CN118776615B - Self-checking device is used in massager production - Google Patents

Abstract

The invention relates to the technical field of adult product quality detection and discloses a self-checking device for massager production, which comprises an installation box, wherein a control module is arranged in the installation box, and a display module is arranged at one end of the back surface of the installation box; this self-checking device is used in massager production through utilizing the vibration of massager main part in-process, strikes the vibration tympanic membrane and makes the inside air current compression flow of drum chamber, and the vibration amplitude of massager main part is less, but the vibration frequency is high, produced instantaneous atmospheric pressure is higher, through the design of piston tube inner structure, realize collecting the alternative of air current, thereby carry out recycle to the kinetic energy that produces when the massager main part vibrates, through the inside multiunit piston plate structural design of piston tube, the inside high-pressure air current's of drum chamber is dredged in turn has been realized, the utilization of the driving force that produces the high-frequency vibration of massager main part has been improved.

Description

Self-checking device is used in massager production

Technical Field

The invention relates to the technical field of adult product quality detection, in particular to a self-checking device for massager production.

Background

In the production process of the existing massager, quality detection is required, the existing massager usually has detection steps of appearance, physical parameters, electrical parameters and the like, the massager usually adopts a vibration mode to massage, and vibration frequency, power consumption performance, wear resistance performance of outer layer materials and the like are important parameters for detection

The existing massager detection device is usually provided with specific detection equipment for detecting the technical parameters, the detection device usually adopts electric power as an energy source for detection, meanwhile, in the detection process of the vibration frequency, the power consumption performance, the wear resistance performance and the like of the massager, the detection period is longer, and in the detection process, the detection device needs to consume a large amount of electric energy, so that a novel massager self-detection device needs to be designed.

Disclosure of Invention

The invention provides a self-checking device for massager production, which solves the technical problems of long detection period and large consumption of electric energy in the detection process of massager detection equipment in the related art.

The invention realizes the above purpose through the following technical scheme:

The utility model provides a massager production is with self-checking device, includes the mounting box, the inside of mounting box is provided with control module, the back one end of mounting box is provided with display module, display module passes through the wire and is connected with control module electricity, the top of mounting box is provided with testing platform, the marginal position department at testing platform top is provided with the protection casing, the both sides of mounting box all are provided with exhaust mechanism;

The front end of the top of the detection platform is provided with a supporting and sliding mechanism, the supporting and sliding mechanism at least comprises a linear sliding rail arranged on the top of the detection platform, the top of the linear sliding rail is provided with a clamping platform, the middle part of the clamping platform is clamped with a massager body, and the linear sliding rail is used for supporting the massager body to slide and displace at the top of the detection platform;

A counter is arranged at the position, close to one side of the clamping platform, of the top of the detection platform and is electrically connected with the control module through a wire, and the counter is used for detecting the sliding displacement times of the massager body;

Vibration detection mechanisms are symmetrically arranged at positions, close to two sides of the massager body, of the top of the detection platform, sound wave detectors are arranged in the two groups of vibration detection mechanisms, the sound wave detectors are used for detecting sound waves generated by the vibration knocking vibration detection mechanisms of the massager body, and the sound wave detectors are electrically connected with the control module through wires;

The vibration detection mechanism at least comprises two groups of drum cavities symmetrically arranged on the outer side of the massager body, one sides of the two groups of drum cavities, which are far away from each other, are provided with gas collection mechanisms, the gas collection mechanisms at least comprise piston pipes which are communicated with the drum cavities, and the piston pipes are used for collecting and amplifying flowing air flows generated by vibration in the drum cavities;

The rear end of the top of the detection platform is provided with a friction detection mechanism, the front end of the friction detection mechanism is symmetrically provided with an upper friction plate and a lower friction plate, and the outer side of the massager body is mutually matched with the inner sides of the upper friction plate and the lower friction plate;

The middle part inside the testing platform is provided with the gas holder, the output of gas holder is provided with the gas shunt, the gas shunt passes through the wire and is connected with the control module electricity, the inside of gas shunt is provided with the air pressure detector that is used for detecting the inside atmospheric pressure of gas holder.

As a further optimization scheme of the invention, the supporting and sliding mechanism further comprises connecting plates arranged on two sides of the clamping platform, the bottoms of the connecting plates penetrate through the detection platform and extend to the inside of the installation box, the bottoms of the two groups of connecting plates are jointly provided with a bottom plate, the inner wall position of the installation box is provided with a telescopic cylinder matched with the bottom plate, the output end of the telescopic cylinder is in bolt fastening connection with the bottom of the bottom plate, and a sliding block is arranged between the bottom of the clamping platform and the top of the linear sliding rail.

As a further optimization scheme of the invention, an electromagnetic valve is arranged at the position, close to the telescopic cylinder, of the inner wall of the installation box, the input end of the electromagnetic valve is communicated with the gas flow divider, the output end of the electromagnetic valve is communicated with the telescopic cylinder, and a displacement long hole matched with the connecting plate is formed in the top of the detection platform.

As a further optimization scheme of the invention, the top of the gas splitter is provided with a liquid storage tank, one side of the liquid storage tank is provided with a pumping unit which is mutually communicated, the input end of the pumping unit is provided with a connecting rod, and the connecting rod and the output end of the telescopic cylinder are positioned on the same longitudinal central line.

As a further optimization scheme of the invention, the output end of the suction unit is provided with a liquid guide pipe, the other end of the liquid guide pipe extends to the top of the detection platform and is communicated with the interior of the upper friction plate, and the bottom of the upper friction plate is uniformly provided with liquid outlet holes communicated with the interior of the upper friction plate.

As a further optimization scheme of the invention, the vibration detection mechanism further comprises a one-way air valve A arranged at the top of the drum cavity, wherein the one-way air valve A is used for supplementing air in the drum cavity, one side of the drum cavity, which is close to the outer side of the massager main body, is provided with a vibration drum membrane, the vibration drum membrane is of an arc-shaped tensioning structure, and the outer side of the vibration drum membrane is mutually attached to the outer side of the massager main body.

As a further optimization scheme of the invention, the gas collection mechanism further comprises a partition plate arranged in the piston tube, a flow control plate is connected to a middle bearing of the partition plate, which is close to one end of the drum cavity, a flow dividing hole is formed in the edge position of the flow control plate, which is close to one end of the drum cavity, a blade is arranged in the middle of the flow control plate, which is close to one end of the drum cavity, a plurality of groups of flow guide holes are uniformly formed in the edge position of the partition plate, and the flow guide holes are matched with the flow dividing holes.

As a further optimization scheme of the invention, a plurality of groups of piston cavities are uniformly arranged in the piston tube at the position of the other end of the partition plate, the piston cavities correspond to the flow guide holes, a piston plate is arranged in the piston cavities, the piston plate slides in the piston cavities, one end of the piston plate is provided with a light spring, one end of the piston tube, far away from the drum cavity, is provided with a sealing plate, and the other end of the light spring is mutually attached to the sealing plate.

As a further optimization scheme of the invention, the outer side of the piston tube is uniformly provided with the one-way air valve C which is mutually communicated with the piston cavity, the output ends of the one-way air valves C are all provided with the bronchus, one end of the sealing plate, which is far away from the piston tube, is provided with the gas collecting tube, the other end of the bronchus is respectively mutually communicated with the gas collecting tube, one end of the back surface of the sealing plate is uniformly provided with the one-way air valve B which is mutually matched with the piston cavity, and the output end of the gas collecting tube penetrates through the detection platform and extends to the inside of the installation box to be mutually communicated with the gas storage tank.

As a further optimization scheme of the invention, one end of the back surface of the installation box is provided with an air inlet mesh screen assembly, the air inlet mesh screen assembly is used for filtering air entering the installation box, the air exhaust mechanism comprises a support frame embedded into the inner wall of the installation box, an impeller set is arranged in the support frame, an air duct is arranged on the outer side of the support frame, the input end of the air duct is communicated with the air splitter, and the output end of the air duct extends to the inner side of the support frame and is matched with the impeller set.

The invention has the beneficial effects that: in the invention, in the process of detecting the main body of the massager, the vibration of the main body of the massager is utilized to knock the vibration drum membrane to enable the air flow in the drum cavity to compress and flow, the vibration amplitude of the main body of the massager is smaller, but the vibration frequency is high, the generated instantaneous air pressure is higher, and the alternate collection of the air flow is realized through the design of the inner structure of the piston tube, so that the kinetic energy generated when the main body of the massager vibrates is recycled;

Through the design of a plurality of groups of piston plates in the piston tube, the alternating dredging of the high-pressure air flow in the drum cavity is realized, and the utilization of the driving force generated by the high-frequency vibration of the massager main body is improved.

Drawings

FIG. 1 is a schematic diagram of the main structure of the present invention;

FIG. 2 is an enlarged schematic view of the structure of the detection platform in the present invention;

FIG. 3 is an enlarged cross-sectional view showing the internal structure of the installation box of the present invention;

FIG. 4 is an enlarged schematic view of the structure of the exhaust mechanism in the present invention;

FIG. 5 is an enlarged schematic view of the connection structure at the friction detection mechanism according to the present invention;

FIG. 6 is an enlarged schematic view of the connection structure at the support slide mechanism in the present invention;

FIG. 7 is an enlarged schematic view of the connection structure of the upper and lower friction plates in the present invention;

FIG. 8 is an enlarged schematic view of the structure of the vibration detecting mechanism according to the present invention;

FIG. 9 is an enlarged cross-sectional view of the structure of the vibration detecting mechanism of the present invention;

FIG. 10 is an enlarged cross-sectional view showing the internal structure of the piston tube according to the present invention;

FIG. 11 is an enlarged cross-sectional view of the connection structure between the piston tube and the flow control plate in the present invention;

FIG. 12 is a cross-sectional view of the structural distribution at the piston chamber in the present invention;

FIG. 13 is a schematic view of the structure of the sealing plate of the present invention from the back.

In the figure: 1. a mounting box; 2. an exhaust mechanism; 201. a support frame; 202. an air duct; 203. an impeller set;

3. a massager body; 4. a detection platform; 5. a counter; 6. a clamping platform; 7. a vibration detection mechanism; 8. a protective cover; 9. a display module; 10. a friction detection mechanism; 11. a linear slide rail; 12. a catheter; 13. a control module; 14. a gas storage tank; 15. a connecting plate; 16. an electromagnetic valve; 17. a slide block; 18. an upper friction plate; 19. a liquid storage tank; 20. a suction unit; 21. a connecting rod; 22. a telescopic cylinder; 23. a bottom plate; 24. a lower friction plate; 25. a gas diverter; 26. a liquid outlet hole;

701. A drum cavity; 702. a one-way air valve A; 703. vibrating the tympanic membrane; 704. a gas collecting tube; 705. bronchi; 706. a piston tube; 707. a blade; 708. a piston chamber; 709. a sealing plate; 710. a light spring; 711. a piston plate; 712. a flow control plate; 713. a deflector aperture; 714. a partition plate; 715. a diversion aperture; 716. a one-way air valve B; 717. a one-way air valve C.

Detailed Description

The subject matter described herein will now be discussed with reference to example embodiments. It is to be understood that these embodiments are merely discussed so that those skilled in the art may better understand and implement the subject matter described herein and that changes may be made in the function and arrangement of the elements discussed without departing from the scope of the disclosure herein. Various examples may omit, replace, or add various procedures or components as desired. In addition, features described with respect to some examples may be combined in other examples as well.

Example 1

As shown in fig. 1 to 13, a self-checking device for producing a massager comprises a mounting box 1, wherein a control module 13 is arranged in the mounting box 1, a display module 9 is arranged at one end of the back surface of the mounting box 1, the display module 9 is electrically connected with the control module 13 through a wire, a detection platform 4 is arranged at the top of the mounting box 1, a protective cover 8 is arranged at the edge position of the top of the detection platform 4, and exhaust mechanisms 2 are arranged at two sides of the mounting box 1;

The front end of the top of the detection platform 4 is provided with a supporting sliding mechanism, the supporting sliding mechanism at least comprises a linear sliding rail 11 arranged at the top of the detection platform 4, the top of the linear sliding rail 11 is provided with a clamping platform 6, the middle part of the clamping platform 6 is clamped with a massager main body 3, the linear sliding rail 11 is used for supporting the massager main body 3 to slide and displace at the top of the detection platform 4, the supporting sliding mechanism also comprises connecting plates 15 arranged at two sides of the clamping platform 6, the bottoms of the connecting plates 15 penetrate through the detection platform 4 and extend to the inside of the installation box 1, the bottoms of the two groups of connecting plates 15 are jointly provided with a bottom plate 23, the inner wall of the installation box 1 is provided with a telescopic cylinder 22 matched with the bottom plate 23, the output end of the telescopic cylinder 22 is in bolt fastening connection with the bottom of the bottom plate 23, a sliding block 17 is arranged between the bottom of the clamping platform 6 and the top of the linear sliding rail 11, the position of the inner wall of the installation box 1 near the telescopic cylinder 22 is provided with an electromagnetic valve 16, the input end of the electromagnetic valve 16 is mutually communicated with a gas diverter 25, the output end of the electromagnetic valve 16 is mutually communicated with the telescopic cylinder 22, the top of the detection platform 4 is provided with a displacement slot hole matched with the connecting plates 15, the top of the gas diverter 25 is mutually matched with the telescopic cylinder 22, the top of the suction box 19 is provided with a suction unit 20, the suction unit 19 is mutually connected with the suction unit 20, and the suction unit is arranged at the same side 20, and is arranged on the side of the suction unit 20;

A counter 5 is arranged at the position, close to one side of the clamping platform 6, of the top of the detection platform 4, the counter 5 is electrically connected with the control module 13 through a wire, and the counter 5 is used for detecting the sliding displacement times of the massager body 3;

The vibration detection mechanisms 7 are symmetrically arranged at positions, close to two sides of the massager body 3, of the top of the detection platform 4, sound wave detectors are arranged in the two groups of vibration detection mechanisms 7 and are used for detecting sound waves generated by the vibration knocking vibration detection mechanisms 7 of the massager body 3, the sound wave detectors are electrically connected with the control module 13 through wires, the vibration detection mechanisms 7 further comprise one-way air valves A702 arranged at the top of the drum cavity 701, the one-way air valves A702 are used for supplementing air in the drum cavity 701, vibration tympanic membranes 703 are arranged on one side, close to the outer side of the massager body 3, of the drum cavity 701, the vibration tympanic membranes 703 are of arc-shaped tensioning structures, and the outer sides of the vibration tympanic membranes 703 are mutually attached to the outer sides of the massager body 3;

The vibration detection mechanism 7 at least comprises two groups of drum cavities 701 symmetrically arranged outside the massager body 3, one sides of the two groups of drum cavities 701 far away from each other are provided with a gas collection mechanism, the gas collection mechanism at least comprises a piston pipe 706 communicated with the drum cavities 701, the piston pipe 706 is used for collecting and amplifying flowing air flow generated by vibration inside the drum cavities 701, the gas collection mechanism also comprises a baffle 714 arranged inside the piston pipe 706, the middle bearing of the baffle 714 near one end of the drum cavities 701 is connected with a flow control plate 712, the edge position of the flow control plate 712 near one end of the drum cavities 701 is provided with a flow dividing hole 715, the middle of the flow control plate 712 near one end of the drum cavities 701 is provided with a blade 707, the edge position of the baffle 714 is uniformly provided with a plurality of flow guide holes 713, the flow guide holes 713 are matched with the flow dividing holes 715, a plurality of groups of piston cavities 708 are uniformly arranged in the piston tube 706 at the position of the other end of the partition 714, the piston cavities 708 correspond to the diversion holes 713, piston plates 711 are arranged in the piston cavities 708, the piston plates 711 slide in the piston cavities 708, one end of each piston plate 711 is provided with a light spring 710, one end of each piston tube 706, which is far away from the drum cavities 701, is provided with a sealing plate 709, the other end of each light spring 710 is mutually attached to the sealing plate 709, the outer side of each piston tube 706 is uniformly provided with a one-way air valve C717 which is mutually communicated with the piston cavities 708, the output ends of the one-way air valves C717 are respectively provided with a branch air tube 705, one end of each sealing plate 709, which is far away from the piston tube 706, is provided with a gas collecting tube 704, the other end of each branch air tube 705 is respectively mutually communicated with the gas collecting tube 704, one-way air valves B716 which are matched with the piston cavities 708 are uniformly arranged at one end of the back of each sealing plate 709, the output end of the gas collecting pipe 704 penetrates through the detection platform 4 and extends to the inside of the installation box 1 to be communicated with the gas storage tank 14;

The rear end of the top of the detection platform 4 is provided with a friction detection mechanism 10, the front end of the friction detection mechanism 10 is symmetrically provided with an upper friction plate 18 and a lower friction plate 24, the outer side of the massager body 3 is mutually matched with the inner sides of the upper friction plate 18 and the lower friction plate 24, the output end of the suction unit 20 is provided with a liquid guide tube 12, the other end of the liquid guide tube 12 extends to the top of the detection platform 4 and is mutually communicated with the inner part of the upper friction plate 18, and the bottom of the upper friction plate 18 is uniformly provided with liquid outlet holes 26 mutually communicated with the inner part of the upper friction plate 18;

the middle part inside the testing platform 4 is provided with gas holder 14, and the output of gas holder 14 is provided with gas shunt 25, and gas shunt 25 passes through the wire and is connected with control module 13 electricity, and the inside of gas shunt 25 is provided with the atmospheric pressure detector that is used for detecting the inside atmospheric pressure of gas holder 14.

The use process of the self-checking device for the massager production provided in the embodiment is as follows, the massager body 3 to be detected is placed on the inner side of the clamping platform 6 for positioning, and the massage end of the massager body 3 is positioned on one side of the two groups of vibration detection mechanisms 7, which are close to each other, so that the massager body 3 is started to vibrate;

In the process of vibrating the massager body 3, the vibrating drum membrane 703 is knocked by the massager body 3 to deform, so that air flow in the drum cavity 701 is compressed, the vibration amplitude of the massager body 3 is small, but the vibration frequency is high, so that the flow speed of the compressed air flow in the drum cavity 701 is high, the compressed air flow in the drum cavity 701 drives the blades 707 to rotate, the blades 707 drive the flow control plate 712 to rotate, at the moment, when the flow distribution hole 715 rotates to be communicated with the flow distribution hole 713, the circulated air flow enters the interior of the piston cavity 708, and the driving force is generated on the piston plate 711 in the piston cavity 708, so that the piston plate 711 compresses the air in the piston cavity 708, drives the air flow in the bronchus 705, and further conveys the air flow to the interior of the air storage tank 14 through the air collection pipe 704 for storage;

In the displacement process of the piston plate 711, the compression light spring 710 contracts to generate a rebound force, the rebound force drives the piston plate 711 to reset, but the displacement of the piston plate 711 and the light spring 710 is a process with a longer period, and the frequency of air compression in the drum cavity 701 generated by knocking the vibration drum membrane 703 by the massager main body 3 is not matched, so that a great amount of kinetic energy is wasted in the air compression process in the drum cavity 701, and further, through the arrangement of a plurality of groups of piston cavities 708 alternately communicated in the interior of the piston pipe 706, the air flow compressed in the drum cavity 701 is sequentially conveyed into different piston cavities 708 through the rotation of the flow control plate 712, so that the functions of piston compression are sequentially and alternately performed in the interiors of the plurality of groups of piston cavities 708, and the utilization of the kinetic energy of the air flow in the drum cavity 701 is improved;

During the process that the massager body 3 knocks the vibration drum 703, sound waves are generated by knocking, collected by the sound wave detector in the vibration drum 703, converted into electric signals and transmitted to the inside of the control module 13 for analysis, and further transmitted to the position of the display module 9 for display by the control module 13;

The air flow conveyed to the inside of the air storage tank 14 is stored, the air flow in the air storage tank 14 is distributed and conveyed along with the increase of the air pressure in the air storage tank 14, the air flow is controlled by the air splitter 25, a part of the air flow is conveyed to the position of the electromagnetic valve 16, the linear sliding rail 11 is driven to operate, the bottom plate 23 is driven to displace through the linear sliding rail 11, the clamping platform 6 connected with the connecting plate 15 is driven to displace, the massager body 3 is driven to reciprocate through the clamping platform 6, the outer sides of the upper friction plate 18 and the lower friction plate 24 are rubbed in the displacing process of the massager body 3, the number of times of the displacement of the massager body 3 is counted through the counter 5, the data is conveyed to the position of the control module 13 for analysis, and the data is conveyed to the position of the display module 9 through the control module 13 for display;

in the displacement process of the bottom plate 23, the output end of the telescopic cylinder 22 pushes the connecting rod 21, so that the connecting rod 21 extrudes the lubricating liquid extracted from the interior of the suction unit 20 into the liquid guide tube 12, and the lubricating liquid is discharged through the liquid outlet hole 26 at the bottom of the upper friction plate 18, so that the massager body 3 is lubricated, and the suction unit 20 is any extraction structure in the prior art and is used for extracting the lubricating liquid in the liquid storage tank 19;

Through the cooperation of the parts, the recovery and the utilization of vibration kinetic energy in the detection process of the massager body 3 are realized, the consumption of electric power is further saved, the energy saving performance of the detection device is improved, meanwhile, the detection mode of the detection device is used for detecting technical parameters of vibration frequency, power consumption performance and wear resistance performance of the massager body 3, and the main body shape of the clamping platform 6 is specially required to be adjusted according to the shape of the massager body 3, so that the detection of the technical parameters of the massager body 3 with different shapes is realized;

furthermore, in the actual detection process, a plurality of groups of detection stations connected in parallel can be arranged at the top of the detection platform 4, so that the detection efficiency of the device is improved.

Example 2

As shown in fig. 1, 3 and 4, a self-checking device for producing a massager is provided, an air inlet mesh screen assembly is arranged at one end of the back surface of a mounting box 1, the air inlet mesh screen assembly is used for filtering air entering the inside of the mounting box 1, an air exhaust mechanism 2 comprises a supporting frame 201 embedded into the inner wall of the mounting box 1, an impeller set 203 is arranged in the supporting frame 201, an air duct 202 is arranged on the outer side of the supporting frame 201, an input end of the air duct 202 is mutually communicated with an air splitter 25, and an output end of the air duct 202 extends to the inner side of the supporting frame 201 and is matched with the impeller set 203.

The use process of the self-checking device for massager production provided in this embodiment is as follows, the air flow inside the air storage tank 14 is controlled and split into the inside of the air guide pipe 202 through the air splitter 25, the air flow discharged from the output end of the air guide pipe 202 blows the impeller set 203 to rotate, and then the air flow inside the installation box 1 circulates to the outside through the rotation of the impeller set 203, and then the air flow outside enters the inside of the installation box 1 through the air inlet mesh screen assembly at one end of the back of the installation box 1, so that the function of cooling the inside of the installation box 1 is realized.

The embodiment has been described above with reference to the embodiment, but the embodiment is not limited to the above-described specific implementation, which is only illustrative and not restrictive, and many forms can be made by those of ordinary skill in the art, given the benefit of this disclosure, are within the scope of this embodiment.

Claims (10)

1. The utility model provides a self-checking device for massager production, includes mounting box (1), the inside of mounting box (1) is provided with control module (13), the back one end of mounting box (1) is provided with display module (9), display module (9) are connected with control module (13) electricity through the wire, the top of mounting box (1) is provided with testing platform (4), the border position department at testing platform (4) top is provided with protection casing (8), the both sides of mounting box (1) all are provided with exhaust mechanism (2), its characterized in that,

The front end of the top of the detection platform (4) is provided with a supporting and sliding mechanism, the supporting and sliding mechanism at least comprises a linear slide rail (11) arranged on the top of the detection platform (4), the top of the linear slide rail (11) is provided with a clamping platform (6), the middle part of the clamping platform (6) is clamped with a massager body (3), and the linear slide rail (11) is used for supporting the massager body (3) to slide and move on the top of the detection platform (4);

a counter (5) is arranged at the position, close to one side of the clamping platform (6), of the top of the detection platform (4), the counter (5) is electrically connected with the control module (13) through a wire, and the counter (5) is used for detecting the sliding displacement times of the massager main body (3);

Vibration detection mechanisms (7) are symmetrically arranged at positions, close to two sides of the massager body (3), of the top of the detection platform (4), sound wave detectors are arranged in the two groups of vibration detection mechanisms (7) and are used for detecting sound waves generated by the vibration knocking vibration detection mechanisms (7) of the massager body (3), and the sound wave detectors are electrically connected with the control module (13) through wires;

the vibration detection mechanism (7) at least comprises two groups of drum cavities (701) symmetrically arranged on the outer side of the massager body (3), one sides of the two groups of drum cavities (701) away from each other are provided with gas collection mechanisms, the gas collection mechanisms at least comprise piston pipes (706) communicated with the drum cavities (701), and the piston pipes (706) are used for collecting and amplifying flowing air flows generated by vibration in the drum cavities (701);

The rear end of the top of the detection platform (4) is provided with a friction detection mechanism (10), the front end of the friction detection mechanism (10) is symmetrically provided with an upper friction plate (18) and a lower friction plate (24), and the outer side of the massager body (3) is mutually matched with the inner sides of the upper friction plate (18) and the lower friction plate (24);

The middle part inside testing platform (4) is provided with gas holder (14), the output of gas holder (14) is provided with gas shunt (25), gas shunt (25) are connected with control module (13) electricity through the wire, the inside of gas shunt (25) is provided with the atmospheric pressure detector that is used for detecting the inside atmospheric pressure of gas holder (14).

2. The self-checking device for massager production according to claim 1, characterized in that the supporting sliding mechanism further comprises connecting plates (15) arranged on two sides of the clamping platform (6), the bottoms of the connecting plates (15) penetrate through the detecting platform (4) and extend to the inside of the installation box (1), a bottom plate (23) is jointly arranged at the bottoms of the two groups of connecting plates (15), a telescopic cylinder (22) matched with the bottom plate (23) is arranged at the position of the inner wall of the installation box (1), the output end of the telescopic cylinder (22) is connected with the bottom of the bottom plate (23) through bolt fastening, and a sliding block (17) is arranged between the bottom of the clamping platform (6) and the top of the linear sliding rail (11).

3. The self-checking device for massager production according to claim 2, characterized in that an electromagnetic valve (16) is arranged at the position, close to the telescopic cylinder (22), of the inner wall of the installation box (1), the input end of the electromagnetic valve (16) is mutually communicated with the gas flow divider (25), the output end of the electromagnetic valve (16) is mutually communicated with the telescopic cylinder (22), and a displacement long hole matched with the connecting plate (15) is formed in the top of the detection platform (4).

4. A self-checking device for producing a massager according to claim 3, characterized in that the top of the gas diverter (25) is provided with a liquid storage tank (19), one side of the liquid storage tank (19) is provided with a pumping unit (20) which is mutually communicated, the input end of the pumping unit (20) is provided with a connecting rod (21), and the output ends of the connecting rod (21) and the telescopic cylinder (22) are positioned on the same longitudinal central line.

5. The self-checking device for massager production according to claim 4, characterized in that the output end of the suction unit (20) is provided with a liquid guide tube (12), the other end of the liquid guide tube (12) extends to the top of the detection platform (4) and is mutually communicated with the interior of the upper friction plate (18), and the bottom of the upper friction plate (18) is uniformly provided with liquid outlet holes (26) mutually communicated with the interior of the upper friction plate.

6. The self-checking device for producing a massager according to claim 1, wherein the vibration detecting mechanism (7) further comprises a one-way air valve a (702) arranged at the top of the drum cavity (701), the one-way air valve a (702) is used for supplementing air in the drum cavity (701), a vibration drum membrane (703) is arranged on one side, close to the outer side of the massager body (3), of the drum cavity (701), the vibration drum membrane (703) is of an arc-shaped tensioning structure, and the outer side of the vibration drum membrane is mutually attached to the outer side of the massager body (3).

7. The self-checking device for massager production according to claim 1, wherein the gas collecting mechanism further comprises a partition plate (714) arranged inside the piston tube (706), a flow control plate (712) is connected to a middle bearing of the partition plate (714) close to one end of the drum cavity (701), a flow dividing hole (715) is formed in the edge position of the flow control plate (712) close to one end of the drum cavity (701), a blade (707) is arranged in the middle of the flow control plate (712) close to one end of the drum cavity (701), a plurality of groups of flow guide holes (713) are uniformly formed in the edge position of the partition plate (714), and the flow guide holes (713) are matched with the flow dividing holes (715).

8. The self-checking device for producing a massager according to claim 7, wherein a plurality of groups of piston cavities (708) are uniformly arranged in the piston tube (706) at the position of the other end of the partition plate (714), the piston cavities (708) correspond to the diversion holes (713), piston plates (711) are arranged in the piston cavities (708), the piston plates (711) slide in the piston cavities (708), one ends of the piston plates (711) are provided with light springs (710), one ends of the piston tubes (706) away from the drum cavities (701) are provided with sealing plates (709), and the other ends of the light springs (710) are mutually attached to the sealing plates (709).

9. The self-checking device for producing a massager according to claim 8, wherein the outer side of the piston tube (706) is uniformly provided with a one-way air valve C (717) which is mutually communicated with the piston cavity (708), the output ends of the one-way air valves C (717) are all provided with a gas collecting tube (704), one end of the sealing plate (709), which is far away from the piston tube (706), is provided with a gas collecting tube (704), the other end of the gas collecting tube (705) is respectively mutually communicated with the gas collecting tube (704), one end of the back surface of the sealing plate (709) is uniformly provided with a one-way air valve B (716) which is matched with the piston cavity (708), and the output end of the gas collecting tube (704) penetrates through the detection platform (4) and extends to the inside of the installation box (1) to be mutually communicated with the gas storage tank (14).

10. The self-checking device for massager production according to claim 1, wherein an air inlet mesh screen assembly is arranged at one end of the back surface of the installation box (1), the air inlet mesh screen assembly is used for filtering air entering the installation box (1), the air exhaust mechanism (2) comprises a supporting frame (201) embedded into the inner wall of the installation box (1), an impeller set (203) is arranged in the supporting frame (201), an air duct (202) is arranged on the outer side of the supporting frame (201), an input end of the air duct (202) is mutually communicated with the air splitter (25), and an output end of the air duct (202) extends to the inner side of the supporting frame (201) and is matched with the impeller set (203).