CN217183478U - TWS earphone pressure and touch sensitivity detection equipment - Google Patents

Abstract

The utility model discloses a TWS earphone pressure and sense of touch sensitivity check out test set. The utility model discloses a TWS earphone pressure and touch sensitivity detection device comprises an earphone fixture, a pressure block, a capacitance pen and a thimble; when the tool is used, the TWS earphone is placed on the earphone jig; the pressure block, the capacitance pen and the thimble are separately arranged outside the earphone jig and can respectively and independently move close to or away from the earphone jig, the pressure block and the capacitance pen correspondingly press and touch a pressure key and a touch key on the TWS earphone, standardized detection of pressure feeling and touch feeling is achieved, and the detection result has high consistency. Moreover, set up corresponding pressure piece driving piece, electric capacity pen driving piece and thimble driving piece, can realize the pressure piece the electric capacity pen and the accurate location of thimble removes, and then can realize the automatic detection of TWS earphone pressure and sense of touch, greatly improves detection efficiency.

Description

TWS earphone pressure and touch sensitivity detection equipment

Technical Field

The utility model relates to an earphone check out test set technical field, concretely relates to TWS earphone pressure and sense of touch sensitivity check out test set.

Background

In the TWS headset, for convenience of use and improvement of experience, a pressure button and a touch button are provided to perform control functions such as volume adjustment and switching. The corresponding action signals of the pressure key and the touch key are mainly obtained through the arranged pressure sensor and the capacitive touch sensor respectively and are transmitted to the control center. The sensitivity of the pressure key and the touch key is directly related to the service performance and experience of the TWS, so that the sensitivity of the TWS earphone needs to be detected before the TWS earphone leaves a factory.

At present, for the sensitivity detection of the TWS earphone, the mass production test detection equipment still stays in a manual simple test, for example, the test of a pressure key is only manually pressed, the force for manually pressing a sensor cannot be accurately controlled, and the test result has great difference; the capacitance touch key is only touched by fingers to test the sensitivity, and the test accuracy cannot be guaranteed due to the difference of individual human bodies and the difference of capacitance and charge attached to the human bodies. Therefore, the pressure and touch detection accuracy of the TWS headset cannot be effectively guaranteed.

In addition, the manual detection efficiency of manpower is low, the labor cost is high, and with the great popularization of TWS earphones, the manual detection of manpower is completed, the production requirement cannot be met, and the mass production scale of TWS is restricted.

SUMMERY OF THE UTILITY MODEL

Detect to have the problem that the detection precision can't be ensured, the error is big, detection efficiency is low for the pressure of solving current TWS earphone and sense of touch, the utility model provides a TWS earphone pressure is felt and sense of touch sensitivity check out test set. The pressure and touch sensitivity detection equipment for the TWS earphone can realize the standardized and accurate detection of the pressure and touch of the TWS earphone, can realize automatic detection and has high detection efficiency.

The purpose of the utility model is realized through the following technical scheme.

A TWS earphone pressure and touch sensitivity detection device comprises an earphone jig, a pressure block, a capacitance pen and a thimble; when the earphone fixture is used, the earphone is placed on the earphone fixture; the pressure block, the capacitance pen and the ejector pin are separately arranged outside the earphone jig and can respectively and independently move close to or away from the earphone jig.

In a preferred embodiment, the earphone fixture is provided with a placing position, and when the earphone fixture is used, the earphone is placed on the placing position in a positioning mode.

In a more preferred embodiment, the placement site is provided with a capacitance pen access port and a thimble access port.

In a preferred embodiment, a pressure block drive is provided; the pressure block driving piece is in transmission connection with the pressure block and can drive the pressure block to move close to or away from the earphone jig.

In a preferred embodiment, the pressure block is located above the earphone fixture and can move up and down to approach or leave the earphone fixture.

In a more preferred embodiment, a pressure block driving part is arranged, and the pressure block is in transmission connection with the pressure block driving part through a weight bracket; the pressure block driving part is in transmission connection with the weight support, and the pressure block can be driven to move close to or away from the earphone jig by driving the weight support to move.

In a further preferred embodiment, the pressure block is movably mounted on the weight bracket and has a pressing head which passes downward through the weight bracket, the pressing head is close to the headset jig relative to the weight bracket, and the pressure block can freely move up and down on the weight bracket.

In a preferred embodiment, a top pressure buffer is provided; when the pressure block moves close to the earphone fixture, the jacking buffer can enable the pressure block to slowly approach the earphone fixture.

In a preferred embodiment, a capacitive pen drive is provided; the capacitance pen driving part is in transmission connection with the capacitance pen and can drive the capacitance pen to move close to or far away from the earphone jig.

In a preferred embodiment, a thimble drive is provided; the thimble driving piece can drive the thimble to move close to or far away from the earphone jig.

In a more preferred embodiment, the thimble is mounted on a thimble base, and the thimble driving member is in transmission connection with the thimble base.

In a preferred embodiment, the TWS headset pressure and touch sensitivity detecting device further includes an upper computer; at least the thimble with the host computer is connected.

Compared with the prior art, the utility model has the advantages of as follows and beneficial effect:

the utility model provides a TWS earphone pressure and touch sensitivity detection device, which is provided with an earphone jig, a pressure block, a capacitance pen and a thimble which can move close to or far away from the earphone jig, when in detection use, the TWS earphone can be positioned and placed on the earphone jig, the pressure block, the capacitance pen and the thimble can position and move the TWS earphone which is arranged close to the earphone fixture, the pressure block and the capacitance pen correspondingly press and touch the pressure key and the touch key on the TWS earphone, wherein the pressure block can be set to generate the pressing of the pressure key based on the self gravity, thereby simulating the manual pressing and the human touch, the pressure and touch of the TWS earphone are detected in a standardized way, the detection precision is high, the error of manual detection is reduced, and the detection structure of the TWS earphone capable of effectively guaranteeing mass production based on the standardized detection operation has high consistency, thereby ensuring the stability of the quality of the mass production product.

Moreover, the corresponding pressure block driving piece, the capacitance pen driving piece and the ejector pin driving piece are arranged, so that accurate positioning movement of the pressure block, the capacitance pen and the ejector pin can be realized, and the stability of detection operation can be guaranteed. Meanwhile, the pressure block driving piece, the capacitance pen driving piece and the thimble driving piece can be automatically controlled to realize the automatic control of the positioning movement of the pressure block, the capacitance pen and the thimble, and a corresponding upper computer is arranged to output and receive corresponding automatic action instructions and detection signals, so that the pressure and touch automatic detection of the TWS earphone can be realized, and the detection efficiency is greatly improved.

Drawings

Fig. 1 is a schematic structural diagram of a TWS earphone pressure and touch sensitivity detecting device according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a TWS headset configuration;

fig. 3 is a schematic structural view of an earphone fixture;

FIG. 4 is a schematic view of a pressure sensing module;

FIG. 5 is a schematic view of a tactile sensation detecting assembly;

FIG. 6 is a schematic structural view of the thimble detecting assembly;

the attached drawings are marked as follows: 1-base station base, 2-button, 3-earphone tool, 301-placement position, 302-capacitance pen access port, 303-thimble access port, 4-TWS earphone, 401-pressure button, 402-touch key, 5-pressure detection component, 51-pressure block, 511-press head, 52-pressure ejector rod driving component, 53-weight support, 54-pressure buffer, 55-pressure detection support, 6-touch detection component, 61-capacitance pen, 62-capacitance pen driving component, 63-touch detection support, 7-thimble detection component, 71-thimble, 72-thimble driving component, 73-thimble base.

Detailed Description

The technical solution of the present invention will be described in further detail with reference to the following specific embodiments and accompanying drawings, but the scope of protection and the implementation of the present invention are not limited thereto.

In the description of the specific embodiments, it should be noted that the terms "upper", "lower", "front", "back", "left", "right", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention are usually placed in when used, and are only used for convenience of describing the present invention and simplifying the description, but do not indicate or imply that the structures or elements to be referred must have specific orientations, be constructed in specific orientations, and be operated, and therefore, should not be construed as limiting the present invention, nor indicating or implying relative importance.

Unless expressly stated or limited otherwise, the terms "mounted," "disposed," "connected," "secured," and the like are to be construed broadly and can include, for example, fixed connections, removable connections, or integral connections; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate. Additionally, where the term "and/or" is used, all references herein are to the inclusion of any and all combinations of one or more of the associated listed items.

Example one

The utility model discloses a TWS earphone pressure and sense of touch sensitivity check out test set please refer to and show in figure 1, including earphone tool 3 to and set up pressure detection subassembly 5, sense of touch detection subassembly 6 and thimble detection subassembly 7 outside earphone tool 3. Wherein, earphone tool 3, pressure sense determine module 5, sense of touch determine module 6 and thimble determine module 7 all set up on a base station base 1, and pressure sense determine module 5, sense of touch determine module 6 and thimble determine module 7 set up separately for earphone tool 3.

When the detection is used, the TWS earphone 4 is placed on the earphone jig 3. Referring to fig. 2, the TWS headset 4 to be detected has a head and a tail. Wherein, a power amplifier device is arranged in the head of the TWS earphone 4, and the front end of the head is provided with a sound transmission hole and a sound transmission net arranged on the sound transmission hole; the tail of the TWS earphone 4 is provided with a communication contact type thimble, and the contact type thimble is connected and conducted with a main board of a power amplifier in the TWS earphone 4. Moreover, a pressure button 401 and a touch button 402 are arranged on the TWS headset 4, the pressure button 401 and the touch button 402 are operatively connected with the main board inside the TWS headset 4, and the main board can generate corresponding signals by pressing the pressure button 401 or touching the touch button 402.

Referring to fig. 3, the headset fixture 3 has a placement position 301, wherein the placement position 301 is a groove adapted to the TWS headset 4 and has a front end and a rear end corresponding to the head and the tail of the TWS headset 4. During the detection operation, the TWS headset 4 may be positioned and placed on the placement portion 301, and the positioning and fixing are maintained on the placement portion 301, so as to perform stable detection.

During detection, the TWS earphone 4 is placed on the earphone jig 3, the pressure button 401 of the TWS earphone 4 is simulated to be manually pressed by the pressure detection component 5, the touch detection component 6 is used for simulating human touch on the touch button 402 of the TWS earphone 4, and the thimble detection component 7 can be used for realizing communication connection between the TWS earphone 4 and the detection external unit so as to read and detect and judge corresponding information.

The pressure detection component 5 is specifically arranged outside the headset jig 3 and is located on one side corresponding to the pressure key 401 of the TWS headset 4 during detection, so as to perform corresponding simulated pressing action on the pressure key 401. In a preferred embodiment, the pressure-sensitive detecting assembly 5 includes a pressure block 51, and the pressure block 51 is disposed outside the earphone fixture 3 and can move close to or away from the earphone fixture 3. The pressing head 511 is disposed on a side of the pressure block 51 facing the headphone fixture 3, and when the TWS headphone 4 is placed on the headphone fixture 3, the pressing head 511 of the pressure block 51 corresponds to the pressure button 401 of the TWS headphone 4. During detection, the pressure block 51 moves close to the TWS headset 4 placed on the headset jig 3, and the pressing head 511 abuts against the pressure button 401 of the TWS headset 4, so as to perform simulated manual pressing on the pressure button 401.

In addition, as shown in fig. 4, the pressure detecting assembly 5 is provided with a pressure block driving member 52. The pressure block driving member 52 can be selected from, but not limited to, an air cylinder or a motor, and the pressure block driving member 52 is in transmission connection with the pressure block 51, and the pressure block 51 can be driven to move closer to or away from the earphone fixture 3 by the action of the pressure block driving member 52.

Further, referring to fig. 1, the pressure detecting assembly 5 is further provided with a pressing buffer 54, and the pressing buffer 54 can be, but not limited to, a rubber block or a spring. During the pressure sensing detection, the pressure plunger 51 moves close to the earphone fixture 3 and pushes the pressure button 401, and the pushing buffer 54 can urge the pressing head 511 of the pressure block 51 to slowly push against the pressure button 401, so as to avoid the impact of a large impact force on the pressure button 401, thereby avoiding affecting the accuracy of the test.

Wherein, according to the orientation of the pressure button 401 when the TWS headset 4 is placed on the headset jig 3, the pressure block 51 may be designed to move closer to the headset jig 3 from the left and right or front and rear sides on the horizontal plane to press the pressure button 401, or to move closer to the headset jig 3 from the top to the bottom to press the pressure button 401. In some preferred embodiments, when the TWS headset 4 is placed on the headset fixture 3, the pressure button 401 faces upward, the pressure block 51 can move toward the headset fixture 3 from top to bottom to press the pressure button 401, and the pressing action on the pressure button 401 is stabilized under the support of the headset fixture 3 holding the TWS headset 4, thereby ensuring the detection stability.

In the preferred embodiment shown, when the TWS headset 4 is placed on the headset fixture 3, the pressure button 401 faces upward, the pressure block driving member 52 is selected as an air cylinder and supported by the pressure detecting support 55 and disposed on the base station base 1, the pressure block 51 is connected to the output end of the pressure block driving member 52, the pressure block 51 is located above the headset fixture 3, and the pressure block driving member 52 is driven to move up and down to approach or leave the headset fixture 3. In the pressure sensing, under the action of the pressure block driving member 52, the pressure block 51 can move downward to approach the pressure button 401 and make the pressing head 511 press against the pressure button 401, or move upward to be away from the pressure button 401.

In some preferred embodiments, as shown in FIG. 4, the pressure block 51 is disposed on a weight support 53 and is drivingly connected to the pressure block drive 52 through the weight support 53. Wherein, the pressure block 51 is movably arranged on the weight bracket 53, the pressing head 511 of the pressure block 51 passes through the weight bracket 53 downwards, and the pressing head 511 is closer to the earphone jig 3 relative to the weight bracket 53, and the pressure block 51 can move up and down freely on the weight bracket 53. The pressure block driving member 52 is in transmission connection with the weight bracket 53, and the weight bracket 53 is driven to move to drive the pressure block 51 to move close to or away from the earphone fixture 3. Specifically, the pressure block 51 can be selected from, but not limited to, a weight, and a shaft of the weight is disposed through the weight bracket 53 and can move up and down freely relative to the weight bracket 53.

When the pressure sensing is performed, under the driving of the pressure block driving part 52, the pressure block 51 moves close to the TWS headset 4 along with the weight bracket 53, and after the pressing head 511 of the pressure block 51 presses the pressure button 401 and the weight bracket 53 continues to descend for a certain distance, the weight bracket 53 releases the support of the pressure block 51 in the vertical direction. At this time, the pressure button 401 is pressed by the self-weight of the pressure block 51. Therefore, the simulated manual pressing acts on the pressure key 401, and the gravity is quite fixed and stable, so that the test result is more accurate and stable.

And in the preferred embodiment specifically shown, the jacking bumpers 54 are positioned below the weight brackets 53. When the pressure block driving element 52 drives the weight bracket 53 to move downwards, so that the pressure block 51 is close to the earphone fixture 3 and abuts against the pressure button 401, the pressing buffer 54 can be firstly contacted with the weight bracket 53 and the descending speed of the weight bracket 53 is reduced, so that the weight bracket 53 can be slowly released to support the pressure block 51, and the pressure block 51 can be slowly pressed against the pressure button 401.

The touch sensing component 6 is specifically arranged outside the headset jig 3 and is located on one side corresponding to the touch key 402 of the TWS headset 4 during detection so as to perform corresponding simulated pressing action on the touch key 402. In a preferred embodiment, the touch sensing assembly 6 comprises a capacitance pen 61, and the capacitance pen 61 is disposed outside the earphone fixture 3 and can move close to or away from the earphone fixture 3. The capacitance pen 61 has a pen point on one side facing the earphone fixture 3, and when the TWS earphone 4 is placed on the earphone fixture 3, the pen point of the capacitance pen 61 corresponds to the touch key 402 of the TWS earphone 4. During detection, the capacitance pen 61 moves close to the TWS headset 4 placed on the headset jig 3, and the pen point is abutted against the touch key 402 of the TWS headset 4, so as to simulate manual touch on the touch key 402.

In addition, as shown in fig. 5, the touch sensing assembly 6 is provided with a capacitive pen driving member 62. The capacitance pen driving member 62 can be selected from but not limited to an air cylinder or a motor, the capacitance pen driving member 62 is disposed on the base station base 1 through a touch detection support 63, and the capacitance pen driving member 62 is in transmission connection with the capacitance pen 61, and the capacitance pen 61 can be driven to move closer to or away from the earphone fixture 3 by the action of the capacitance pen driving member 62.

Wherein the capacitive pen 61 may be designed to move closer to the touch key 402 to the headphone fixture 3 from the left and right or front and rear sides on a horizontal plane, depending on the orientation of the touch key 402 when the TWS headphone 4 is placed on the headphone fixture 3. In the embodiment shown, when the TWS headset 4 is placed on the headset jig 3, the touch keys 402 face forward, the capacitive pen 61 can move back and forth to approach or depart from the TWS headset 4 on the headset jig 3 by the capacitive pen driving member 62, and touch the touch keys 402 on the TWS headset 4 when moving back to approach the TWS headset 4.

The thimble detecting component 7 is specifically disposed at a side close to the rear end of the placing position 301, and the thimble detecting component 7 includes a thimble 71, and the thimble 71 is correspondingly disposed outside the earphone fixture 3 and can move close to or away from the earphone fixture 3. During the detection operation, the thimble 71 can move close to or away from the TWS headset 4 placed on the headset jig 3, and during the detection operation, the thimble is close to the TWS headset 4 to contact the thimble on the TWS headset 4, so as to realize mutual communication connection. In particular, the thimble 71 may be disposed at a height corresponding to the height of the placement position 301, such that the thimble 71 may move directly to the left and right on the horizontal plane to approach or depart from the TWS headset 4, and in the illustrated embodiment, may move to approach the TWS headset 4 from the right to the left and move to depart from the TWS headset 4 from the left to the right.

In a preferred embodiment, as shown in FIGS. 1 and 6, the pin detecting assembly 7 is provided with a pin driving member 72. The pin driving member 72 may be selected from, but not limited to, a motor or a cylinder. The thimble driving unit 72 is connected to the thimble 71 in a transmission manner, and the thimble 71 is driven to move closer to or away from the earphone fixture 3 by the driving of the thimble driving unit 72. Optionally, when the thimble driving member 72 is a telescopic driving member such as an air cylinder, the thimble 71 may be directly connected to the thimble driving member 72, and when the thimble driving member 72 is driven to be telescopic, the thimble 71 may be directly pushed and pulled to move closer to or away from the earphone fixture 3; when the thimble driving member 72 is a rotary driving member such as a motor, the thimble 71 can be connected to the output end of the thimble driving member 72 through a gear or a screw transmission, and can be stably moved close to or away from the earphone fixture 3 under the driving of the thimble driving member 72.

In the illustrated embodiment, the ejector pins 71 are mounted on an ejector pin base 73, and the ejector pin driving member 72 is selected as a cylinder. The thimble driving element 72 is in transmission connection with the thimble base 73, specifically, the thimble 71 is mounted on one end of the thimble base 73 close to the earphone fixture 3, and an output end of the thimble driving element 72 is connected with one end of the thimble base 73 away from the earphone fixture 3. During the detection operation, the thimble driving member 72 moves and drives the thimble base 73 to move left and right by pushing and pulling in the horizontal direction, so as to drive the thimble 71 to move closer to or away from the earphone fixture 3.

In another preferred embodiment, referring to fig. 3, the placement site 301 has a capacitance pen access port 302 and a thimble access port 303. The capacitance pen access port 302 is communicated with the head of the groove of the placement position 301 from the front of the earphone fixture 3, and the thimble access port 303 is communicated with the tail of the groove of the placement position 301, specifically, can be a groove structure integrally formed with the placement position 301.

When the TWS earphone 4 is positioned and placed on the placement position 301 of the earphone jig 3 for detection, the capacitance pen 61 of the touch detection component 6 can move and extend into the placement position 301 from the capacitance pen access port 302 so as to be in contact with the head touch key 402 of the TWS earphone 4 placed on the placement position 301; and the thimble 71 of the thimble detection component 7 can move and extend into the placing position 301 from the thimble access port 302 so as to contact with the tail contact thimble of the TWS earphone 4 placed on the placing position 301. After the ear insertion detection of the TWS headset 4 is completed, the capacitive pen 61 and the thimble 71 move out of the corresponding capacitive pen access port 302 and the thimble access port 303, respectively.

Example two

The TWS headset in-ear detection device of this embodiment is the same as the first embodiment, and further, the TWS headset in-ear detection device of this embodiment is further provided with an upper computer. Specifically, the upper computer can be selected but not limited to a PC upper computer, is internally provided with a control chip and is provided with a display screen.

At least the thimble 71 is connected to the upper computer, and for example, the thimble 71, the capacitance pen driving element 62, the thimble driving element 72, and the pressure block driving element 52 are all connected to the upper computer. The upper computer can send control instructions to the pressure block driving part 52, the capacitance pen driving part 62 and the thimble driving part 72, and can be in communication connection with the TWS earphone 4 through the thimble 71 to read information in the TWS earphone 4 or send instruction information to the TWS earphone 4.

The base station base 1 is provided with a button 2 electrically connected to the upper computer, and the button 2 is provided with a safety device for protecting an operator. When the detection operation is carried out, the button 2 is started, under the control action of the upper computer, the test mode can be entered according to a preset program, the pressure block driving piece 52, the capacitance pen driving piece 62 and the thimble driving piece 72 can execute corresponding action instructions, and the pressure block 51, the capacitance pen 61 and the thimble 71 can move in place to carry out corresponding detection; meanwhile, the upper computer is communicated with and acquires the internal information of the TWS earphone 4 and compares the internal information with the internal information to complete corresponding detection, and a test result is automatically displayed on a display screen. Therefore, a standard automatic detection process is realized, errors of manual detection and judgment are eliminated, the detection efficiency is greatly improved, a large amount of labor cost is saved, and the detection precision is high.

EXAMPLE III

When the TWS headset in-ear detection device of the second embodiment is used for detecting the TWS headset 4, the automatic detection process is as follows:

s1, flatly placing the TWS earphones 4 to be tested in the earphone jig 3 of the detection equipment;

s2, starting a button 2 with a safety device for protecting operators;

s3, the upper computer sends an instruction, the thimble driving piece 72 drives the communication thimble 71 to contact the communication contact thimble on the TWS earphone 4, so that the two are connected and communicated with each other;

s4, the upper computer sends a reset instruction to the TWS earphone 4 through the thimble 71, after the TWS earphone 4 is reset and initialized, the upper computer starts to read the electric quantity of the earphone, the MAC address, the version information of the earphone and the station-crossing detection, if any one of the read information is not in accordance with the preset parameter value of the upper computer, the display is unqualified, and the test mode exits; if the parameter value meets the preset parameter value of the upper computer, the qualified release is displayed, and the next testing step is carried out;

s5, after the last testing step is tested to be qualified, the upper computer sends a testing earphone pressure sensing instruction to drive the pressure block driving piece 52 to run downwards, and the pressure block 51 falls on the pressure button 401 of the TWS earphone 4;

at this time, the top pressure buffer 54 may make the pressure block 51 slowly fall on the pressure button 401 of the TWS headset 4, so as to avoid a large impact force from impacting the pressure button 401 of the TWS headset 4, so as to avoid affecting the accuracy of the test;

the pressure sensor of the TWS earphone 4 detects the gravity of the pressure block 51, a signal is sent to the upper computer through the thimble 71, the upper computer compares the received information with the preset parameter value of the upper computer, any one of the information which is not in accordance with the preset parameter value of the upper computer indicates that the information is unqualified, and the test mode exits; if the preset parameter value of the upper computer is met, the qualified product is displayed, then the pressure block driving part 52 receives the instruction and operates upwards until the initial state is recovered, and the next test item is entered;

s6, sending a headset touch feeling test instruction next to the upper computer, driving the capacitive pen driving piece 62 to enable the capacitive pen 61 to extend out, simulating human body induction to contact the touch control key 402 of the TWS headset 4, enabling stable charges generated by the capacitive pen 62 to act on the capacitive touch sensor of the TWS headset 4, feeding back touch data to the upper computer through the thimble 71 by the touch sensor of the TWS headset 4 for analysis, comparing the received information with the preset parameter value of the upper computer by the upper computer, displaying that the touch data is unqualified if any one of the touch data is inconsistent with the preset parameter value of the upper computer, and exiting the test mode; if the parameter value accords with the preset parameter value of the upper computer, the qualified release is displayed;

the capacitive pen driver 62 then receives the command and moves back, restoring the initial state.

And S7, uploading the data to a designated server through the network whether the test is qualified or not.

After the test is finished, the earphone is manually taken out, placed to the next station, the whole test program is completed, and the next test instruction is waited.

The above embodiments are merely preferred embodiments of the present invention, and are only intended to describe the technical solutions of the present invention in further detail, but the above descriptions are exemplary, not exhaustive, and not limited to the disclosed embodiments, the protection scope and implementation manner of the present invention are not limited thereto, and any changes, combinations, deletions, substitutions or modifications that do not depart from the spirit and principle of the present invention are all included in the protection scope of the present invention.

Claims (12)

1. The TWS earphone pressure and touch sensitivity detection equipment is characterized by comprising an earphone jig, a pressure block, a capacitance pen and a thimble; when the earphone fixture is used, the earphone is placed on the earphone fixture; the pressure block, the capacitance pen and the ejector pin are separately arranged outside the earphone jig and can respectively and independently move close to or away from the earphone jig.

2. The TWS earphone pressure and touch sensitivity detection apparatus of claim 1, wherein the earphone fixture has a placement location thereon on which the earphone is positioned to be placed in use.

3. The TWS earphone pressure and touch sensitivity detection device of claim 2, wherein the placement site has a capacitance pen access port and a thimble access port.

4. The TWS earphone pressure and touch sensitivity detection apparatus of claim 1 wherein a pressure block drive is provided; the pressure block driving piece can drive the pressure block to move close to or far away from the earphone jig.

5. The TWS earphone pressure and touch sensitivity detection apparatus of claim 1, wherein the pressure block is located above the earphone fixture and can move up and down to approach or depart from the earphone fixture.

6. The TWS earphone pressure and touch sensitivity detection device of claim 5, wherein a pressure block driving member is provided, the pressure block being in driving connection with the pressure block driving member through a weight bracket; the pressure block driving part is in transmission connection with the weight support, and the pressure block can be driven to move close to or away from the earphone jig by driving the weight support to move.

7. The TWS earphone pressure and touch sensitivity detecting device according to claim 6, wherein the pressure block is movably mounted on the weight support and has a pressing head which passes downward through the weight support, the pressing head is close to the earphone jig relative to the weight support, and the pressure block can freely move up and down on the weight support.

8. The TWS earphone pressure and tactile sensation sensitivity detection apparatus according to claim 1, wherein a top pressure buffer is provided; when the pressure block moves close to the earphone fixture, the jacking buffer can act to enable the pressure block to slowly approach the earphone fixture.

9. The TWS earphone pressure and touch sensitivity detection apparatus of claim 1 wherein a capacitive pen drive is provided; the capacitance pen driving part is in transmission connection with the capacitance pen and can drive the capacitance pen to move close to or far away from the earphone jig.

10. The TWS earphone pressure and touch sensitivity detection apparatus of claim 1, wherein a thimble drive is provided; the thimble driving piece can drive the thimble to move close to or far away from the earphone jig.

11. The TWS earphone pressure and tactile sensitivity detection apparatus of claim 10, wherein the thimble is mounted on a thimble base, the thimble driver being in driving connection with the thimble base.

12. The TWS earphone pressure and touch sensitivity detection device according to any one of claims 1-11, further comprising an upper computer; at least the thimble with the host computer is connected.

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