CN210904661U - Ear acupoint stimulation device and system - Google Patents

Abstract

The application provides an ear acupuncture point stimulation device and system, the device includes: an ear model provided with at least one acupoint; at least one acupoint paster which is arranged on the acupoint of the ear model and is used for stimulating the acupoint of the ear model; the singlechip is used for controlling the level state of at least one output pin according to the received trigger signal; the switch module is used for controlling the working state of the acupuncture point patch according to the level state of at least one output pin of the singlechip; a power supply for supplying power; the at least one acupoint patch corresponds to the at least one switch module one by one; one end of each switch module in the at least one switch module is connected with the power supply through the corresponding acupuncture point patch, and the other end of each switch module is connected with an output pin of the single chip microcomputer; the power supply is also connected with the singlechip.

Description

Ear acupoint stimulation device and system

Technical Field

The application relates to the field of electronic instruments, in particular to an ear acupoint stimulation device and system.

Background

At present, the conventional ear acupoint stimulation device generally pastes an acupoint stimulation patch on the skin of an ear of a user, then a power supply supplies power to the acupoint stimulation patch so as to stimulate the acupoint, but when the ear acupoint stimulation device fails, for example, when electricity leaks, the mode that the acupoint patch is directly pasted on the skin has great potential safety hazard.

SUMMERY OF THE UTILITY MODEL

An object of the embodiments of the present application is to provide an ear acupoint stimulation device and system, so as to solve the problem of insecurity caused by the direct attachment of the existing acupoint stimulation patch of the acupoint stimulation device to the skin of a user.

In order to achieve the above purpose, the present application provides the following technical solutions:

in a first aspect: the application provides an ear acupoint stimulation device, the device includes: an ear model provided with at least one acupoint; at least one acupoint patch arranged on the acupoint of the ear model for stimulating the acupoint of the ear model; the singlechip is used for controlling the level state of at least one output pin according to the received trigger signal; the switch module is used for controlling the working state of the acupuncture point patch according to the level state of at least one output pin of the singlechip; a power supply for supplying power; the at least one acupoint patch corresponds to the at least one switch module one by one; one end of each switch module in the at least one switch module is connected with a power supply through a corresponding acupuncture point patch, and the other end of each switch module is connected with an output pin of the single chip microcomputer; the power supply is also connected with the singlechip.

The ear acupoint stimulation device of the design is characterized in that the ear model is provided with the acupuncture points, and the acupuncture point patches for stimulation are arranged on the acupuncture points, so that the acupuncture point stimulation can be completed after a user wears the ear model. When the ear acupoint stimulation device fails, such as electric leakage, the ear model can be used as a large resistor to ensure the safety of a user, and the problem of insecurity caused by the fact that an acupoint patch in the ear acupoint stimulation device is directly attached to the skin of the user in the prior art is solved.

In an optional implementation manner of the first aspect, at least one output pin of the single chip microcomputer corresponds to the at least one switch module one to one; each output pin in at least one output pin of the singlechip is connected with the power supply through the corresponding switch module and the acupuncture point patch in sequence.

The ear acupuncture point stimulation device of above-mentioned design, the level state according to a plurality of output pin of received trigger signal control comes the on off state of a plurality of switch module of control and a plurality of output pin correspondence connection through the singlechip, and then the operating condition of the acupuncture point paster of control and each switch module connection, the problem that does not have the pertinence that current acupuncture point stimulation device can't stimulate the existence to the acupuncture point according to user's specific demand selectivity has been solved, make the user can carry out the selectivity stimulation to the acupuncture point, realize doctor or user's acupuncture point stimulation scheme, reach the amazing effect of pertinence.

In an optional implementation manner of the first aspect, the switch module includes a PNP triode and a first base resistor, an emitter of the PNP triode is connected to the corresponding acupuncture point patch, a collector of the PNP triode is grounded, and a base of the PNP triode is connected to the output pin of the single chip microcomputer through the first base resistor.

In an optional implementation manner of the first aspect, the switch module includes an NPN triode and a second base resistor, a collector of the NPN triode is connected to the corresponding acupoint patch, an emitter of the NPN triode is grounded, and a base of the NPN triode is connected to an output pin of the single chip microcomputer through the second base resistor.

In the two embodiments, the PNP triode or the NPN triode is used as the switch module, so that the switch circuit can be switched on and off according to the level state output by the output pin of the single chip, and the triode has the advantages of long service life, safety, reliability, high switching speed and the like.

In an optional implementation manner of the first aspect, the apparatus further includes a wireless receiving module configured to receive a wireless signal and convert the wireless signal into the trigger signal, where the wireless receiving module includes an antenna, a signal amplifier, a demodulator, and an analog-to-digital converter, the antenna, the signal amplifier, the demodulator, and the analog-to-digital converter are sequentially connected, and the analog-to-digital converter is connected to an input pin of the single chip microcomputer.

In the above embodiment, the wireless receiving module can receive the wireless signal transmitted from the outside of the ear acupoint stimulation device, and then the wireless signal is converted into the trigger signal to be input to the single chip microcomputer, so that the single chip microcomputer can complete the process of controlling the acupoint stimulation in a subsequent selection mode.

In an optional implementation manner of the first aspect, the wireless receiving module further includes a filter, and the antenna is connected to the signal amplifier through the filter.

In the above embodiment, the filter is used to filter noise and partial interference from the received wireless signal, so that the filtered signal can be more effectively amplified, demodulated and converted.

In an alternative embodiment of the first aspect, the acupoint patches comprise electrode pads and patches connected with each other, the patches are attached to the acupoints of the ear models, and the electrode pads are connected with the corresponding switch modules.

In the above embodiment, the electrode plate stimulates the acupuncture points after the switch module is switched on, and simultaneously stimulates the plaster in the medicinal patch to act on the acupuncture points, so that the stimulation on the acupuncture points is not only targeted but also more effective.

In an alternative embodiment of the first aspect, the electrode pads are connected to the patch by an adhesive member.

In the above embodiment, the electrode sheet and the patch are adhered by the adhesive member, so that the electrode sheet and the patch are more firmly fixed.

In an alternative embodiment of the first aspect, the ear model is a 3D printed ear model.

In the embodiment, the simulated ears are printed out through 3D, so that the ear models can be directly generated from computer graphic data without machining or any die, the ear models generated through 3D printing are the same models which are manufactured according to the individuation of the ears of the patients, and thus, the ear models can be well matched with all acupuncture points of the patients, so that the effect of effective stimulation is achieved, meanwhile, the development cycle of the ear models is greatly shortened, the production rate of the ear models is improved, and the production cost is reduced.

In an optional implementation manner of the first aspect, the single chip microcomputer is of a type AT89S 51.

In a second aspect: the present application provides an ear acupoint stimulation system comprising an ear acupoint stimulation device as described in any one of the alternative embodiments of the first aspect.

According to the ear acupoint stimulation system, the acupoints are arranged on the ear model, and the acupoint patches for stimulation are arranged on the acupoints, so that acupoint stimulation can be completed after a user wears the ear model. When the ear acupoint stimulation device fails, such as electric leakage, the ear model can be used as a large resistor to ensure the safety of a user, and the problem of insecurity caused by the fact that an acupoint patch in the ear acupoint stimulation device is directly attached to the skin of the user in the prior art is solved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments of the present application will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and that those skilled in the art can also obtain other related drawings based on the drawings without inventive efforts.

Fig. 1 is a first structural diagram of an ear acupoint stimulation device according to a first embodiment of the present application;

fig. 2 is a second structural diagram of an ear acupoint stimulation device according to a first embodiment of the present application;

fig. 3 is a schematic diagram of a third structure of an ear acupoint stimulation device according to a first embodiment of the present application;

fig. 4 is a fourth structural diagram of an ear acupoint stimulation device according to a first embodiment of the present application;

fig. 5 is a fifth structural diagram of an ear acupoint stimulation device according to a first embodiment of the present application.

Icon: ear model-10; acupoint-101; acupoint paster-30; a first acupoint patch-301; a second acupoint patch-302; a third acupoint patch-303; a singlechip-40; a first output pin-a 1; a second output pin-a 2; a third output pin-a 3; a first input pin-b 1; a second input pin-b 2; a switch module-50; a first switching module-501; a first PNP transistor 5101; a first resistance-R1; a first NPN transistor-5201; a fourth resistor-R4; a second switching module-502; a second PNP transistor 5102; a second resistance-R2; a second NPN transistor-5202; a fifth resistor-R5; a third switching module-503; a third PNP transistor 5103; a third resistor-R3; a third NPN transistor-5203; a sixth resistor-R6; power supply-60; a wireless receiving module-70; an antenna-701; a signal amplifier-702; a demodulator-703; analog-to-digital converter-704; filter-705.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application.

First embodiment

An embodiment of the present application provides an ear acupoint stimulation device, as shown in fig. 1, including: an ear model 10 provided with at least one acupoint 101; at least one acupuncture point patch 30 disposed on acupuncture points 101 of the ear model 10 for stimulating the acupuncture points of the ear model 10; the singlechip 40 is used for controlling the level state of at least one output pin according to the received trigger signal; at least one switch module 50 for controlling the working state of at least one acupoint patch 30 according to the level state of at least one output pin of the singlechip 40; a power supply 60 for supplying power; the at least one acupoint patch 30 corresponds to the at least one switch module 50 one by one; one end of each switch module 50 in the at least one switch module 50 is connected to the power supply 60 through the corresponding acupoint patch 30, the other end is connected to the output pin of the single chip microcomputer 40, and the power supply 60 is further connected to the single chip microcomputer 40.

When the ear acupoint stimulation device is used, a user can wear the ear model 10 on an ear needing acupoint stimulation, the resistance of the ear model 10 is large enough, and when the ear acupoint stimulation device breaks down to form large current in a current transmission circuit, the ear model 10 can effectively reduce the current so as to guarantee the safety of the user.

The ear model 10 can be a 3D printed ear model, and the 3D printed ear model already contains the respective acupuncture points of the ear; the simulated ears are printed out through 3D, so that the ear models can be directly generated from computer graphic data without machining or any die, the ear models generated through 3D printing are the same models which are manufactured according to the individuation of the ears of the patients, and therefore the ear models can be well matched with all acupuncture points of the patients, the effect of effective stimulation is achieved, meanwhile, the development period of the ear models can be greatly shortened, the production rate of the ear models is improved, and the production cost is reduced.

In the aforementioned at least one switch module 50, one end of each switch module 50 is connected to the power supply 60 through the corresponding acupoint patch 30, and the other end is connected to the output pin of the single chip microcomputer 40, which may represent two meanings, specifically: first, the single chip microcomputer 40 may control one or more switch modules connected thereto through one output pin. Second, the single chip microcomputer 40 includes a plurality of output pins, each of which is connected to a switch module, and the switch module is controlled by respectively controlling the level states of the plurality of output pins.

The ear acupoint stimulation device of the design is characterized in that the ear model is provided with the acupuncture points, and the acupuncture point patches for stimulation are arranged on the acupuncture points, so that the acupuncture point stimulation can be completed after a user wears the ear model. When the ear acupoint stimulation device fails, such as electric leakage, the ear model can be used as a large resistor to ensure the safety of a user, and the problem of insecurity caused by the fact that an acupoint patch in the ear acupoint stimulation device is directly attached to the skin of the user in the prior art is solved.

In an optional implementation manner of this embodiment, as mentioned above, when the single chip microcomputer 40 includes a plurality of output pins, at least one output pin of the single chip microcomputer 40 corresponds to at least one switch module 50 one to one; the at least one switch module 50 corresponds to the at least one acupoint patch 30 one by one; each output pin of the at least one output pin of the single chip microcomputer 40 is connected with the power supply 60 through the corresponding switch module 50 and the acupoint patch 30 in sequence.

While the above structure and principle are illustrated by specific examples in the west, the at least one switch module may be three switch modules, the at least one acupoint patch is three acupoint patches at this time, and the at least one output pin is also three output pins at this time, for example, as can be seen from the ear acupoint stimulation device shown in fig. 2, the ear acupoint stimulation device includes three switch modules 50, which are a first switch module 501, a second switch module 502 and a third switch module 503; the number of the acupoint patches 30 is 3, which are respectively a first acupoint patch 301, a second acupoint patch 302 and a third acupoint patch 303, and the single chip microcomputer 40 comprises three output pins and two input pins, which are respectively a first output pin a1, a second output pin a2 and a third output pin a 3; a first input pin b1 and a second input pin b 2.

As mentioned above, the at least one acupoint patch 30 and the at least one switch module 50 are in one-to-one correspondence, and one acupoint patch 30 corresponds to one switch module 50, for example, the first acupoint patch 301 in fig. 2 corresponds to the first switch module 501; the second acupoint patch 302 corresponds to the second switch module 502; the third acupoint patch corresponds to the third switch module 503. As mentioned above, at least one output pin of the single chip 40 corresponds to at least one switch module 50 one to one, and as can be seen from fig. 2, it is represented as: a first output pin a1 of the single chip microcomputer 40 corresponds to the first switch module 501; the second output pin a2 of the single chip microcomputer 40 corresponds to the second switch module 502; a third output pin a3 of the single chip microcomputer 40 corresponds to the third switch module 503; the first input pin b1 of the single chip microcomputer is connected with the power supply 60, and the second input pin b2 of the single chip microcomputer is used for receiving a trigger signal.

Each of the at least one output pin of the single chip 40 is connected to the power supply 60 through the corresponding switch module 50 and the acupoint patch 30 in sequence, as can be seen from fig. 2, it is represented as: a first output pin a1 of the singlechip 40 is connected with the power supply 60 through a first switch module 501 and a first acupoint patch 301; the second output pin a2 of the single chip microcomputer 40 is connected with the power supply 60 through the second switch module 502 and the second acupuncture point patch 302; the third output pin a3 of the single chip microcomputer 40 is connected with the power supply 60 through the third switch module 503 and the third acupoint patch 303.

In the initial stage, the first switch module 501, the second switch module 502 and the third switch module 503 are all in the off state, so that the power source 60 does not supply power to the first acupoint patch 301, the second acupoint patch 302 and the third acupoint patch 303 in the initial stage.

When the second input pin b2 of the single chip microcomputer 40 receives the trigger signal, the level states output by the first output pin a1, the second output pin a2 and the third output pin a3 are controlled according to the trigger signal, when the level state output by the output pin of the single chip microcomputer 40 changes, the corresponding switch state changes, and then the power supply 60 supplies power to the corresponding acupuncture point patch. For example, when the single chip microcomputer 40 controls the level state output by the first output pin a1 to change according to the trigger signal, the level state of the first output pin a1 changes, and the corresponding first switch module 501 changes from the off state to the on state, at this time, the power source 60, the first switch module 501 and the first acupoint patch 301 are in the on state, the power source 60 supplies power to the first acupoint patch 301, and the first acupoint patch 301 stimulates the acupoint corresponding to the first acupoint patch 301.

The ear acupuncture point stimulation device of above-mentioned design, the level state according to a plurality of output pin of received trigger signal control through the singlechip controls the on off state of a plurality of switch module that correspond to be connected with a plurality of output pin, and then the operating condition of the acupuncture point paster of control and each switch module connection, solve current acupuncture point stimulation device and can't carry out amazing the not pertinence problem that does not have that exists to the acupuncture point according to user's specific demand selectivity, make the user can carry out the selectivity amazing to the acupuncture point, realize doctor or user's acupuncture point amazing scheme, reach the amazing effect of pertinence.

In an alternative embodiment of this embodiment, there are various selection manners of the switch module 50, for example, a transistor or a mos transistor may be used as the switch module 50 in this embodiment, and a PNP transistor is specifically described as the switch module 50 in this embodiment below:

as shown in fig. 3, the first switch module 501, the second switch module 502, and the third switch module 503 in the foregoing example are respectively changed into a PNP triode plus a resistor as the switch module 50, the first switch module 501 includes a first PNP triode 5101 and a first resistor R1, an emitter of the first PNP triode 5101 is connected to the power supply 60 through the first acupoint patch 301, a collector of the first PNP triode 5101 is grounded, and a base of the first PNP triode 5101 is connected to the first output pin a1 of the single chip microcomputer 40 through the first resistor R1; similarly, the second switch module 502 includes a second PNP transistor 5102 and a second resistor R2, an emitter of the second PNP transistor 5102 is connected to the power supply 60 through the second acupoint patch 302, a collector of the second PNP transistor 5102 is grounded, and a base of the second PNP transistor 5102 is connected to the second output pin a2 of the single chip microcomputer 40 through a second resistor R2; the third switching module 503 includes a third PNP transistor 5103 and a third resistor R3, an emitter of the third PNP transistor 5103 is connected to the power supply 60 through the third acupoint patch 303, a collector of the third PNP transistor 5103 is grounded, and a base of the third PNP transistor 5103 is connected to the third output pin a3 of the single chip microcomputer 40 through the third resistor R3.

On the basis of the connection relation, because the emitter of the PNP triode is connected with the power supply and is at a high level, the base of the PNP triode is set to be at the high level in the initial stage, so that the collector and the emitter of the PNP triode are cut off and are in a non-conduction state in the initial stage, and the power supply 60 does not supply power for the acupuncture point patch.

In the working phase, the single chip microcomputer 40 receives a trigger signal through the second input pin b2, the trigger signal includes information for changing a high level output by a certain output pin into a low level, so that after the output pin outputs the low level, a collector electrode and an emitter electrode of a corresponding PNP triode are conducted, the power supply 60, the acupoint patch 30, the emitter electrode of the PNP triode and the collector electrode of the PNP triode form a passage, the power supply 60 supplies power to the acupoint patch 30, and the acupoint patch 30 stimulates a corresponding acupoint. Specifically, taking the foregoing connection structure as an example, the single chip microcomputer is set in advance as follows: when receiving the trigger signal 001, the single chip microcomputer adjusts the high level output by the first output pin a1 to be a low level; when the single chip microcomputer receives the trigger signal 010, the single chip microcomputer adjusts the high level output by the second output pin a2 to be a low level; when the single chip microcomputer receives the trigger signal 100, the single chip microcomputer adjusts the high level output by the third output pin a3 to be the low level. At this time, it is assumed that the trigger signal received by the single chip microcomputer through the second input pin b2 includes 001 and 100, the single chip microcomputer adjusts the high level output by the first output pin a1 to a low level, the power supply 60, the first acupoint patch 301, the emitter of the first PNP triode 5101, the collector of the first PNP triode 5101, and the ground terminal form a path, the power supply 60 supplies power to the first acupoint patch 301, and the first acupoint patch 301 stimulates a corresponding acupoint; similarly, since there is 100 in the trigger signal, the single chip adjusts the high level output by the third output pin a3 to a low level, the power supply 60, the third acupoint patch 303, the emitter of the third PNP transistor 5103, the collector of the third PNP transistor 5103, and the ground terminal form a path, the power supply 60 supplies power to the third acupoint patch 301, and the third acupoint patch 303 stimulates the corresponding acupoint.

In an optional implementation manner of this embodiment, taking an NPN triode as the switch module 50 as an example, specifically as shown in fig. 4, the first switch module 501, the second switch module 502, and the third switch module 503 in the foregoing examples are respectively changed into an NPN triode plus a resistor as the switch module 50, where the first switch module 501 includes a first NPN triode 5201 and a fourth resistor R4, an emitter of the first NPN triode 5201 is grounded, a collector of the first NPN triode 5201 is connected to the first acupoint patch 301, and a base of the first NPN triode 5201 is connected to the first output pin a1 of the single chip microcomputer 40 through the fourth resistor R4; the second switch module 502 includes a second NPN transistor 5202 and a fifth resistor R5, an emitter of the second NPN transistor 5202 is grounded, a collector of the second NPN transistor 5202 is connected to the second acupuncture point patch 302, and a base of the second NPN transistor 5202 is connected to the second output pin a2 of the single chip microcomputer 40 through the fifth resistor R5; the third switching module 503 includes a third NPN transistor 5203 and a sixth resistor R6, an emitter of the third NPN transistor 5203 is grounded, a collector of the third NPN transistor 5203 is connected to the third bit patch 303, and a base of the third NPN transistor 5203 is connected to the third output pin a3 of the single chip microcomputer 40 through the sixth resistor R6.

On the basis of the connection relation, because the emitter of the NPN triode is connected with the power supply at a low level, the base of the NPN triode is set at the low level in the initial stage, so that the collector and the emitter of the NPN triode are cut off and are in a non-conducting state in the initial stage, and the power supply 60 does not supply power for the acupuncture point patch.

In the working stage, the single chip microcomputer 40 receives a trigger signal through the second input pin b2, the trigger signal includes information for changing a low level output by a certain output pin into a high level, so that after the output pin outputs the high level, a collector and an emitter of a corresponding NPN transistor are connected, the power supply 60, the acupoint patch 30, the emitter of the NPN transistor, and the collector of the NPN transistor form a passage, the power supply 60 supplies power to the acupoint patch 30, and the acupoint patch 30 stimulates a corresponding acupoint. Specifically, taking the aforementioned connection structure as an example, the single chip microcomputer 40 is set in advance as follows: when receiving the trigger signal 001, the single chip microcomputer adjusts the low level output by the first output pin a1 to be a high level; when the single chip microcomputer 40 receives the trigger signal 010, the single chip microcomputer 40 adjusts the low level output by the second output pin a2 to be a high level; when the single chip microcomputer 40 receives the trigger signal 100, the single chip microcomputer adjusts the low level output by the third output pin a3 to a high level. At this time, if the trigger signal received by the single chip microcomputer 40 includes 001 and 100, the single chip microcomputer adjusts the low level output by the first output pin a1 to a high level, the power supply 60, the first acupoint patch 301, the emitter of the first NPN transistor 5201, the collector of the first NPN transistor 5201, and the ground terminal form a path, the power supply 60 supplies power to the first acupoint patch 301, and the first acupoint patch 301 stimulates the corresponding acupoint; similarly, since the trigger signal includes 100, the single chip microcomputer adjusts the low level output by the third output pin a3 to a high level, the power supply 60, the third acupoint patch 303, the emitter of the third NPN transistor 5203, the collector of the third NPN transistor 5203, and the ground terminal form a path, the power supply 60 supplies power to the third acupoint patch 301, and the third acupoint patch 303 stimulates the corresponding acupoint.

In the above two embodiments, the PNP triode or NPN triode is used as the switch module 50, so that the switch circuit can be switched on and off according to the level state output by the output pin of the single chip, selective stimulation of acupuncture points is realized, an acupuncture point stimulation scheme of a doctor or a user is realized, and a targeted stimulation effect is achieved.

In an alternative embodiment of this embodiment, as shown in fig. 5, the ear acupoint stimulation device further includes a wireless receiving module 70, and the wireless receiving module 70 is configured to receive a wireless signal and convert the wireless signal into a trigger signal. The wireless receiving module comprises an antenna 701, a signal amplifier 702, a demodulator 703 and an analog-digital converter 704, wherein the antenna 701, the signal amplifier 702, the demodulator 703 and the analog-digital converter 704 are sequentially connected, and the analog-digital converter 704 is connected with an input pin corresponding to the singlechip 40.

By using the wireless receiving module 70, the received wireless signal can be converted into a trigger signal, and the trigger signal is transmitted to the single chip microcomputer 40, so that the single chip microcomputer 40 can complete the control process and selectively stimulate the acupuncture points. For example, the wireless receiving module 70 may receive a wireless signal transmitted from a mobile terminal such as a mobile phone, and convert the wireless signal into the aforementioned trigger signal such as 001, 010, or 100. Specifically, the positions of the respective acupoint patches and the acupoints on the ear model, for example, the positions of the first acupoint patch 301, the second acupoint patch 302 and the third acupoint patch 303, can be displayed on the mobile terminal such as the mobile phone, and the user can click one of the acupoint patches, for example, click the first acupoint patch 301 according to the physical condition of the wearer, at this time, the mobile phone sends a wireless signal outwards, the wireless signal includes information of clicking the first acupoint patch 301, and the wireless receiving module 70 receives the information through the antenna 701, and converts the information into the corresponding trigger signal 001 through the signal amplifier 702, the demodulator 703 and the analog-to-digital converter 704 in sequence. The click information of the first acupoint patch 301 generated by the mobile phone and the corresponding converted trigger signal 001 may be set in advance to correspond to each other. The other acupuncture point patch and the corresponding converted trigger signal can also be set in advance to correspond to each other.

In the above embodiment, the wireless receiving module can receive the wireless signal transmitted from the outside of the ear acupoint stimulation device, and then the wireless signal is converted into the trigger signal to be input to the single chip microcomputer, so that the single chip microcomputer can complete the process of controlling the acupoint stimulation in a subsequent selection mode.

In an optional implementation manner of this embodiment, the wireless receiving module 70 further includes a filter 705, and the antenna 701 is connected to the signal amplifier 702 through the filter 705.

In the above embodiment, the filter is used to filter noise and partial interference from the received wireless signal, so that the filtered signal can be more effectively amplified, demodulated and converted.

In an alternative embodiment of this embodiment, the acupuncture point patches 30 include electrode pads and patches connected to each other, the patches being attached to the acupuncture points 101 of the ear model 10, the electrode pads being connected to the switch module 50.

In the above embodiment, the electrode plate stimulates the acupuncture points after the switch module is switched on, and simultaneously stimulates the plaster in the medicinal patch to act on the acupuncture points, so that the stimulation on the acupuncture points is not only targeted but also more effective.

Wherein the electrode pads and the patch are connectable by means of an adhesive substance, such as double sided tape or the like, so that the same patch can be replaced after a period of use.

In an optional implementation manner of this embodiment, the single chip microcomputer is a 51-series single chip microcomputer, preferably an AT89S51 single chip microcomputer.

Second embodiment

The present application provides an ear acupoint stimulation system comprising an ear acupoint stimulation device as in any one of the alternative embodiments of the first embodiment. The specific implementation process and advantages of the ear acupoint stimulation system are similar to those of the ear acupoint stimulation device in the first embodiment, and therefore, the detailed description is omitted here.

In the description of the present application, it should be noted that the terms "inside", "outside", 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 application usually place when using, and are only used for convenience in describing the present application and simplifying the description, but do not indicate or imply that the devices or elements that are referred to must have a specific orientation, be constructed in a specific orientation, and operate, and thus, should not be construed as limiting the present application. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

It should also be noted that, unless expressly stated or limited otherwise, the terms "disposed" and "connected" are to be construed broadly, e.g., as meaning fixedly connected, detachably connected, or integrally connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood in a specific case by those of ordinary skill in the art.

The above description is only an example of the present application and is not intended to limit the scope of the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims (10)

1. An ear acupoint stimulation device, the device comprising:

an ear model provided with at least one acupoint;

at least one acupoint patch arranged on the acupoint of the ear model for stimulating the acupoint of the ear model;

the singlechip is used for controlling the level state of at least one output pin according to the received trigger signal;

the switch module is used for controlling the working state of the acupuncture point patch according to the level state of at least one output pin of the singlechip;

a power supply for supplying power;

the at least one acupoint patch corresponds to the at least one switch module one by one; one end of each switch module in the at least one switch module is connected with a power supply through a corresponding acupuncture point patch, and the other end of each switch module is connected with an output pin of the single chip microcomputer; the power supply is also connected with the singlechip.

2. The device of claim 1, wherein at least one output pin of the single chip microcomputer corresponds to the at least one switch module one to one; and each output pin in at least one output pin of the singlechip is connected with the power supply after sequentially passing through the corresponding switch module and the acupuncture point patch.

3. The device of claim 1, wherein the switch module comprises a PNP triode and a first base resistor, wherein an emitter of the PNP triode is connected to the corresponding acupuncture point patch, a collector of the PNP triode is grounded, and a base of the PNP triode is connected to the output pin of the single chip microcomputer through the first base resistor.

4. The device of claim 1, wherein the switch module comprises an NPN triode and a second base resistor, a collector of the NPN triode is connected to the corresponding acupoint patch, an emitter of the NPN triode is grounded, and a base of the NPN triode is connected to the output pin of the single chip microcomputer through the second base resistor.

5. The device of claim 1, further comprising a wireless receiving module for receiving a wireless signal and converting the wireless signal into the trigger signal, wherein the wireless receiving module comprises an antenna, a signal amplifier, a demodulator and an analog-digital converter, the antenna, the signal amplifier, the demodulator and the analog-digital converter are connected in sequence, and the analog-digital converter is connected with an input pin of the single chip microcomputer.

6. The apparatus of claim 5, wherein the wireless receiving module further comprises a filter, and wherein the antenna is connected to the signal amplifier through the filter.

7. The device as claimed in claim 1, wherein the acupuncture point patches include electrode pads and patches connected to each other, the patches being attached to acupuncture points of the ear models, the electrode pads being connected to corresponding switch modules.

8. The apparatus of claim 1, wherein the ear model is a 3D printed ear model.

9. The device of claim 1, wherein the single chip microcomputer is of the type AT89S 51.

10. An ear acupoint stimulation system, comprising an ear acupoint stimulation device according to any one of claims 1 to 9.

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