KR20140107872A - Automatic electron control device - Google Patents

Abstract

The present invention relates to a multimedia type complex electronic automatic controller which comprises: a power member including an alternating current input unit, a power switch unit, a down transformer unit, a rectifying unit, and a constant voltage unit; an oscillating member having a key input unit, a sensor input unit, and a ceramic oscillator; a display member including a LED display unit and a conditional display unit; a thermal member; a potential member; an electromagnetic member; and a control member. Thermal effect due to heat, potential effect due to generation of negative potential, and electromagnetic generation effect for medical use due to a coil can be provided together. Further, by using the thermal, electric potential, and electromagnetic together, muscle pain can be reduced and blood circulation can be enhanced.

Description

TECHNICAL FIELD [0001] The present invention relates to a multi-

More particularly, the present invention relates to a multimeter type hybrid electronic automatic control apparatus capable of simultaneously providing a heating effect by heat, a potential effect by generating a negative potential, and a medical electromagnetic generating effect by a coil, The present invention relates to a multimeter type hybrid electronic automatic control apparatus capable of alleviating muscular pain using electromagnetic waves together and helping blood circulation.

Generally, mats are used to warm the body by providing heat.

There are also a number of products that provide heat to the body to provide a warm effect to the human body.

On the other hand, generating a potential by the negative potential gives a lot of help to the human body such as relieving muscle aches and improving blood circulation, and it also gives various kinds of help to the human body by generating a medical electromagnetic wave by a coil.

However, in the conventional products, the treatment by the heat, the treatment by the electric potential, and the treatment by the electromagnetic wave are separated and exist separately, which increases the inconvenience of the user. There was a problem.

Therefore, there is a need for a product in which an electric potential generator by a hot and negative potential and an electromagnetic wave generator by a coil are operated and controlled together.

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve all of the above problems, and it is an object of the present invention to provide a heating effect by heat, a potential effect by generation of a negative potential and a medical electromagnetic generation effect by a coil, The present invention has been made in view of the above problems, and it is an object of the present invention to provide a multimeter-type hybrid automatic electronic control apparatus capable of alleviating muscular pain by using electromagnetic waves together with electromagnetic waves and helping blood circulation.

According to an aspect of the present invention, there is provided a multi-mea type hybrid automatic electronic control apparatus comprising: an AC input unit to which an AC current is applied; a power switch unit to allow and block the flow of electrical energy; A power source member having a down transformer portion for reducing the number of bolts, a rectifying portion for rectifying the applied current, a constant voltage portion for converting the applied alternating current into a direct current, and a control portion for sensing whether the operation keys for instructing operation are pushed, A sensor input section for receiving a signal of installed sensors and generating a signal corresponding thereto and setting an input value to the sensors, an oscillating member having a ceramic oscillator for oscillating, A display member including an LED display unit displaying a time and a temperature, and a condition display unit displaying time and temperature; A heating element which is capable of changing the temperature by a hot wire, the bimetal being set at 105 degrees to prevent over-temperature, and the time to provide heat not exceeding 8 hours, and the output current is 0.5 milliampere (mA) And the operation time is limited to 20 minutes, and the potential member generating the potential due to the negative potential, and the output magnetic member having the maximum output power of 40 Gauss (Gauss) , An electromagnetic member which is set so as not to generate an output even when power is turned on again after a power failure and is limited to an operation time of 20 minutes and generates a text magnetic field by a magnetic field coil, When the bolt is supplied, key input, sensor input, etc. are read in the programmed contents to control the temperature, Controls to shut off the power supply to the heating member when the actual temperature rises above the temperature set in the heating member, and controls the current to be cut off when the overcurrent flows through the heating member, and the heating member and the potential member And a control member for controlling the heating member and the electromagnetic member so as not to operate at the same time, and controlling the heating member and the electromagnetic member to not operate at the same time.

According to the multimeter type compound electronic automatic control apparatus of the present invention, it is possible to simultaneously provide a heat effect by heat, a potential effect by the generation of a negative potential, and a medical electromagnetic generation effect by a coil, Thereby relieving muscle pain, and has an effect of helping blood circulation.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

1 is a block diagram showing a configuration of a multi-meger type hybrid electronic automatic control apparatus according to an embodiment of the present invention;
2 is a circuit diagram showing a main configuration of the multimeter type hybrid electronic automatic control apparatus shown in Fig. 1
3 is a circuit diagram of a power supply member portion of the multi-mer type hybrid electronic automatic control apparatus shown in Fig. 1
Fig. 4 is a circuit diagram showing a grounding method of the multi-mer multiple electronic automatic control apparatus shown in Fig. 1
5 is a diagram showing a circuit diagram of an electromagnetic member of the multimeter type hybrid electronic automatic control apparatus shown in Fig. 1
6 is a diagram showing a circuit diagram of a potential member of the multimeter type hybrid electronic automatic control apparatus shown in Fig. 1
7 is a diagram showing a circuit diagram relating to the power of the multi-mer multiple electronic automatic control apparatus shown in Fig. 1

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram illustrating a configuration of a multi-mer multiple electronic automatic control apparatus according to an embodiment of the present invention. Referring to FIG. 1 through FIG. 7, Fig. 2 is a circuit diagram showing a main configuration of the multi-mer multiple electronic automatic control apparatus shown in Fig. 1. Fig. 3 is a schematic diagram of a multi-mer electronic automatic control apparatus shown in Fig. Fig. 4 is a circuit diagram showing a grounding method of the multi-mer multiple electronic automatic control apparatus shown in Fig. 1. Fig. 5 is a diagram showing a circuit diagram of the multi- FIG. 6 is a circuit diagram of a potential member of the multimeter type hybrid electronic automatic control apparatus shown in FIG. 1, and FIG. 7 is a circuit diagram of the electromagnetic member of the multi- Type complex electronic control station A shows a diagram illustrating a circuit diagram related to a power respectively.

As shown in the drawings, a multi-meger type hybrid electronic automatic control system 100 according to an embodiment of the present invention includes a power source member 10, an oscillating member 20, a display member 30, An electromagnet member 60, and a control member 70. The electromagnet member 60 and the control member 70 constitute a control unit.

The power supply member 10 includes an AC input unit 11 to which an AC current is applied, a power switch unit 12 that allows and blocks the flow of electrical energy, and a down-transformer unit 13, a rectifying section 14 for rectifying the applied current, and a constant voltage section 15 for converting the applied alternating current into direct current.

The oscillating member 20 includes a key input unit 21 for sensing whether the operation keys indicating operation are pushed and for generating a signal corresponding thereto, and a control unit 20 for receiving signals of installed sensors and outputting signals corresponding thereto, A sensor input section 22 capable of setting an oscillation frequency, and a ceramic oscillator 23 oscillating.

The display unit 30 includes an LED display unit 31 for displaying an operation state according to an input of a key, and a condition display unit 32 for displaying time and temperature.

The temperature of the heating member 40 can be changed by a hot wire. The temperature of the bimetal is set to 105 degrees to prevent overheating, and the time for providing heat does not exceed 8 hours.

The output current of the potential member 50 does not exceed a maximum of 0.5 milliampere (mA), and the output is not generated even when the power is turned on again after the power failure. The operation time is limited to 20 minutes, A potential is generated.

The electromagnetic member 60 is set so that the output magnetic force does not exceed 40 Gauss maximum and the output is not generated even when the power is turned on again after the power failure. The operation time is limited to 20 minutes, To generate a text magnetic field.

The control member 70 stores the program. When the DC 5 volts is supplied, the control member 70 reads the key input, the sensor input, and the like with the programmed contents to control the temperature and control the contents displayed on the display member 30, Controls the power supply to the heating member 40 to be cut off when the actual temperature rises above the temperature set in the heating member 40 and controls the current to be cut off when the overcurrent flows through the heating member 40, And the potential member 50 are not operated at the same time, and controls the heating member 40 and the electromagnetic member 60 so that they do not operate simultaneously.

The multi-mimic-type hybrid electronic automatic control apparatus 100 having the above-described configuration according to the embodiment of the present invention is used as follows.

First, when the power is input, power is supplied through the connection terminals Jupiter 4 (JP4) - S W 1 (SW 1) - Current fuse F 1 (F 1) and F 2 (F 2) When the power is supplied, the other side is a push type, and it is judged which line of the input two lines is a neural line.

If you press and release SW1, the C2 of the simple power section of the electromagnetic wave section will be operated as the charging current for about 5 seconds because it is a large capacity, and the input power section and the main body are completely insulated. If the line is connected to the neutral line of the two input lines, the power source of the grounding circuit operation unit is at the ground potential, so that the input signal does not exist and the ground check LED 1 is not turned on In case of non-neural live line, AC potential difference occurs, so OP AMP operates and lights up.

In this case, connect the pin of the power plug to the left and right, and repeat the above operation again, LED1 will not operate and the user will know that the input line is properly connected.

This is a grounding potential checking device that matches the negative power supply of all the operating power sources of the main unit with the neutral line of the AC input line, so that the user does not cause electrostatic phenomenon during use.

The next operation turns on the power switch SW1 and is applied to the operating power source through the power supply filters TNR1-C12-L2-power transformer T2. AC1 and AC2 of the applied power line are supplied to the heating wire and the heater 1 non-contact switch Q16, and the voltage passing through the power transformer is converted into DC 5V and 12V, and supplied to the CPU and the negative potential portion and the relay portion, respectively.

The operation buttons consist of temperature, heat, electromagnetic, potential and time control. Each button is connected to the CPU IC1 through the CPU IC1 and the resistance of each R0-R14. .

Since the left and right functions are the same as the user selecting the left or right functions, the description will be made with reference to the left side.

When the warm button is pressed, the IC1 recognizes the warm signal and outputs to the temperature display FND1. The temperature is set by pressing the temperature rising or falling button. IC1 compares the voltage inputted from the temperature sensor mounted in the interior of the brush with the signal inputted through the internal connector terminal-relays RY1-R24 to the pin 23 and the set voltage and outputs the operation signal at the pin 16 until the set temperature, PC817 is turned on and the porcelain coupler K3021 is operated and power is supplied to the heating wire inside the bolt in the order of AC1-TRIAC Q16-RY2-internal connector-heating wire H1-HC-RY3-AC2.

When the temperature reaches the temperature, the temperature sensor built in the probe is NTC type. Therefore, the resistance becomes smaller and the sensor input voltage becomes lower. Since the sensor 23 is input to the pin 23 of the internal sensor-internal connector -RY1-R24-IC1, 16, the output signal is turned off and the power supply to the triac Q16 is interrupted.

As the repetition of this type, the temperature is controlled and the temperature is automatically set to 8 hours. When the set time is reached, all functions are turned off and the system waits for the initial state again.

When the user presses the electromagnetic button, the signal is input to IC1 and the output signal is supplied in the order of pin 18-PC817 (ISO 3) -RY4- internal connector - electromagnetic generator - internal connector -RY3-AC2 .

At this time, the operation is performed for 20 minutes, and then the output is stopped.

When the user presses the electric potential button, the signal is input to IC1 and the potential output signal is output from pin 17. This signal is applied to the porter coupler PC817 (ISO2) -ISO5-RY3 so that 12 volts DC is applied to the potential RY1, RY2, RY3, and RY4 are activated by this signal, so that the heating wire, the temperature sensor, and the electromagnetic generating device inside the reference are disconnected.

At this time, the power source applied to the electric potential circuit is applied with 12 volts DC through RY6, and the residual circuit is operated. The output is applied to the potential plate of the electric current limiting resistor R40-RY6 in the order of the internal connector.

When 12 volts DC is applied to the negative potential circuit, a signal is input to the base of TR Q1 through the high-voltage transformer T1, and the signal induced in the high-voltage transformer is input to the base of Q2 due to the operation of Q1, The high frequency of about 10 Kh is oscillated by the C1 of the transformer L and the high voltage of about 380 Vmean or more occurs on the secondary side due to the primary and secondary winding ratios.

Since this output is a high-frequency high-voltage, a high-voltage diode D1 is connected to the output terminal of the high-voltage capacitor C3 in the reverse direction to generate a negative output. The output of the high-voltage diode D1 is applied to the potential plate .

At this time, since the maximum time is set to 20 minutes, the function is stopped after 20 minutes.

10. Power supply absence 11. AC input
12. Power switch part 13. Down transformer part
14. Rectifying part 15. Constant voltage part
20. Oscillating member 21. Key input unit
22. Sensor Input Section 23. Ceramic Oscillator
30. Display member 31. LED display unit
32. Condition display unit 40. Heating member
50. Electrostatic member 60. Electromagnetic member
70. absence of control

Claims (1)

An AC input section 11 to which an AC current is applied, a power switch section 12 that allows and blocks the flow of electric energy, a down-transform section 13 that reduces the number of volts of the applied AC current, A power supply member (10) having a rectifying part (14) for rectifying the applied alternating current and a constant voltage part (15) for converting the applied alternating current into a direct current;
A key input unit 21 for sensing whether the operation keys indicating operation are pressed and generating a signal corresponding thereto, a sensor input unit 21 for receiving signals of installed sensors and outputting signals corresponding thereto, and setting input values to the sensors An oscillating member (20) having a ceramic oscillator (22) and an oscillating ceramic oscillator (23);
A display member (30) including an LED display portion (31) for displaying an operation state according to an input of a key, and a condition display portion (32) for displaying time and temperature.
A heating member 40 capable of changing the temperature by a hot wire, the bimetal being set at 105 degrees to prevent over-temperature, and the time for providing heat not exceeding 8 hours;
The output current is set so as not to exceed 0.5 milliampere (mA) maximum and the output is not generated even after the power is turned on again after the power failure. The operation time is limited to 20 minutes and the potential member 50);
The output magnetic field is set so as not to exceed 40 Gauss maximum and the output is not generated even when the power is turned on again after the power failure. The operation time is limited to 20 minutes, and the magnetic field generated by the magnetic field coil (60);
And controls the temperature and the contents displayed on the display member 30 by reading the key input, the sensor input, and the like with the programmed contents when the DC 5 volts is supplied, The heating member 40 and the potential member 50 are controlled so as to shut off the power supplied to the heating member 40 when the actual temperature rises and to shut off the current when the overcurrent flows through the heating member 40, And a control member (70) for controlling the heating member (40) and the electromagnetic member (60) so that the heating member (40) and the electromagnetic member (60) are not operated at the same time.

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