CN113418729A - Simulation device for cupping device negative pressure detection and application method - Google Patents

Abstract

The invention belongs to the field of intelligent manufacturing of cupping devices, and provides simulation equipment for cupping device negative pressure detection, which comprises: the detection platform is provided with at least one detection part; the invention provides a simulation device for cupping device negative pressure detection and an application method thereof, wherein the simulation device can simulate real human skin to perform cupping detection, detection contents comprise temperature, pressure, impedance and negative pressure, the temperature value reflects skin temperature, the pressure value reflects skin touch, the impedance value reflects skin adsorption and rising degree, the negative pressure value reflects cupping strength, and the comprehensive capability of cupping device production quality inspection is improved.

Description

Simulation device for cupping device negative pressure detection and application method

Technical Field

The invention relates to the field of intelligent manufacturing of cupping devices, in particular to simulation equipment for cupping device negative pressure detection and an application method.

Background

The mechanism of the cupping device is discovered through the vacuum negative pressure effect and the research of scholars at home and abroad: human body is when jar negative pressure is inhaled and is pulled out, and there is a large amount of bubbles on the skin surface to spill over to strengthen local tissue's gas exchange, through the inspection, also observe: the negative pressure causes the permeability change of local capillary vessels and the rupture of the capillary vessels, a small amount of blood enters the tissue gaps, so as to generate blood stasis, red blood cells are damaged, hemoglobin is released, the phenomenon of home hemolysis occurs, the self-regulation of the organism has the effects of promoting qi and blood circulation, relaxing tendons and activating collaterals, relieving swelling and pain, dispelling wind and removing dampness and the like, and the negative pressure plays a role in stimulating the health and promoting the recovery of normal functions.

The cupping glass is a folk name for cupping glass therapy, is also called a cupping glass tube or a suction cup, is a treatment method for removing air in the cupping glass by using heat and adsorbing the air on skin by using negative pressure to cause blood stasis, and has the functions of heating to simulate the cupping glass effect, regulating yin and yang balance, eliminating fatigue, strengthening physique and the like.

Design of multi-effect cupping device, production, use need to hold layer upon layer, especially, production quality control, can direct influence user's use experience, if product negative pressure gear, heating gear design is unreasonable, not only can influence the product public praise, also can cause bodily injury to the user, in addition, traditional multi-effect cupping device directly regards as the switching standard of function gear with arbitrary intensity difference, lack objective standard of judging, it is very inconvenient to make the user adjust the setting to the cupping device, this has influenced the cup and has experienced, lack reasonable detection feedback equipment and method.

SUMMARY OF THE PATENT FOR INVENTION

Aiming at the defects in the prior art, the invention provides simulation equipment for cupping device negative pressure detection and an application method thereof, and solves the problems that the detection of a multi-effect cupping device is not comprehensive and the gear design of the multi-effect cupping device is not reasonable.

The simulation device for cupping device negative pressure detection provided by the embodiment of the invention comprises:

the detection platform is provided with at least one detection part;

a test system disposed in the detection part to sense performance of the cupping device;

the processing module is arranged on the operating table;

the display module is controlled by the processing module to display the pressure, temperature, negative pressure and impedance values of the cupping; and

and the power supply module provides operating power for the test system, the processing module and the power supply module.

Further, the detection part comprises an insulating layer, a conducting layer and a body sensing layer, wherein the conducting layer is wrapped between the insulating layer and the body sensing layer.

Furthermore, the test system comprises a temperature sensing unit, a pressure sensing unit, an impedance sensing unit and at least one negative pressure sensing unit, wherein the temperature sensing unit and the pressure sensing unit are wrapped inside the somatosensory layer.

Further, the detection part is provided with at least one through hole, wherein the negative pressure sensing unit is arranged in the operation table and is communicated with the through hole through a negative pressure pipe.

Further, the temperature sensing unit comprises a first detection module and at least one thermistor, and the thermistor is electrically connected with the first detection module.

Further, the pressure sensing unit comprises a second detection module and at least one piezoresistor, and the piezoresistor is electrically connected with the second detection module.

Furthermore, the impedance sensing unit comprises a positive electrode, a negative electrode and a third detection module, a closed loop is formed by the positive electrode, the negative electrode and the conducting layer, and the third detection module is electrically connected with the conducting layer loop.

Further, insulating layer, body feel the layer and be flexible insulating material, the conducting layer is flexible electrically conductive material.

An application method of simulation equipment for cupping device negative pressure detection comprises the following operation steps:

the method comprises the following steps: placing the cupping device on the back of a person to be tested, opening the cupping device to a gear to be tested, and recording the somatosensory reaction of the dictation of the person to be tested after the cupping device is stabilized;

step two: connecting the simulation equipment with electricity, placing the cupping device on the detection part of the operating table, starting the cupping device to the gear adjusted in the step one, and observing and recording the pressure, temperature, negative pressure and impedance values displayed by the display module after the negative pressure of the cupping device is stable;

step three: matching the numerical values obtained in the step two with the somatosensory reaction of the dictation of the person to be detected, and establishing a database of detection numerical values corresponding to different somatosensory reactions;

step four: and applying the design of the cupping devices of the same type according to the pressure, temperature, negative pressure and impedance values corresponding to different somatosensory reactions in the detection database.

According to the technical scheme, the beneficial effects of the invention are as follows:

1. the simulation device for the negative pressure detection of the cupping device and the application method thereof can simulate real human skin to carry out cupping detection, and the detection content comprises temperature, pressure, impedance and negative pressure, wherein the temperature value reflects skin temperature, the pressure value reflects skin touch, the impedance value reflects the adsorption and rising degree of the skin, and the negative pressure value reflects the cupping strength, so that the comprehensive production quality detection capability of the cupping device is improved, the detection range is wide, and the quality detection requirement of a multifunctional cupping device is met.

2. According to the simulation device and the application method for cupping device negative pressure detection, provided by the invention, by matching the simulation numerical value with the real human body feeling, a database of detection numerical values corresponding to different body feeling reactions can be quickly established, the gear setting requirements of the similar cupping devices can be obtained by means of big data, the cupping experience of users can be improved, and the application range is wide.

Drawings

In order to more clearly illustrate the patentable embodiments of the invention, reference will now be made to the appended drawings, which are briefly described as embodiments or as required in the prior art description. In all the drawings, the elements or parts are not necessarily drawn to actual scale.

FIG. 1 is an external view of a preferred embodiment of the simulation apparatus for cupping device negative pressure detection and the application method thereof provided by the present invention;

FIG. 2 is a cutaway view of a preferred embodiment of the simulation device for cupping device negative pressure detection and the application method provided by the invention;

FIG. 3 is a block control diagram of a preferred embodiment of the simulation apparatus for cupping device negative pressure detection and the application method provided by the present invention;

FIG. 4 is a circuit diagram of a preferred embodiment of the simulation apparatus for cupping device negative pressure detection and the application method thereof provided by the present invention;

FIG. 5 is a schematic diagram illustrating a first simulation apparatus for cupping device negative pressure detection and a first application method according to a preferred embodiment of the present invention;

fig. 6 is a schematic diagram of a simulation device for cupping device negative pressure detection and an application method according to a preferred embodiment of the invention.

Reference numerals: the device comprises an operation table 1, a detection part 11, an insulating layer 111, a conductive layer 112, a body sensing layer 113, a test system 2, a temperature sensing unit 21, a first detection module 211, a thermistor 212, a pressure sensing unit 22, a piezoresistor 221, a second detection module 222, an impedance sensing unit 23, a positive electrode 231, a negative electrode 232, a third detection module 233, a negative pressure sensing unit 24, a negative pressure tube 241, a processing module 3, a display module 4 and a power supply module 5.

Detailed Description

Embodiments of the patented technology of the present invention will be described in detail below with reference to the drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and therefore are only used as examples, and the protection scope of the present invention is not limited thereby.

Example (b): as shown in fig. 1 to 6, the simulation apparatus for cupping negative pressure detection provided in this embodiment includes: an operation table 1, on which at least one detection part 11 is arranged; a test system 2, the test system 2 being provided in the detection section 11 to sense performance of the cupping device; the processing module 3 is arranged on the operating platform 1; the display module 4 is controlled by the processing module 3 to display the pressure, temperature, negative pressure and impedance values of the cupping; and a power supply module 5, wherein the power supply module 5 provides the running power of the test system 2, the processing module 3 and the power supply module 5.

Specifically, the operating table 1 is in a frustum shape, a square shape or a round shape, and the upper side of the operating table is provided with the detection part 11, so that the cupping device is easy to be horizontally placed; the processing module 3 is any one of a PCB (printed circuit board), a PLC (programmable logic controller) or a control chip, is fixed in the front side of the operating platform 1 by screws and can intelligently and integrally set the test system 2 and the display module 4 to operate; the display module 4 is any one of an electronic display screen or an indicator light set, optionally, when the display module 4 is set as the indicator light set, different rows of indicator lights are respectively used for prompting temperature, pressure, negative pressure and impedance, the light quantity of the same row of indicator lights respectively corresponds to different test intensities, it is worth mentioning that the display module 4 is pressed between the processing module 3 and a notch on the front side of the operation table 1, and the notch is arranged on an inclined plane on the front side of the operation table 1, so that the display module 4 can be over against an operator, and observation is convenient; the power supply module 5 is a charging socket, plays a role in supplying power, and preferably, the charging socket is electrically connected with a lithium battery, so that the negative pressure detection simulation equipment can move and operate.

Furthermore, the detection part 11 comprises an insulating layer 111, a conductive layer 112 and a body-sensing layer 113, wherein the conductive layer 112 is covered between the insulating layer 111 and the motion sensing layer 113, specifically, the insulating layer 111, the conductive layer 112 and the motion sensing layer 113 are sequentially bonded by one of glue bonding or hot melt bonding, the detection part 11 which is composed of the insulating layer 111, the conductive layer 112 and the body feeling layer 113 is a whole, the flexibility is good, thus, the conductive layer 112 will not generate the leakage, and it is worth mentioning that the upper side of the console 1 is detachably connected with the pressing ring, the pressing ring is internally provided with a step groove in a shape like a Chinese character 'tu', so that the detecting part 11 can be clamped and fixed by the pressing ring and the console 1, the detection part 11 can be tightly attached to the top wall of the operating platform 1, the looseness is not easy to occur, and the pressing ring and the operating platform 1 can be in any form of interference clamping or screw fixation.

Further, the testing system 2 includes a temperature sensing unit 21, a pressure sensing unit 22, an impedance sensing unit 23, and at least one negative pressure sensing unit 24, wherein the temperature sensing unit 21 and the pressure sensing unit 22 are wrapped inside the body sensing layer 113, specifically, the body sensing layer 113 covers the upper side of the conductive layer 112 and directly contacts with the cupping mouth, the thickness of the body sensing layer 113 is not greater than 0.8cm, the sensitivity of elements in the body sensing layer 113 is ensured, and it is worth mentioning that the processing mode of the body sensing layer 113 is as follows: the temperature sensing unit 21 and the pressure sensing unit 22 are filled in the mold by hot-melt silica gel liquid, the temperature sensing unit 21 and the pressure sensing unit 22 are not in contact, electric connection ends of the temperature sensing unit and the pressure sensing unit extend to the outer side of the mold, and the temperature sensing unit and the pressure sensing unit are manufactured and molded through cooling.

Further, the detecting portion 11 is provided with at least one through hole, wherein the negative pressure sensing unit 24 is disposed in the operation table 1, and the negative pressure sensing unit 24 is communicated with the through hole through a negative pressure tube 241, specifically, the negative pressure sensing unit 24 is an air pressure sensor, the negative pressure tube 241 transmits the negative pressure state of the cupping opening to the negative pressure sensing unit 24, so as to clearly reflect the negative pressure capability of the cupping device, and it is worth mentioning that the air pressure sensor also adopts a structural form of combining a pressure sensitive unit and a voltmeter, and the application does not limit the specific model of the air pressure sensor.

Further, the temperature sensing unit 21 includes a first detection module 211 and at least one thermistor 212, the thermistor 212 is electrically connected to the first detection module 211, specifically, the first detection module 211 is any one of a voltmeter and an ammeter, and the detection principle thereof is as follows: the thermistor 212 is influenced by the heating effect of the cupping device to increase the temperature, so that the internal resistance of the thermistor is changed, and the voltage value or the current value of the thermistor 212 is measured in real time through the first detection module 211, so that the simulated temperature environment information of the detection part 11 can be reflected, and the heating condition of the skin can be truly reflected.

Further, the pressure sensing unit 22 includes a second detection module 222 and at least one pressure sensitive resistor 221, the pressure sensitive resistor 221 is electrically connected to the second detection module 222, specifically, the second detection module 222 is any one of a voltmeter and an ammeter, and the detection principle thereof is as follows: the piezoresistor 221 is influenced by the heating effect of the cupping device to increase the temperature, so that the internal resistance of the piezoresistor 221 is changed, the voltage value or the current value of the thermistor 212 is measured in real time through the second detection module 222, the pressure environment information simulated by the detection part 11 can be reflected, the skin compression condition is truly reflected, it is worth mentioning that the piezoresistor 221 is annularly arranged in the peripheral range of the thermistor 212, the formed annular structure is basically matched with the pipe orifice structure of the cupping device to reflect the contact pressure and avoid damage to the skin of a human body, preferably, the piezoresistor 221 is designed in a multi-ring structure, so that the piezoresistor 221 can be adapted to pipe orifice structures of the cupping devices of different models, during detection, the piezoresistor 221 with the maximum pressure is used as output information, it is worth mentioning that an identification ring is further arranged on the upper side of the detection part 11, the alignment detection is convenient, and the detection position deviation can be avoided.

Further, the impedance sensing unit 23 includes a positive electrode 231, a negative electrode 232 and a third detecting module 233, a closed loop is formed among the positive electrode 231, the negative electrode 232 and the conductive layer 112, and the third detecting module 233 is electrically connected to the conductive layer 112 loop, specifically, the positive electrode 231 and the negative electrode 232 are respectively disposed on two sides of the conductive layer 112 in an exposed manner, main bodies of the positive electrode 231 and the negative electrode 232 are thermally sealed at an edge of the detecting portion 11, the softness of the detecting portion 11 is close to the softness of the skin of the human body, when the conductive layer 112 is deformed by the negative pressure of the cupping device, the resistance of the conductive layer 112 is changed, the higher the deformation degree is, the longer the pulling path is, the resistance of the conductive layer 112 is increased, the third detecting module 233 is any one of a voltmeter or an ammeter, and the voltage value or the current value of the conductive layer 112 is measured in real time by the third detecting module 233, the simulated skin deformation characteristics of the detection section 11 can be reflected, so that simulation can be realized, and the degree of skin doming can be reflected in a real manner.

Further, insulating layer 111, body sense layer 113 are flexible insulating material, conducting layer 112 is flexible electrically conductive material, and wherein insulating layer 111, body sense layer 113 can be made for insulating silica gel material, and conducting layer 112 can be made for electrically conductive silica gel material, and is optional, and conducting layer 112 also can be made for gel material for detection portion 11 possesses good pliability characteristics, can simulate skin reaction when the negative pressure attracts.

The working principle is as follows: an application method of simulation equipment for cupping device negative pressure detection comprises the following operation steps:

the method comprises the following steps: placing the cupping device on the back of a person to be tested, opening the cupping device to a gear to be tested, and recording the somatosensory reaction of the dictation of the person to be tested after the cupping device is stable, wherein the person to be tested selects according to the population targeted by the product, the test group is not less than 20 persons, the more test objects are, the better test objects are, and the somatosensory reaction of the dictation of the person to be tested comprises heat, pain, suction, comfort degree before and after cupping and the like;

step two: electrifying the simulation equipment, placing the cupping device on the detection part 11 of the operating table 1, starting the cupping device to the gear adjusted in the step one, observing and recording the pressure, temperature, negative pressure and impedance values displayed by the display module 4 after the negative pressure of the cupping device is stable, wherein the pressure, temperature, negative pressure and impedance directly influence the heat, pain and suction of a user and the comfort before and after cupping;

step three: matching the values obtained in the step two with the somatosensory reaction of the dictation of the person to be detected, and establishing a database of detection values corresponding to different somatosensory reactions, wherein in general, after the pressure, temperature, negative pressure or impedance reaches a certain peak value, adverse effects can be caused to the user, and the application effect is gradually reduced below the peak value, so that the cupping experience of the user corresponds to the test value, and a reasonable gear setting range can be quickly screened out;

step four: according to the pressure, temperature, negative pressure and impedance values corresponding to different somatosensory reactions in the detection database, the design of the similar cupping device is applied, and experience curves are respectively established between the somatosensory reactions of different degrees and the pressure, temperature, negative pressure or impedance, for example: the temperature sensing experience takes noninductive, slightly hot, hotter, warm, hot and overheated grades as a Y axis, and different temperature values are set as an X axis, so that the temperature values corresponding to the Y axis coordinate of the slightly hot oral sensing body can be displayed, a personal body sensing coordinate curve is established by analogy in sequence, body sensing curves of different testers are obtained by analogy, the slightly hot body sensing ranges of different body sensing curves are compared, the average temperature value is taken as a slightly hot gear to be set, the gear switching process of the cupping device is simplified, and the use requirements of most people can be met.

In the description of the present patent application, numerous specific details are set forth. However, it is understood that embodiments of the invention may be practiced without these specific details. In some instances, well-known methods, structures and techniques have not been shown in detail in order not to obscure an understanding of this description.

In the description herein, reference to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present patent. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

The above examples are only used to illustrate the technical solutions of the present invention, but not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art will understand that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; the modifications or substitutions do not make the essence of the corresponding technical solution depart from the scope of the technical solutions of the embodiments of the patent of the present invention, and the technical solutions are all covered in the claims and the specification of the patent of the present invention.

Claims (10)

1. The utility model provides a simulation equipment that cupping device negative pressure detected which characterized in that includes:

the detection platform is provided with at least one detection part; and

a test system disposed within the detection section to sense performance of the cupping device.

2. The simulation device for cupping negative pressure detection of claim 1, wherein the detection part comprises an insulating layer, a conductive layer and a body sensing layer, wherein the conductive layer is coated between the insulating layer and the body sensing layer.

3. The simulation device for negative pressure detection of the cupping device as claimed in claim 2, wherein the testing system comprises a temperature sensing unit, a pressure sensing unit, an impedance sensing unit and at least one negative pressure sensing unit, wherein the temperature sensing unit and the pressure sensing unit are wrapped inside the somatosensory layer.

4. The simulation device for cupping negative pressure detection of claim 3, wherein: the detection part is provided with at least one through hole, wherein the negative pressure sensing unit is arranged in the operation table and is communicated with the through hole through a negative pressure pipe.

5. The simulation device for cupping negative pressure detection of claim 4, wherein: the temperature sensing unit comprises a first detection module and at least one thermistor, and the thermistor is electrically connected with the first detection module.

6. The simulation device for cupping negative pressure detection of claim 5, wherein: the pressure sensing unit comprises a second detection module and at least one piezoresistor, the piezoresistor is electrically connected with the second detection module, and the planar arrangement distance of the piezoresistor is smaller than 1 cm.

7. The simulation device for cupping negative pressure detection of claim 6, wherein: the impedance sensing unit comprises a positive electrode, a negative electrode and a third detection module, a closed loop is formed by the positive electrode, the negative electrode and the conducting layer, and the third detection module is electrically connected with the conducting layer loop.

8. The simulation device for cupping negative pressure detection of claim 7, wherein: the insulating layer, the body sense layer are flexible insulating materials, and the conducting layer is flexible conducting materials.

9. The simulation apparatus for cupping negative pressure detection of claim 8, further comprising:

the processing module is arranged on the operating table;

the display module is controlled by the processing module to display the pressure, temperature, negative pressure and impedance values of the cupping;

and the power supply module provides operating power for the test system, the processing module and the power supply module.

10. The application method of the simulation device for cupping device negative pressure detection as claimed in claim 9, characterized by comprising the following operation steps:

the method comprises the following steps: placing the cupping device on the back of a person to be tested, opening the cupping device to a gear to be tested, and recording the somatosensory reaction of the dictation of the person to be tested after the cupping device is stabilized;

step two: connecting the simulation equipment with electricity, placing the cupping device on the detection part of the operating table, starting the cupping device to the gear adjusted in the step one, and observing and recording the pressure, temperature, negative pressure and impedance values displayed by the display module after the negative pressure of the cupping device is stable;

step three: matching the numerical values obtained in the step two with the somatosensory reaction of the dictation of the person to be detected, and establishing a database of detection numerical values corresponding to different somatosensory reactions;

step four: and applying the design of the cupping devices of the same type according to the pressure, temperature, negative pressure and impedance values corresponding to different somatosensory reactions in the detection database.

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