KR200236432Y1 - A controller for controlling electromagnetic treatment apparatus - Google Patents

Abstract

According to the control device of the electromagnetic therapy apparatus according to the present invention, by receiving a user's control command input from the input means to operate the switching means by the control of the microprocessor, the current flows through the heating wires built in the left and right heating mats Radiate, apply power to the ultra-high frequency generating means built in the left and right heating mats to output the ultra-high frequency alternating magnetic field, apply high voltage to the ozone generating means built in the heat mat, and generate ozone, and electromagnetic waves are generated from the heating wire. The generation of electromagnetic waves is prevented by the electromagnetic wave generation preventing means, a power supply command is input to the left and right heating mat by the left and right heat setting switches of the input means, and the left and right heat time setting switches of the input means ㆍ Control signal output from the microprocessor when the heat radiation time of the right side thermal mat is set The left and right LED arrays are sequentially emitted by the driving means, and the control signal of the microprocessor receiving the user's control command set by the input means is received by the vertical and horizontal driving means and displayed on the set value display means, and the ground check switch If the ground line is not grounded, check whether the ground line is grounded.If the ground line is not grounded, turn on the electromagnetic wave output display lamp to indicate that the electromagnetic wave is being output, and if the electromagnetic wave is output, operate the electromagnetic wave prevention means. It is configured to prevent the output.

Description

A CONTROLLER FOR CONTROLLING ELECTROMAGNETIC TREATMENT APPARATUS}

The present invention relates to a control device of an electromagnetic therapy device, and more particularly, to a control device of an electromagnetic therapy device that can treat various pains in the body, such as low back pain, menstrual pain, lumatis, neuralgia arthritis and prostate disease.

Such a conventional electromagnetic and potential therapy device is disclosed in the electromagnetic and potential therapy device (Utility Model Publication No. 1994--0005125 (published date; March 16, 1994)) of Korean Utility Model Publication No. 1995-0008347 .

The electromagnetic and dislocation therapy device 10 disclosed in the Korean Utility Model Publication is composed of an array of vortex-wound electromagnets 12 and a carbon sheet 14 as a dislocation generating element, as shown in Figs. The spiral wound electromagnet 12 is a wound wound coiled multi-core cord.

These spirally wound electromagnets 12 are arranged in a plurality of longitudinally and horizontally and electrically connected between the upper and lower protective sheets 16 and 16 ′ and sense heat generated from the electromagnet 12 to rise above a predetermined temperature. In this case, the temperature sensor 18 and the bimetal 20 are configured to block the current flowing to the electromagnet 12.

Upper and lower shoulder layers 22 and 22 'are incorporated on each outer surface of the upper and lower protective sheets 16 and 16' for protecting the electromagnet 12, and a high-pitched sound is placed on the upper upper layer 22. The carbon sheet 14 to which electric potential is applied is arrange | positioned, the nonwoven fabric 24 is again integrated in the upper part of the carbon sheet 14, and the upper and lower outer shell materials 26 and 26 'are coalesced.

Electromagnetic and potential therapy device configured as described above is composed of a back-pressure rectifier 28 and a phase-controlled temperature control circuit 30 to rectify to DC by receiving an AC power supply voltage.

A high negative potential of about -700 volts output from the output of the back pressure rectifier 28 is applied to the carbon sheet 14. The phase-controlled temperature control circuit 30 connected in parallel to the back pressure rectifier 28 detects heat generated by the current flowing through the coated multi-core cord constituting the electromagnet 12 with the temperature sensor 18 and the bimetal 20. Current to control the current.

Conventional electromagnetic and potential therapy device configured as described above, since the spiral wound electromagnet 12 does not use iron core core, it can be configured thinly and lightly, and also has flexibility, so it is not only convenient to apply to bedding, but also the electromagnetic field of the ultra long wave alternating magnetic field is Activation of human cells, normalization of blood circulation, and endocrine normalization can be expected, but the output time of the electromagnetic alternating field and the potential of the ultra long alternating magnetic field can not be controlled. In addition, it is inconvenient to use because it is not possible to display the set value and set time of electromagnetic and potential of these ultra-high alternating magnetic fields, and it is possible to remove the power cord at a preset level by simply plugging in the power cord. Since the output until, there was a problem such as wasting energy.

Accordingly, the present invention has been made to solve the various problems described above, and an object of the present invention is to provide a control device of an electromagnetic therapy device that can cure various pains of a body for a predetermined time according to a user's need.

Another object of the present invention is to provide an apparatus for controlling an electromagnetic therapy device that can be easily used and saves energy.

Another object of the present invention is to provide an electromagnetic therapy device capable of arbitrarily setting the ultra-high frequency and ozone generation respectively output from the left and right heating mats, and displaying the output time of the set ultra-high wave and ozone generation levels and blocking the output of electromagnetic waves. To provide a control device.

It is still another object of the present invention to provide a control device for an electromagnetic therapy device that can display that power is applied to the left and right heating mats, and that the power supply time of the left and right heating mats is set.

In order to achieve the above object, the control apparatus of the electromagnetic therapy apparatus according to the present invention is provided with a left and a right heating mat, each of which is provided with a heating wire radiating heat, and is disposed in the left and right heating mat, respectively, to receive power. Ultrasonic wave generating means for outputting an ultra long wave alternating magnetic field, ozone generating means disposed in the left and right thermal mats respectively to receive high voltage and generating ozone, and electromagnetic wave generation preventing means for preventing the generation of electromagnetic waves in the left and right thermal mats; And left and right heating mats by a microprocessor for controlling the overall operation, an input means for inputting a user's control command to the microprocessor, and a control signal output from the microprocessor according to the control command input from the input means. Control of ultra-high wave generation means, ozone generating means and electromagnetic wave preventing means A power supply command is input to the left and right heating mats by means of a switching means and a left and right heating setting switch of the input means, and a heat dissipation time of the left and right heating mats by a heat time setting switch of the input means. In the case of setting, the number of left and right LED arrays to drive the left and right LED arrays sequentially in response to the control signal output from the microprocessor to indicate that power is applied to the left and right thermal mats. However, set value display means for displaying a user's control command set by the input means, and vertical and horizontal for driving the set value display means to display the set value input by the user set by the input means in the set value display means. Whether the drive means, the main switch that regulates the input power, and the ground line are grounded It is characterized in that it comprises a ground confirmation switch for confirming, and a lamp that is turned on when the ground line is not grounded at the time of switching on of the ground confirmation switch.

1 is a partial cutaway perspective view of a conventional electromagnetic and potential therapy device,

2 is a potential generating and adjusting circuit of FIG.

Figure 3 is an external perspective view schematically showing a control device of the electromagnetic therapy device according to an embodiment of the present invention,

Figure 4 is a block diagram of a control device of the electromagnetic therapy device according to an embodiment of the present invention,

Figure 5 is a detailed circuit diagram showing the left and right side thermal mat, ultra-high temperature output means, ozone generating means, electromagnetic wave blocking means and switching means in the control device of the electromagnetic therapy apparatus of an embodiment of the present invention,

FIG. 6 is a detailed circuit diagram showing left and right LED arrays, left and right LED driving means, segment driving means input means, and set value display means in the control apparatus of the electromagnetic therapy apparatus in one embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

98a, 98b: Heating cable 100a: Left heating mat

105: grounding confirmation switch 106: electromagnetic wave output display lamp

110a, 110b: Ultra long wave generating means 120: Ozone generating means

122: radio wave rectifying means 123: + electrode

124: pole plate 130: electromagnetic wave prevention means

140: microprocessor 145: switching means

150: input means 105: electromagnetic ground confirmation switch

106: electromagnetic wave output display lamp 151: left heat temperature setting switch

152: right temperature setting switch 153: left temperature setting switch

154: right heat time setting switch 155: electromagnetic wave output prevention switch

156: ultra-high alternating magnetic field output time setting switch

157: ozone occurrence time setting switch 158: reset switch

160a: left LED array 160b: right LED array

170a: left LED array driving means 170b: right LED array driving means

180: set value display means 181: left heat temperature display segment

182: right side temperature display segment 183: left side temperature display segment

184: Right heat time display segment

185: Ultrasonic alternating magnetic field output time display segment

186: Ozone occurrence time display segment 210: Main switch

220a: first connector 220b: second connector

Hereinafter, a control device of an electromagnetic therapy apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is an external perspective view schematically showing a control device of the electromagnetic therapy device according to an embodiment of the present invention, Figure 4 is a block diagram of a control device of the electromagnetic therapy device according to an embodiment of the present invention, Figure 5 Figure 6 is a detailed circuit diagram showing the left and right side thermal mat, the ultra-high temperature output means, the ozone generating means, the electromagnetic wave blocking means and the switching means in the control device of the electromagnetic therapy device of one embodiment of the present invention, Figure 6 is an embodiment of the present invention Fig. 6 is a detailed circuit diagram showing left and right LED arrays, left and right LED driving means, segment driving means input means and set value display means in the control device.

3 to 6, the control device of the electromagnetic therapy apparatus according to the embodiment of the present invention has left and right heating mats 100a, in which heating wires 98a and 98b radiate heat by receiving power. 100b), ultra-low wave generating means (110a, 110b) disposed in the left and right heating mats (100a, 100b), respectively, and receiving a power to output an ultra-high frequency alternating magnetic field, and in the left and right heating mats (100a, 100b). Ozone generating means 120 for generating ozone by receiving high voltage, respectively, Electromagnetic wave preventing means 130 for preventing the generation of electromagnetic waves in the left and right thermal mats 100a and 100b, and microcontrolling the whole operation The processor 140 and the user's control command, for example, a heat generation temperature / heat generation time setting command of the left and right heating mats 100a and 100b, and an ultra-high frequency alternating magnetic field output from the ultra-wave generators 110a and 110b. Output time setting command and above An input means 150 for inputting an output time setting command of ozone output from the zone generating means 120 to the microprocessor 140, and the microprocessor 140 according to a control command input from the input means 150. Switching means for controlling the operation of the left and right heating mats (100a, 100b), ultra-wave generating means (110a, 110b), ozone generating means 120 and the electromagnetic wave generation preventing means 130 by the control signal output from 160 and a power supply command are input to the left and right heating mats 100a and 100b by the left and right heating setting switches 151 and 152 of the input means 150, and the heating time of the input means 150 is input. When the heat dissipation time of the left and right side thermal mats 100a and 100b is set by the setting switches 153 and 154, the microprocessor may be used to indicate that power is applied to the left and right side thermal mats 100a and 100b. Receive control signal output from 140) Left and right LED array driving means 170a and 170b for driving the LED arrays 160a and 160b to emit light sequentially, and set value display means for displaying a user's control command set by the input means 150 ( 180, vertical and horizontal drive means 190 for driving the set value display means 180 to display the set value input by the user set by the input means 150 on the set value display means 180, and an input. The main switch 210 for controlling power, the ground check switch 105 for checking whether the ground line is grounded, and the ground check switch 105 are turned on when the ground line is not grounded at the time of switching on the ground check switch 105. An electromagnetic wave output display lamp 106 is provided.

The input unit 150 is set to 75 ° C by increasing the set temperature by 5 ° C each time it is pressed once, and the microprocessor generates a control signal for applying power to heat the left and right heating mats 100a and 100b. The left and right heat temperature setting switches 151 and 152 inputted to 140 and the set time increase by 1 hour each time are set up to 8 hours, and the heat dissipation time of the left and right heat mats 100a and 100b is set. Electromagnetic waves are output from the left and right heating time setting switches 153 and 154 and the heating wires 98a and 98b of the left and right heating mats 100a and 100b for inputting a control signal for setting the control signal to the microprocessor 140. In this case, the output time of the electromagnetic wave output preventing switch 155 for preventing the output of electromagnetic waves and the ultra-high frequency alternating magnetic fields 110a and 110b disposed in the left and right thermal mats 100a and 100b are set. Do not recall the control signal Control signal for setting the ozone generation time by the ultra-high frequency alternating magnetic field output time setting switch 156 input to the black processor 140 and the ozone generating means 120 disposed in the left and right heating mats 100a and 100b, respectively. Control signal set by the ozone generation time setting switch 157 for inputting the microprocessor 140 to the microprocessor 140, a reset switch 158 for resetting the entire operation, and the switches 151, 152, 153, 154, 155, 156, 157 and 158. It consists of pull-up resistors R11 and R12 for applying an operating power supply (+ 5V) to input to the input.

The switching means 160 receives the left thermal mat 100a power supply control signal output from the microprocessor 140 through a bias resistor R1 and switches the transistor Q1 and the switching of the transistor Q1. A relay RL1 for connecting the movable contact RL1A to the fixed contact RL1B in parallel with the relay RL1 so that a current flows on so that a current flows through the heating wire 98a of the left heating mat 100a. A diode D3 connected to the relay RL1 to prevent the flow of reverse current and a control signal applied to the right heating mat 100b output from the microprocessor 140 through a bias resistor R2 and switched. The movable contact RL2A is connected to the fixed contact RL2B so that a current flows when the transistor Q2 and the transistor Q2 are switched on so that a current flows through the heating wire 98b of the right side heating mat 100b. Relay RL2, Diode D4 connected in parallel to the relay RL2 to prevent reverse current flow to the relay RL2, and the ultra-high frequency alternating magnetic field output control signal output from the microprocessor 140 to the bias resistor R3. The transistor Q3 to be switched through and connected to the fixed contact RL1B so that a current flows when the transistor Q3 is switched on to supply power to the ultra-wave generators 110a and 110b. A relay RL3, a diode D5 connected in parallel to the relay RL3 to prevent a reverse current from flowing to the relay RL3, and an ozone output control signal output from the microprocessor 140. The transistor Q4 switched through the bias resistor R4 and the movable contact RL4A are applied to the fixed contact RL4 so that a current flows when the transistor Q4 is switched on to apply power to the ozone generating means 120. A relay RL4 connected to B), a diode D6 connected in parallel to the relay RL4 to prevent a reverse current from flowing to the relay RL4, and an electromagnetic wave output from the microprocessor 140; Transistor Q5 that receives the output prevention control signal through the bias resistor R5 and switches so that current flows when switching on the transistor Q5 so that electromagnetic waves are not output from the left and right thermal mats 100a and 100b. A relay RL5 for connecting the movable contact RL5A to the fixed contact RL5B, and a diode D7 connected in parallel with the relay RL5 to prevent the flow of reverse current to the relay RL5. have.

The left and right LED arrays 160a and 160b are controlled by the left and right LED array driving means 170a and 170b which receive the control signal output from the microprocessor 140 to emit light. (LED1-LED16, LED17-LED32). In other words, the left LED array 160a includes light emitting diodes LED1 to LED16, and the right LED array 160b includes light emitting diodes LED17 to LED32.

The ozone generating unit 120 receives the ozone output control signal output from the microprocessor 140 through the bias resistor R4 and switches the bias signals through the bias resistors R8 and R9 when the transistor Q4 is switched. Is switched on as the terminal is applied to the base terminal, a transformer T1 for boosting and outputting the power applied to the primary coil at a predetermined ratio when the transistor Q6 is switched on, and the transformer T1. A full-wave rectifying means 122 for full-wave rectifying the voltage induced in the secondary side coil of the) and a high electrode output from the full-wave rectifying means 122 so as to face the negative electrode plate 124 to generate ozone. It consists of 123.

The set value display means 180 increases the heat temperature by 5 ° C. each time the left and right heat temperature setting switches 151 and 152 of the input unit 150 are pressed once. It receives the control signal output from 190 and displays the left and right heating temperature, and displays the temperature detected by the temperature detection sensors 202a and 202b after a predetermined time (for example, 5 seconds) after setting. Each time the left and right heating temperature display segments 181 and 182 and the left and right heating time setting switches 153 and 154 of the input unit 150 are pressed once, the set time is increased by 1 hour to set the heating time set to 8 hours. • The setting time increases by one hour each time the left and right heating time display segments (183, 184) received from the horizontal driving means (190) and the ultra-high alternating magnetic field setting switch (156) of the input unit (150) are pressed once. 8 hours By the ultra-high alternating magnetic field output time display segment 185 for receiving and displaying the predetermined long-wave alternating magnetic field output time from the vertical and horizontal driving means 190, and the ozone generation time setting switch 157 of the input unit 150. The ozone generation time display segment 186 is configured to receive and display the set ozone generation time from the vertical and horizontal driving means 190.

The electromagnetic wave generation preventing means 130 includes a movable contact RL5A and a fixed contact RL5B of the relay RL5.

In the figure, 102a and 102b are respectively installed in the left and right heating mats 100a and 100b to detect temperature and output the temperature to the microprocessor 140 through the second and first connectors 220b and 220a. 104a and 104b are bimetals connected in series to the heating wires 98a and 98b to block the flow of current when the temperature is above a certain temperature, and R20 is to suppress the electromagnetic wave output signal when the electromagnetic wave output display lamp 106 is turned on. Current limiting resistors output to the microprocessor 140 through the second and first connectors 220b and 220a, and 109a and 109b are ground terminals for grounding the left and right thermal mats 100a and 100b, respectively.

Next, the operation and effects of the control device of the electromagnetic therapy apparatus according to the embodiment of the present invention configured as described above will be described.

The present invention is plugged into the outlet (not shown), the main switch 210 is switched on, the left and right heating temperature setting switch (151, 152) of the input means 150 to set the temperature, the left and right heating time setting Press the switches (153, 154) to set the time, the ultra-high alternating field generation time setting switch (156) to set the ultra-high alternating magnetic field generation time, press the ultra-high ozone generation time setting switch (157) to set the ozone generation time, These signals are input to the microprocessor 140 through the input terminals A and B of the microprocessor 140.

Accordingly, electric current flows in the heating wires 98a and 98b in the left and right heating mats 100a and 100b to radiate heat, for example, far infrared rays, to apply far infrared rays to the user's body to promote blood circulation, and to generate ultra-long wave generation means. Power is also applied to (110a, 110b) to output the ultra-high frequency alternating magnetic field to apply to the pain area of the user to cure the pain, and to apply the power to the ozone generating means 120, + electrode 123 and-electrode ( Ozone is generated between 124 to sterilize bad bacteria or various bacteria in the air, and when the electromagnetic wave output display lamp 106 is turned on by pressing the ground check switch 105, the electromagnetic wave output prevention switch 155 is pressed. By grounding the ground line among the heating wires 98a and 98b in the left and right heating mats 100a and 100b, electromagnetic waves are not output.

In other words, when a power plug (not shown) is connected to the AC220V line, and then the heat is required to be radiated to a necessary temperature, for example, 45 ° C, to radiate the left and right heat temperature setting switches 151 and 152 of the input means 150. Since the left and right heat temperature setting switches 241 and 242 increase by 5 ° C each time, the left and right heat temperature setting switches 151 and 152 are pressed nine times to radiate heat to the left and right heat mats 100a and 100b. When the temperature is set to 45 ° C. and the heat time setting switches 153 and 154 are pressed eight times to set the heat dissipation time of the left and right heat mats 100a and 100b to eight hours, the set time is 1 for each press. As time increases, the heat release time is set to 8 hours.

At the same time, since the signals related to the left and right warm temperature and the heat time are input to the microprocessor 140 through the input terminals A and B of the microprocessor 140, the first and second signals of the microprocessor 140 A control signal is output so that a current is applied to the left and right heating mats 100a and 100b through the second connectors 220a and 220b, and the transistors Q1 and R1 through the bias resistors R1 and R2 of the switching means 160. Transistors Q1 and Q2 are switched on by being applied to the base terminal of Q2), and currents flow through the relays RL1 and RL2 according to the switching-on of the transistors Q1 and Q2, respectively, and thus the movable contacts RL1A and RL2A. Since this is connected to the fixed contacts RL1B and RL2B, AC220V is applied to the heating wires 98a and 98b of the left and right heating mats 100a and 100b, respectively, so that current flows through the heating wires 98a and 98b, respectively. It is radiated.

Temperatures in the left and right side heating mats 100a and 100b, through which current flows through the heating wires 98a and 98b, respectively, radiate heat, are detected by the temperature detection sensors 202a and 202b and output to the microprocessor 140. When the detection temperature is higher than the preset temperature, the thermal control signal is not output from the microprocessor 140, so that the corresponding transistors Q1 and Q2 are turned off, so that the left and right heating mats 100a and 100b are not. The bimetal 104a is prevented from overheating the corresponding thermal mat, and when the left and right heating mats 100a and 100b are overheated because the temperature cannot be detected due to a defect of the temperature detection sensors 202a and 202b. (104b) is operated to block the flow of current to the heating wires (98a, 98b) to prevent safety accidents such as fire.

As described above, a heat treatment may be performed by simultaneously flowing a current to the heating wires 98a and 98b of the left and right heating mats 100a and 100b, for example, among the left and right heating mats 100a and 100b. If you want to heat treatment using only the left heat mat 100a, operate only the left heat setting switch 151 to set the left heat temperature, and if you want to heat treatment using only the right heat mat 100b, It is only necessary to operate the heat switch 152 to set the right heat temperature.

In this case, the signals related to the left and right warm temperature and the heat time set by the left and right warm temperature setting switches 151 and 152 and the left and right warm time setting switches 153 and 154 of the input unit 150 are transmitted to the microprocessor 140. Since it is also input to the microprocessor 140 through the input terminals (A, B) of), the left and right heat temperature display segments (181, 182) of the set value display means 180 by receiving the control signal output from the microprocessor (140) The left and right heating temperature is set in the display, the heat dissipation time is set in the left and right heating time display segments 183 and 184, and the control signal output from the microprocessor 140 is left and right LED array driving means. The left and right LED arrays 160a and 160b are emitted by the light sources 170a and 170b to indicate that current flows through the heating wires 98a and 98b of the left and right heating mats 100a and 100b.

As described above, the ultra-high frequency alternating magnetic field output time setting switch 156 of the input means 150 while the heat treatment is performed by flowing a current through the heating wires 98a and 98b of the left and right heating mats 100a and 100b. If you want to treat the ultra long-wave alternating magnetic field by operating, the output time is increased by 1 hour every time you press and can be set up to 8 hours. For example, if you press the ultra long alternating magnetic field output time setting switch 156 three times, When these signals are set, these signals are input to the microprocessor 140 through the input terminals A and B of the microprocessor 140, so that the ultra long-wave alternating field output control signal is output from the microprocessor 140 to switch means. The transistor Q3 is switched on by being applied to the base terminal of the transistor Q3 through the bias resistor R3 of the 160, and the relay (according to the switching on of the transistor Q3). Since the current flows through RL3, respectively, and the movable contact RL3A is connected to the fixed contact RL3B, AC220V is applied to the ultra-high frequency output means 110a and 110b to output the ultra-high frequency alternating magnetic field.

In addition, as described above, a heat treatment is performed by flowing a current through the heating wires 98a and 98b of the left and right heating mats 100a and 100b during operation, and outputting an ultra-high frequency alternating magnetic field from the microwave output means 110a and 110b. In the course of treating pain, when the ozone generation time setting switch 157 of the input means 150 is operated to generate ozone, the output time is increased by 1 hour for each press, and thus can be set up to 8 hours. For example, when the ozone generation output time setting switch 157 is pressed three times to set three hours, these signals are input to the microprocessor 140 through the input terminals A and B of the microprocessor 140. The ozone generation output control signal is output from the microprocessor 140 and applied to the base terminal of the transistor Q4 through the bias resistor R4 of the switching means 160 so that the transistor Q4 is switched. Since the current flows through the relay RL4 according to the switching-on of the transistor Q4, the movable contact RL4A is connected to the fixed contact RL4B, so that the transistor Q6 is switched on to be constant in the transformer T1. Since the power boosted to the level is full-wave rectified by the full-wave rectifier 122 and output to the + electrode 123, ozone is released between the negative electrode plates 124 provided to face the + electrode 123.

When these signals are input to the microprocessor 140, the microprocessor 140 outputs a set value display control signal to the vertical / horizontal driving means 190, and outputs the control signal from the vertical / horizontal driving means 190. Outputs the left and right heating temperature displayed on the left and right heating temperature display segments 181 and 182 of the set value display means 180, and after a predetermined time (usually 5 minutes) has elapsed, the temperature detecting sensors 202a and 202b The current temperature in the left and right heating mats 100a and 100b detected by the display, and the heating time set by the left and right heating time setting switches 153 and 154, respectively, on the left and right heating time display segments 183 and 184, respectively. Is displayed, and the ultra-high alternating magnetic field output time set by the ultra-high alternating magnetic field setting switch 156 is displayed on the ultra-high alternating magnetic field output time display segment 185, and the ozone generation time is set. The ozone generation time is set by the position 157 will be displayed for each of the ozone generating time display segment 186.

In the above description, each set time is counted by a timer (not shown) built in the microprocessor 140 to control the output of the control signal.

In this way, if you want to cancel all the operation of the present invention and to operate again, press the reset switch 158 of the input means 150, + 5V power is applied to the pull-up resistor (R12), at this time After filtering the noise at C13 and limiting the current at the current limiting resistor R13, the current flows to the ground through the light emitting diode LED33, indicating that the light emitting diode LED33 emits light to indicate a reset state.

In the above description, although illustrated and described with reference to specific embodiments, the present invention is not limited to this, for example, by those of ordinary skill in the art without departing from the concept of the present invention Of course, the design can be changed in various ways.

As described above, according to the control device of the electromagnetic therapy apparatus according to the present invention, the current is applied to the heating wires installed in the left and right heating mats by operating the switching means under the control of the microprocessor in response to a user's control command input from the input means. Flows to radiate heat, applies power to the microwave generating means built in the left and right heating mats, outputs the alternating magnetic field of magnetic fields, and applies ozone to the ozone generating means built in the heat mat to generate ozone, When electromagnetic waves are generated, electromagnetic waves are prevented from being generated by the electromagnetic wave generation preventing means, and a power supply command is inputted to the left and right thermal mats by the left and right heat setting switches of the input means, and a heat time setting switch of the input means. When the heat dissipation time of the left and right heating mats is set by The control signal outputted from the drive means receives the left and right LED arrays sequentially and the control signal of the microprocessor receiving the user's control command set by the input means is received from the vertical and horizontal drive means. Check whether the ground line is grounded by the ground check switch, and if the ground line is not grounded, turn on the electromagnetic wave output display lamp to indicate that the electromagnetic wave is being output. Since it is configured to prevent the output of electromagnetic waves by operating the prevention means, it is possible to cure various pains of the body for a certain period of time according to the user's needs, can easily use, save energy, and also the left and right heating mat You can arbitrarily set the ultra-high frequency and ozone generation output from At the same time, the output time of the generated microwave and ozone generation can be displayed and the output of electromagnetic waves can be cut off, and the power is supplied to the left and right heat mats. This has the great effect of indicating that the time is set.

Claims (6)

The heating wires 98a and 98b radiating heat by receiving power are respectively disposed in the left and right heating mats 100a and 100b and the left and right heating mats 100a and 100b respectively, and the power is alternately received to receive power. Ultra-wave generating means (110a, 110b) for outputting a magnetic field, ozone generating means (120) which is disposed in the left and right heating mats (100a, 100b) respectively to generate ozone under high voltage, and the left and right heating mats Electromagnetic wave generation preventing means 130 for preventing the generation of electromagnetic waves at (100a, 100b), a microprocessor 140 for controlling the overall operation, and input means 150 for inputting a user's control command to the microprocessor 140 And left and right heating mats 100a and 100b, ultra-high wave generating means 110a and 110b, and ozone by a control signal output from the microprocessor 140 according to a control command input from the input means 150. Generating means 120 and electromagnetic wave prevention water The power supply command is supplied to the left and right heating mats 100a and 100b by the switching means 160 for controlling the operation of the stage 130 and the left and right heating setting switches 151 and 152 of the input means 150. When the heat dissipation time of the left and right heating mats 100a and 100b is set by the heating time setting switches 153 and 154 of the input means 150, the power is supplied to the left and right heating mats 100a and 100b. The left and right LED array driving means 170a, which is driven to sequentially emit the left and right LED arrays 160a and 160b by receiving a control signal output from the microprocessor 140 to indicate that the signal is applied. 170b), set value display means 180 for displaying a user's control command set by the input means 150, and a set value input by the user set by the input means 150; The set value display means 180 to display at Vertical and horizontal drive means 190 for driving the main power supply, the main switch 210 for controlling the input power, a ground confirmation switch 105 for confirming whether the ground line is grounded, and the ground confirmation switch 105 And an electromagnetic wave output lamp (106) which is turned on when the ground line is not grounded at the time of switching on.). According to claim 1, wherein the input means 150 is set up to 75 ℃ by setting the temperature increases by 5 ℃ each time is pressed once, to apply power to heat the left and right heating mat (100a, 100b) The left and right heat temperature setting switches 151 and 152 for inputting a control signal to the microprocessor 140, and the set time is increased by 1 hour and set up to 8 hours with each press, and the left and right heat mat 100a is set. The left and right heating time setting switches 153 and 154 for inputting a control signal for setting the heat dissipation time of the 100b to the microprocessor 140, and the heating wires 98a and 100b of the left and right heating mats 100a and 100b. The electromagnetic wave output prevention switch 155 which prevents the output of the electromagnetic wave when the electromagnetic wave is output from 98b), and the ultra-high wave alternating means in the ultra-wave generators 110a and 110b disposed in the left and right thermal mats 100a and 100b, respectively. To set the output time of the magnetic field The ozone generation time is set by the ultra-high frequency alternating magnetic field output time setting switch 156 for inputting a signal to the microprocessor 140 and the ozone generating means 120 disposed in the left and right thermal mats 100a and 100b, respectively. The control signal set by the ozone generation time setting switch 157 for inputting a control signal to the microprocessor 140, a reset switch 158 for resetting the entire operation, and the switches 151, 152, 153, 154, 155, 156, 157 and 158. And a pull-up resistor (R11, R12) for applying an operating power (+ 5V) to be input to (140). The transistor Q1 of claim 1, wherein the switching unit 160 receives and controls a left heating mat 100a power supply control signal output from the microprocessor 140 through a bias resistor R1, and A relay RL1 for connecting the movable contact RL1A to the fixed contact RL1B such that a current flows when the transistor Q1 is switched on so that a current flows in the heating wire 98a of the left heating mat 100a, and the relay A diode D3 connected in parallel to the RL1 to prevent the flow of reverse current to the relay RL1, and a control signal for applying a power supply control signal to the right side heating mat 100b output from the microprocessor 140; The fixed contact of the movable contact RL2A such that a current flows through the transistor Q2 which is received and switched through the R2 and the switching current of the transistor Q2 flows through the heating wire 98b of the right side heating mat 100b. Connect to (RL2B) A relay RL2, a diode D4 connected in parallel to the relay RL2 to prevent a reverse current from flowing to the relay RL2, and an ultra-high frequency alternating magnetic field output control signal output from the microprocessor 140. Is fixed via the bias resistor R3, and the movable contact RL1A is fixed to supply power to the ultra-wave generators 110a and 110b by flowing a current when switching on the transistor Q3. A relay RL3 connected to the contact RL1B, a diode D5 connected in parallel to the relay RL3 to prevent a reverse current from flowing to the relay RL3, and an output from the microprocessor 140; The transistor Q4 is switched to receive the ozone output control signal through the bias resistor R4 and a current flows when the transistor Q4 is switched on to apply power to the ozone generating means 120. A relay RL4 connecting A) to the fixed contact RL4B, a diode D6 connected in parallel to the relay RL4 to prevent a reverse current from flowing to the relay RL4, and the microprocessor ( Transistor Q5, which receives the electromagnetic wave output prevention control signal output from 140 through a bias resistor R5, and a current flows when the transistor Q5 is switched on so that the left and right thermal mats 100a and 100b are turned on. A relay RL5 for connecting the movable contact RL5A to the fixed contact RL5B so as to prevent electromagnetic waves from being outputted, and a diode connected in parallel to the relay RL5 to prevent a flow of reverse current to the relay RL5. The control apparatus of the electromagnetic therapy apparatus comprised by (D7). The method of claim 2, wherein the ozone generating unit 120 receives the ozone output control signal output from the microprocessor 140 through the bias resistor R4, and when the transistor Q4 is switched, the bias resistor R8, The transistor Q6 switched on when the bias signal is applied to the base terminal through R9), and the transformer T1 boosts and outputs the power applied to the primary coil at a predetermined ratio when the transistor Q6 is switched on. And a full wave rectifying means 122 for full-wave rectifying the voltage induced in the secondary coil of the transformer T1, and a high pressure output from the full-wave rectifying means 122 so as to face the negative electrode plate 124. Control device of the electromagnetic therapy device, characterized in that consisting of + electrode 123 for generating ozone. The method of claim 2, wherein the set value display means 180 increases the heat temperature by 5 deg. C each time the left and right warm temperature setting switches 151, 152 of the input unit 150 are pressed. Receives control signals output from the vertical and horizontal driving means 190, respectively, and displays left and right heat temperatures, and after setting a predetermined time, displays left and right temperatures displayed by the temperature detection sensors 202a and 202b. Each time the right side warm temperature display segment (181, 182) and the left and right side warm time setting switches (153, 154) of the input unit (150) are pressed once, the set time is increased by one hour, and the set heat time is set to eight hours. The set time is increased by one hour each time the left and right heating time display segments 183 and 184 received from the horizontal driving means 190 and the ultra-high frequency alternating magnetic field setting switch 156 of the input unit 150 are pressed once. 8 o'clock By the ultra-high alternating magnetic field output time display segment 185 for receiving and displaying the ultra-high alternating magnetic field output time set from the vertical and horizontal driving means 190 and by the ozone generation time setting switch 157 of the input unit 150. And an ozone generation time display segment (186) for receiving and displaying a set ozone generation time from the vertical and horizontal driving means (190). 3. The control apparatus of an electromagnetic therapy apparatus according to claim 2, wherein the electromagnetic wave generation preventing means (130) comprises a movable contact (RL5A) and a fixed contact (RL5B) of the relay (RL5).