide with the support plate 1040.

In one possible implementation, as shown in fig. 12, the third ram portion 1053 includes a connecting plate 10532 having an opening 10531, a cover plate 10533 secured in combination with the connecting plate 10532, and a hold-down 10535 located within the opening 10531 and secured to the cover plate 10533 by a resilient member 10534; the hold down 10535 is used to hold down the key assembly electrical connector portion to allow communication between the key assembly electrical connector portion and the connector 1082. The elastic member 10534 may be a spring, for example, i.e., the pressing member 10535 is connected to the cover 10533 via the spring, while ensuring that the pressing member 10535 can float up and down relative to the cover 10533. In one particular example, the cover 10533 and the connecting plate 10532 are secured by a threaded connection.

In another specific example, the third pressing head 1053 further includes a stopper 10536 on a side of the connecting plate 10532 facing away from the cover 10533, and the stopper 10536 may be connected to the connecting plate 10532 by screws, for example. This stopper 10536 is used for spacing the distance that third pressure head portion 1053 moved down along the vertical direction, prevents that third pressure head portion 1053 from moving down too much distance to crush button subassembly electrical connector portion.

Specifically, when the key assembly electrical connector portion is placed in the third cavity 10413, the key assembly electrical connector portion is not in contact with the connector 1082, and when the third pressing head 1053 moves downward, the pressing piece 10535 is in contact with the key assembly electrical connector portion and drives the key assembly electrical connector portion to move downward to be in contact with the connector 1082, so that conduction is achieved. The lower pressing piece 10535 of the implementation mode is fixedly connected with the cover plate 10533 through the elastic piece 10534, so that the acting force applied to the key assembly electric connector is output by the spring force of the elastic piece 10534 between the lower pressing piece 10535 and the cover plate 10533, rather than the force directly output by the driving assembly, the electric connector part of the key assembly is prevented from being damaged by the force directly output by the driving assembly, and the quality of the key assembly is ensured.

In a possible implementation manner, the top plate 1020 includes a plurality of base plates 1030, a plurality of supporting plates 1040 located on the base plates 1030, and a plurality of crimping assemblies 1050 and conduction assemblies corresponding to the base plates 1030, so that while a group of key assemblies is tested, another group of key assemblies can be placed in an inner cavity 1041 of another supporting plate 1040 in advance, and the crimping assemblies 1050 are pressed down to be fixed and conducted, and after the first group of key assemblies are tested, the second group of key assemblies can be directly tested, thereby effectively saving the test time and improving the test efficiency.

The specific workflow of the detection device is as follows:

firstly, the key assembly is placed in the inner cavity 1041 of the supporting plate 1040, after the sensor 10414 senses that the key assembly is in place, the external vacuum generator device works, vacuum suction force generated by the vacuum generator directly acts on the key assembly through the vacuum suction nozzle 1043, the ventilation channel and the suction hole 1042, and the key assembly is fixed in the inner cavity 1041 in a suction manner. At the same time, the drive assembly 1100 drives the crimp assembly 1050 forward, moving to the first 1051, second 1052 and third 1053 ram portions of the crimp assembly 1050 corresponding to portions of the key assembly. The drive assembly 1100 drives the press-fit assembly 1050 to be pressed downwards, the second signal switching block 1081 is contacted and conducted with the metal ring at the back of the key assembly circuit board part, the key assembly electrical connector part is contacted and conducted with the connector 1082, and meanwhile, the lifting assembly drives the lifting plate 1031 to move upwards in the vertical direction, so that the head end of the conductive piece 1080 is connected and conducted with the key assembly press-key part.

Then, the moving component drives the testing device to move forward along the Y-axis direction, and moves to a position where the testing head corresponds to the key portion of the key assembly, and the moving component drives the testing device to move downward along the Z-axis direction, so that the testing head 10611 contacts with the key portion of the key assembly, and meanwhile, the conducting piece 10612 is conducted with the first signal switching block 1063 on the substrate 1030, thereby realizing the testing of the key assembly. Thereafter, the moving component drives the testing device to move upward and continue to move forward, so that the second testing head 10611 corresponds to the key component. The moving component drives the testing device to move downward, so that the second testing head 10611 contacts with the key component and tests, and the testing process of the testing head 10611 is the same as that described above, and is not described again.

After the detection is finished, the moving assembly drives the testing device to move upwards, the lifting assembly drives the lifting plate 1031 to move downwards, the lifting plate 1031 restores to the initial position, and the conductive piece 1080 is separated from the key part of the key assembly; at the same time, the driving assembly 1100 drives the press-fit assembly 1050 to rise, the second signal relay block 1081 is separated from the metal ring on the back surface of the key assembly circuit board portion, and the key assembly electrical connector portion is separated from the connector 1082. Subsequently, the driving assembly 1100 drives the pressing assembly 1050 to move backward, and the vacuum generator operates to break the vacuum suction. And finally, taking out the key assembly.

It should be understood that the above-mentioned 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, and it will be obvious to those skilled in the art that other variations or modifications may be made on the basis of the above description, and all embodiments may not be exhaustive, and all obvious variations or modifications may be included within the scope of the present invention.

Claims (11)

1. A detection device for a key assembly, the detection device comprising:

the key assembly comprises a substrate and a bearing plate which is positioned on the substrate and is provided with an inner cavity, wherein the inner cavity is used for bearing the key assembly;

the conduction assembly is used for conducting with the key assembly;

the compression joint component is used for moving up and down along the vertical direction so as to enable the key component to be communicated with the conduction component;

a test device positioned above the support plate, the test device comprising:

the displacement plate comprises a first structure part and a second structure part positioned beside the first structure part;

the testing assembly comprises a testing head positioned on the first structure part and a conducting piece which is accommodated and fixed in the second structure part and is arranged corresponding to the testing head;

the test head is in signal connection with the corresponding conducting piece through a lead;

the detection equipment further comprises a first signal transfer block which is used for being conducted with the conducting piece;

the testing head is used for testing the key assembly through the conduction piece and the first signal switching block.

2. The detection apparatus according to claim 1,

the testing assembly comprises a plurality of testing heads positioned on the first structure part and a plurality of conducting pieces which are arranged in one-to-one correspondence with the testing heads;

the plurality of test heads are arranged in a direction perpendicular to an extending direction of the internal cavity in a plane.

3. The detection apparatus according to claim 1,

the testing device comprises a pressure assembly positioned beside the testing head;

the pressure component is configured to apply pressure to the key assembly.

4. The detection apparatus according to claim 1,

the detection equipment comprises a moving component connected with the testing device;

the moving assembly is configured to drive the testing device to reciprocate in a vertical direction;

is configured to drive the testing device to reciprocate in the extending direction of the inner cavity, an

Configured to drive the test device to reciprocate in a direction perpendicular to an extension direction of the lumen within a plane.

5. The detection apparatus according to claim 1,

the inner cavity comprises:

the first cavity corresponds to the key part of the key assembly;

the second cavity corresponds to the circuit board part of the key assembly; and

a third cavity corresponding to the electrical connector part of the key assembly;

the pass-through assembly includes:

the conductive piece is positioned in the first cavity and is used for being conducted with the key part of the key assembly;

the second signal switching block is positioned in the second cavity and is used for being conducted with the circuit board part of the key assembly; and

and the connector is positioned in the third cavity and is used for being conducted with the electrical connector part of the key assembly.

6. The detection apparatus according to claim 5,

the crimping assembly includes:

the first pressing head part is arranged corresponding to the first cavity and comprises a hollow hole corresponding to the pressing part of the key assembly;

the second pressure head part is arranged corresponding to the second cavity; and

and the third pressure head part is arranged corresponding to the third cavity.

7. The detection apparatus according to claim 6,

the third pressure head part comprises a connecting plate with an opening, a cover plate fixedly combined with the connecting plate and a lower pressing piece positioned in the through hole and fixedly connected with the cover plate through an elastic piece;

the lower pressing piece is used for pressing the electric connector part of the key assembly down so as to enable the electric connector part of the key assembly to be communicated with the connector.

8. The detection apparatus according to claim 1,

the detection device comprises a driving assembly;

the drive assembly is configured to drive the crimping assembly to reciprocate in a crimping direction of the crimping assembly and to drive the crimping assembly to reciprocate in a direction in a plane perpendicular to an extension direction of the internal cavity.

9. The detection apparatus according to claim 5,

a side plate body of the base plate, which is far away from the bearing plate, comprises a lifting plate;

the conductive piece penetrates through the lifting plate;

a floating piece is arranged between the lifting plate and the base plate;

the lifting plate is configured to move relative to the substrate in the acting force direction of the floating piece so as to enable conduction between the conductive piece and the key part of the key assembly;

the head end of the conductive piece extends to the outer side of the top surface of the lifting plate, and the tail end of the conductive piece extends to the outer side of the bottom surface of the lifting plate;

the bearing plate comprises a through hole for the head end of the conductive piece to pass through.

10. The detection apparatus according to claim 5,

the bearing plate comprises a first plate body and a second plate body;

the first cavity and the second cavity are formed on the top surface of the first plate body;

the third cavity is formed in the top surface of the second plate body.

11. The detection apparatus according to claim 10,

the base plate comprises a fixed plate for accommodating and fixing the connector and a floating plate which is positioned above the fixed plate and can float up and down;

the floating plate forms the second plate body, the third cavity is formed on the floating plate, and the third cavity penetrates through the upper surface and the lower surface of the floating plate.

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