CN216366331U - Intelligent heating adjustment physiotherapy instrument based on bioelectricity feedback - Google Patents
Intelligent heating adjustment physiotherapy instrument based on bioelectricity feedback Download PDFInfo
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- CN216366331U CN216366331U CN202122401752.7U CN202122401752U CN216366331U CN 216366331 U CN216366331 U CN 216366331U CN 202122401752 U CN202122401752 U CN 202122401752U CN 216366331 U CN216366331 U CN 216366331U
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Abstract
The utility model discloses a physiotherapeutic instrument for intelligent heating adjustment based on bioelectricity feedback. The device comprises an MCU controller, a boost control circuit, a pulse output control circuit, a bioelectricity feedback circuit and a heating control circuit, wherein the MCU controller is respectively connected with the boost control circuit, the pulse output control circuit, the bioelectricity feedback circuit and the heating control circuit, the pulse output control circuit inputs electric pulses in a safe range to a human body load through an electrode plate, and the bioelectricity feedback circuit feeds back the electric pulses to the MCU controller through one or more electric parameters of human body resistance, voltage, current and frequency. The utility model judges the condition of the human body by inputting pulses to the human body and by one or more electric parameters such as resistance value, current, voltage, frequency and the like which are fed back, thereby adjusting the proper temperature, and realizing the intelligent adjustment of the heating temperature according to different physiological conditions of the human body.
Description
Technical Field
The utility model relates to the technical field of physiotherapy equipment, in particular to a physiotherapy instrument based on bioelectricity feedback and capable of intelligently heating and adjusting.
Background
The electric pulse physiotherapy instrument connects pulse electric signal with certain voltage and frequency with human body through electrodes, and because many components of human body tissue have certain electric characteristics, when receiving electric stimulation, the muscle, nerve, body fluid and blood of human body can produce physicochemical reaction to a certain extent. Low frequency electrotherapy and medium frequency electrotherapy are among the most common of such devices. The pain can be improved and the nerve function can be adjusted by electrotherapy in hospitals.
However, in order to enhance the comfort level of the user and enhance the physiotherapy effect, the physiotherapy instruments with functions on the market can be adjusted by setting different heating intensities, but the heating gear is basically adjusted by the user, so that the heating intensity is adjusted. This type of adjustment is obviously highly demanding with respect to physical therapy techniques and presents difficulties for the general population or the elderly.
SUMMERY OF THE UTILITY MODEL
Aiming at the defects in the prior art, the utility model aims to provide an intelligent heating regulation physiotherapy instrument based on bioelectricity feedback.
In order to achieve the purpose, the utility model adopts the following technical scheme:
the utility model provides a physiotherapy equipment that intelligence heating was adjusted based on biological electric feedback, includes MCU controller, boost control circuit, pulse output control circuit, biological electric feedback circuit and heating control circuit, the MCU controller is connected boost control circuit, pulse output control circuit, biological electric feedback circuit and heating control circuit respectively, pulse output control circuit inputs the electric pulse in the safety range to human load through the electrode slice, biological electric feedback circuit feeds back to the MCU controller through gathering one or more electric parameter in human resistance, voltage, electric current, the frequency, the MCU controller is according to the parameter difference of feeding back to the heating duration of heating plate is controlled through heating control circuit to reach the height control of temperature.
Preferably, boost control circuit includes inductance, first triode and second triode, the base of first triode is connected with the PUMP end pin of MCU controller through first resistance, inductance one end inserts the power, the other end is connected with the collecting electrode of first triode, the collecting electrode of first triode is connected with the diode and is connected with the positive pole of diode, the diode negative pole is connected with pulse output control circuit, the negative pole of diode passes through charging capacitor ground connection and is connected with the collecting electrode of second triode through third resistance, the base of second triode is connected through the DIS _ P end pin of second resistance and MCU controller.
Preferably, the pulse output control circuit includes a fourth transistor, a fifth transistor, a sixth transistor and a seventh transistor, the base electrodes of the fourth triode, the fifth triode, the sixth triode and the seventh triode are respectively connected with the M-2 terminal pin, the M-0 terminal pin, the M-3 terminal pin and the M-1 terminal pin of the MCU controller through a sixth resistor, a fifth resistor, an eighth resistor and a seventh resistor, the emitting electrodes of the fifth triode and the seventh triode are connected with the output end of the boost control circuit, the collector of the fifth triode is connected with the emitter of the fourth triode and is simultaneously connected with the electrode plate, the collector of the seventh triode is connected with the emitter of the sixth triode and simultaneously connected with the other end of the electrode plate, and the collector electrodes of the fourth triode and the sixth triode are simultaneously connected with the bioelectricity feedback circuit.
Preferably, the bioelectricity feedback circuit comprises an eleventh resistor and a fourth resistor, one end of the eleventh resistor is grounded, the other end of the eleventh resistor is connected with the fourth resistor and the pulse output control circuit, and the other end of the fourth resistor is grounded through the first capacitor and connected with a pin of a B-DET (test-detection) terminal of the MCU controller.
Preferably, the heating control circuit comprises a third triode and an eighth triode, the base of the third triode is grounded through a tenth resistor and is connected with the HEAT terminal pin of the MCU controller through a ninth resistor, the collector of the third triode is connected with the base of the eighth triode, the emitter of the eighth triode is connected with the power supply, the collector of the eighth triode is connected with the heating sheet, and the other end of the heating sheet is grounded through a self-recovery fuse.
By adopting the scheme, the utility model judges the condition of the human body by inputting pulse to the human body and by one or more electric parameters such as resistance value, current, voltage, frequency and the like which are fed back while carrying out pulse physiotherapy, thereby adjusting proper temperature to carry out related thermotherapy and realizing intelligent treatment of automatic temperature adjustment according to different physiological conditions of the human body.
Drawings
Fig. 1 is a schematic structural diagram of an embodiment of the present invention.
Fig. 2 is a schematic structural diagram of an MCU controller according to an embodiment of the present invention.
Fig. 3 is a schematic structural diagram of a boost control circuit according to an embodiment of the present invention.
Fig. 4 is a schematic structural diagram of a pulse output control circuit according to an embodiment of the present invention.
Fig. 5 is a schematic structural diagram of a bioelectrical feedback circuit according to an embodiment of the present invention.
Fig. 6 is a schematic structural diagram of a heating control circuit according to an embodiment of the present invention.
Detailed Description
The embodiments of the utility model will be described in detail below with reference to the drawings, but the utility model can be implemented in many different ways as defined and covered by the claims.
As shown in fig. 1 to 6, the intelligent heating-adjusting physiotherapy instrument based on bioelectricity feedback provided in this embodiment includes an MCU controller 1, a boost control circuit 2, a pulse output control circuit 3, a bioelectricity feedback circuit 4 and a heating control circuit 5, the MCU controller 1 is connected to the boost control circuit 2, the pulse output control circuit 3, the bioelectricity feedback circuit 4 and the heating control circuit 5, the pulse output control circuit 3 inputs an electric pulse in a safe range to a human body load through an electrode plate, the bioelectricity feedback circuit 4 feeds back to the MCU controller 1 through one or more electrical parameters of human body resistance, voltage, current, frequency, etc., and the MCU controller 1 controls the heating duration of the heating plate through the heating control circuit 5 according to the different feedback resistances, so as to achieve the temperature control.
In this embodiment, the MCU controller 1 may adopt XWIC035 model, the PUMP terminal pin of the MCU controller 1 outputs PWM signal for the boost control circuit 2, the PUMP terminal pin DIS _ P of the MCU controller 1 is GPIO output port for the discharge control of the boost control circuit 2, M0 of the MCU controller 1, M1, M2, the M3 terminal pin is GPIO output for controlling the pulse output to the human body, the HEAT terminal pin of the MCU controller 1 is GPIO port for performing on-off control on the product heating module, the B _ DET terminal pin of the MCU controller 1 is AD detection port for collecting the human body feedback current during operation. MCU controller 1 is according to the treatment procedure of user's selection, control step up and pulse output, and the human body current of feeding back on one's body on the acquisition B _ DET terminal pin through AD mouth simultaneously reachs the human corresponding resistance of target through calculating to judge human physiology situation, classify the people of different states, if: sensitive type, normal type and slow type, then controlling the heating temperature interval according to different user groups, and referring to the comparison table as follows:
feedback resistance value | Corresponding crowd | Controlling temperature |
500 omega or less | Sensitive type | 36~38℃ |
500~10KΩ | General type | 38~40℃ |
10K omega or more | Late blunt type | 40~42℃ |
According to this table, the MCU controller 1 realizes automatic temperature adjustment by controlling the PWM duty ratio of the heating control circuit 5. It should be noted that: the above only represents the relationship between the feedback resistance interval definition and the control temperature selection, which is only used as an example, and the collected electrical parameter category difference and the change of the related value are still within the protection scope of the present embodiment.
Further, the boost control circuit 2 of the present embodiment may adopt a circuit structure as shown in fig. 3, that is, the boost control circuit includes an inductor L1, a first triode Q1 and a second triode Q2, a base of the first triode Q1 is connected to a PUMP terminal pin of the MCU controller 1 through a first resistor R1, one end of the inductor L1 is connected to a power supply, and the other end is connected to a collector of the first triode Q1, a collector of the first triode Q1 is connected to a diode D1 and to an anode of the diode D1, a cathode of the diode D1 is connected to the pulse output control circuit 4, a cathode of the diode D1 is grounded through a charging capacitor E1 and connected to a collector of the second triode Q2 through a third resistor R3, and a base of the second triode Q2 is connected to a DIS _ P terminal pin of the MCU controller 1 through a second resistor R2. The boosting part of the circuit adopts a bootstrap principle, when the output of a PUMP terminal pin of the MCU controller 1 is high, a first triode Q1 is conducted, a power supply VCC discharges to the ground through an inductor L1, wherein a diode D1 prevents the voltage of a capacitor E1 from flowing backwards, because the current on a direct current inductor linearly increases in a certain proportion, and the energy is stored in the inductor L1 along with the increase of the current; when the PUMP pin output of the MCU controller 1 is low, the first transistor Q1 is turned off, and the current flowing through the inductor L1 does not immediately become 0 but slowly changes from the value at the end of charging to 0 due to the current holding characteristic of the inductor L1. The original circuit is disconnected, so the inductor L1 can only discharge through the new circuit, that is, the inductor L1 starts to charge the capacitor E1, the voltage across the capacitor E1 rises, and at this time, the voltage is higher than the input voltage, and the boosting is completed. The DIS _ P pin of the MCU controller 1 is at a low level at ordinary times, the second transistor Q2 is turned off, when the boost level is not needed or needs to be lowered, the DIS _ P pin of the MCU controller 1 outputs a high level, the second transistor Q2 is turned on, and the voltage across the capacitor E1 is discharged through the second transistor Q2.
Further, the pulse output control circuit 3 of the present embodiment may adopt the circuit structure of fig. 4, that is, it includes a fourth transistor Q4, a fifth transistor Q5, a sixth transistor Q6 and a seventh transistor Q7, bases of the fourth transistor Q4, the fifth transistor a5, the sixth transistor a6 and the seventh transistor Q7 are respectively connected to an M-2 terminal pin, an M-0 terminal pin, an M-3 terminal pin and an M-1 terminal pin of the MCU controller 1 through a sixth resistor R6, a fifth resistor R5, an eighth resistor R8 and a seventh resistor R7, emitters of the fifth transistor Q5 and the seventh transistor Q7 are connected to an output terminal of the boost control circuit 2, a collector of the fifth transistor Q5 is connected to an emitter of the fourth transistor Q4 and simultaneously connected to an electrode pad, a collector of the seventh transistor Q7 is connected to an emitter of the sixth transistor Q6 and simultaneously connected to the other end of the electrode pad, the collectors of the fourth transistor Q4 and the sixth transistor Q6 are both connected to the bio-electric feedback circuit 4. The pulse control end of the circuit is an M-0, M-1, M-2 and M-3 terminal pin of the MCU controller 1, all high levels are output at ordinary times, all triodes are cut off, when a forward pulse is needed, the M-0 terminal pin and the M-3 terminal pin are output low, the M-1 terminal pin and the M-2 terminal pin are output high, a fifth triode Q5 and a sixth triode Q6 are switched on, a fourth triode Q4 and a seventh triode Q7 are cut off, and boosted current is input to an electrode plate through the fifth triode Q5 and then enters a human body load, so that the forward pulse is generated on the human body and is fed back to the bioelectricity feedback circuit from the sixth triode Q6; when reverse pulse is needed, the output of an M-1 terminal pin and an M-2 terminal pin is low, the output of an M-0 terminal pin and an M-3 terminal pin is high, the fourth triode Q4 and the seventh triode Q7 are conducted, the fifth triode Q5 and the sixth triode Q6 are cut off, current is input to an electrode plate through the fourth triode Q4 and then enters a human body load, and the seventh triode Q7 transmits signals to a bioelectricity feedback circuit, so that reverse pulse is generated on a human body, and effective control of pulse is achieved.
Further, the bioelectrical feedback circuit 4 of the present embodiment may adopt the circuit structure shown in fig. 5, and includes an eleventh resistor R11 and a fourth resistor R4, one end of the eleventh resistor R11 is grounded, and the other end is simultaneously connected to the fourth resistor R4 and the pulse output control circuit 3, and the other end of the fourth resistor R4 is grounded through the first capacitor C1 and is connected to the pin of the B-DET terminal of the MCU controller 1. The circuit is mainly used for feeding back the bioelectricity fed back to the human body to the MCU controller 1 in a whole manner, and when the circuit works specifically, a voltage difference is generated after a signal input by the pulse output control circuit 3 passes through the eleventh resistor R11, and then an effective stable voltage is formed after RC filtering is carried out on the signal by the fourth resistor R4 and the first capacitor C1, and the effective stable voltage is provided for the MCU controller 1 to carry out AD detection.
Further, the heating control circuit 5 of this embodiment may adopt a circuit structure as shown in fig. 6, that is, the heating control circuit includes a third transistor Q3 and an eighth transistor Q8, a base of the third transistor Q3 is grounded through a tenth resistor R10 and is connected to a HEAT terminal pin of the MCU controller 1 through a ninth resistor R9, a collector of the third transistor Q3 is connected to a base of an eighth transistor Q8, an emitter of the eighth transistor Q8 is connected to a power supply, a collector of the eighth transistor Q8 is connected to a heater chip, and the other end of the heater chip is grounded through a self-recovery fuse F1. Temperature control port B3 in this circuit, B4 connect the heating plate, and the HEAT terminal pin of MCU controller 1 is low level at ordinary times, and third triode Q3 ends, and the effect of tenth resistance R10 is, for IO mouth potential instability when preventing MCU controller 1 to go up electricity, and then ends for guaranteeing third triode Q3. Its third triode Q3 is high because of the base of eighth triode Q8 department after cutting off, therefore eighth triode Q8 is likewise cut off, the VCC power is disconnected, the heating plate can't work, when needs HEAT, when the HEAT terminal pin output high level of MCU controller 1, third triode Q3 switches on, drives eighth triode Q8 and switches on, VCC voltage is loaded at the heating plate both ends through eighth triode Q8, the heating plate normally works. The MCU controller 1 controls the high and low level time of the HEAT terminal pin, so that the working time of the heating sheet can be effectively controlled, and the heating temperature is controlled. Meanwhile, in order to prevent the heating plate from short-circuiting to cause large current, a self-recovery fuse F1 is specially added, the self-recovery fuse F1 is low in resistance at ordinary times, and when the working current is too large, the resistance of the F1 is changed to be sharply increased to limit the working current, so that the protection effect is achieved.
The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.
Claims (5)
1. The utility model provides a physiotherapy equipment that intelligence heating was adjusted based on biological electricity feedback which characterized in that: the intelligent temperature control device comprises an MCU controller, a boost control circuit, a pulse output control circuit, a bioelectricity feedback circuit and a heating control circuit, wherein the MCU controller is respectively connected with the boost control circuit, the pulse output control circuit, the bioelectricity feedback circuit and the heating control circuit, the pulse output control circuit inputs electric pulses in a safety range to a human body load through an electrode plate, the bioelectricity feedback circuit feeds back the electric pulses to the MCU controller by collecting one or more electric parameters of resistance, voltage, current and frequency of the human body, and the MCU controller controls the heating duration of a heating plate through the heating control circuit according to different feedback parameters so as to achieve temperature control.
2. The intelligent heating regulated physiotherapy instrument based on bioelectrical feedback of claim 1, wherein: the boost control circuit comprises an inductor, a first triode and a second triode, wherein the base of the first triode is connected with the PUMP end pin of the MCU controller through a first resistor, one end of the inductor is connected with a power supply, the other end of the inductor is connected with the collector of the first triode, the collector of the first triode is connected with a diode and is connected with the anode of the diode, the cathode of the diode is connected with the pulse output control circuit, the cathode of the diode is connected with the collector of the second triode through a charging capacitor and a third resistor, and the base of the second triode is connected with the DIS _ P end pin of the MCU controller through a second resistor.
3. The intelligent heating regulated physiotherapy instrument based on bioelectrical feedback of claim 1, wherein: the pulse output control circuit comprises a fourth triode, a fifth triode, a sixth triode and a seventh triode, the base electrodes of the fourth triode, the fifth triode, the sixth triode and the seventh triode are respectively connected with the M-2 terminal pin, the M-0 terminal pin, the M-3 terminal pin and the M-1 terminal pin of the MCU controller through a sixth resistor, a fifth resistor, an eighth resistor and a seventh resistor, the emitting electrodes of the fifth triode and the seventh triode are connected with the output end of the boost control circuit, the collector of the fifth triode is connected with the emitter of the fourth triode and is simultaneously connected with the electrode plate, the collector of the seventh triode is connected with the emitter of the sixth triode and simultaneously connected with the other end of the electrode plate, and the collector electrodes of the fourth triode and the sixth triode are simultaneously connected with the bioelectricity feedback circuit.
4. The intelligent heating regulated physiotherapy instrument based on bioelectrical feedback of claim 1, wherein: the bioelectricity feedback circuit comprises an eleventh resistor and a fourth resistor, one end of the eleventh resistor is grounded, the other end of the eleventh resistor is connected with the fourth resistor and the pulse output control circuit, and the other end of the fourth resistor is grounded through the first capacitor and connected with a B-DET terminal pin of the MCU controller.
5. The intelligent heating regulated physiotherapy instrument based on bioelectrical feedback of claim 1, wherein: the heating control circuit comprises a third triode and an eighth triode, the base of the third triode is connected with the HEAT terminal pin of the MCU controller through a tenth resistor and a ninth resistor, the collector of the third triode is connected with the base of the eighth triode, the emitter of the eighth triode is connected with the power supply, the collector of the eighth triode is connected with the heating sheet, and the other end of the heating sheet is grounded through a self-recovery fuse.
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CN113813508A (en) * | 2021-10-07 | 2021-12-21 | 东莞市医脉实业有限公司 | Intelligent heating adjustment physiotherapy instrument based on bioelectricity feedback |
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CN113813508A (en) * | 2021-10-07 | 2021-12-21 | 东莞市医脉实业有限公司 | Intelligent heating adjustment physiotherapy instrument based on bioelectricity feedback |
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