KR20160068444A - Switched Mode Power Supply - Google Patents

Abstract

The present invention relates to a switch mode power supply circuit for controlling medical appliances capable of preventing a problem of easily exploding a transformer in an area in which power is not easily supplied, and more than 30% frequencies are changed such as Cambodian, Laos, Myanmar, etc. and being applied to a medical mat. The switch mode power supply circuit for controlling the medical appliances comprises: a power inputting unit, a power blocking unit, power of a control unit, an SMPS, a first overcurrent detecting unit, a temperature sensor unit, an over temperature detection blocking signal unit, a power blocking signal unit, a second overcurrent detecting unit, DC out, a DC output unit, a temperature sensor inputting unit, a negative potential generating unit, a temperature control volume, a circuit temperature sensor unit, a button inputting unit, an FND displaying unit, and an LCD displaying device.

Description

Switched Mode Power Supply for Medical Device Control [

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a switched mode power supply (SMPS), and more particularly, to a switch-mode power supply circuit for a medical instrument control that has a stable and easy usage relationship even under unfavorable conditions .

In general, a switch mode power supply (SMPS) means a device that rectifies an input AC voltage to an input DC voltage (DC-Link voltage) and converts an input DC voltage to a DC output voltage having a different level , It is understood that such a switch mode power supply (SMPS) is used in many electronic equipment such as an adapter of a laptop computer, a battery charger of a mobile phone, and the like.

The switch mode power supply SMPS has the maximum limit current ILIM set. When the current Id flowing to the main switch in the short-circuit or overload state of the output terminal reaches the maximum limit current ILIM, By turning off the switch, the main switch of the switch mode power supply (SMPS) is prevented from being damaged due to overload or short circuit of the output terminal. This limits the maximum power delivered to the output stage, so this maximum limiting current (ILIM) plays an important role in selecting the rating of the device used in a switch mode power supply (SMPS) design .

However, even if the maximum limit current ILIM is set, the actual current Id is determined by the delay time of various elements inevitably present in the switch mode power supply SMPS, for example, The internal propagation delay time of the mode power supply (SMPS) control unit, and the turn-off delay time of the main switch.

In general, the higher the input voltage, the greater the change in current Id during the same delay time, and the rating of the circuit elements included in the switch mode power supply (SMPS) depends on the current Id when the input voltage is high Which leads to an increase in production cost.

1 is a diagram showing a current Id flowing in a main switch of a general switch mode power supply SMPS in response to a change in the input voltage Vin when the delay time Delta Time does not exist.

As the input voltage Vin changes from the low voltage V1 to the high voltage V2, the slope of the current Id flowing through the main switch becomes large. As a result, as shown in Fig. 1, t1, which is the time to reach the maximum limit current ILIM when the input voltage Vin is the low voltage V1, is the time when the input voltage Vin is the high voltage V2 Is longer than t2, which is the time to reach the maximum limit current (ILIM).

On the other hand, as shown in Fig. 1, when there is no delay time, the maximum limit current ILIM flowing to the main switch is controlled in the same manner regardless of the slope of the current Id flowing through the main switch, Is kept constant regardless of the input voltage (Vin).

2 is a graph showing a current Id flowing in a main switch of a general switch mode power supply SMPS corresponding to a change in the input voltage Vin when a delay time exists.

FIG. 2 shows a case where the delay time exists by? T, and the delay time inside the switch mode power supply SMPS is constant regardless of the variation of the input voltage Vin. At this time, since the slope at which the current Id flowing through the main switch increases according to the magnitude of the input voltage Vin, the input voltage Vin is the low voltage V1 during the delay time Δt, (V2), the amount of increase of the current Id flowing through the main switch is changed.

That is, when the input voltage Vin is the low voltage V1, the slope at which the current Id flowing through the main switch increases is relatively small as compared with the case where the input voltage Vin is the high voltage V2, The increase amount of the current Id flowing through the main switch during the period DELTA t is also smaller than when the input voltage Vin is the high voltage V2. In contrast, when the input voltage Vin is the high voltage V2, the slope at which the current Id flowing through the main switch increases is relatively large as compared with the case where the input voltage Vin is the low voltage V1, The increase amount of the current Id flowing through the main switch during the period DELTA t is also larger than when the input voltage Vin is the low voltage V1.

2, the maximum limit current ILIM2 flowing to the main switch when the input voltage Vin is the high voltage V2 is the same as the maximum limit current ILIM2 when the input voltage Vin is the low voltage V1, Which is much larger than the maximum limit current (ILIM1) flowing through the resistor. Such a difference in the maximum limit current flowing through the main switch of the primary side has a serious problem in which the maximum output power of the output stage is affected by the magnitude of the input voltage.

In order to solve such a problem of a general switch mode power supply (SMPS), recently, US Patent No. 6,674,656 and US Patent No. 6,665,197 have considered the maximum limit current (ILIM) A switch mode power supply (SMPS) including an additional circuit for constantly controlling the input voltage regardless of the magnitude of the input voltage has been proposed.

However, the switch mode power supply (SMPS) proposed in the above-mentioned U.S. Patent No. 6,674,656 and U.S. Patent No. 6,665,197 does not limit the maximum limit current (ILIM) flowing in the main switch of a general switch mode power supply (SMPS) By including an additional circuit for constant control regardless of the size, it poses an important problem that makes miniaturization and low cost of a switch mode power supply (SMPS) difficult.

Therefore, the present invention is intended to solve the problems of the conventional switch mode power supply (SMPS) and to be applied to a medical instrument, in particular, a medical mat;

It is an object of the present invention to prevent the breakdown of transformers in an unstable region such as Cambodia, Laos, Myanmar, etc. in an irregular region where the frequency fluctuates by more than 30% And more particularly, to a switch mode power supply circuit for application to a medical instrument control, particularly a medical mat, which has a more stable and easy usage relationship.

In order to achieve the above object, according to a first aspect of the present invention, there is provided a switch mode power supply circuit for controlling a medical instrument, comprising:

A second overcurrent detecting unit, a DC OUT, and a second overcurrent detecting unit. The power supply input unit, the power cutoff unit, the control unit power supply, the SMPS, the first overcurrent detecting unit, the temperature sensor unit, A DC output unit, a temperature sensor input unit, a negative potential generation unit, a temperature regulation volume, a circuit temperature sensor unit, a button input unit, an FND display unit, and an LCD display unit.

Therefore, the medical device control switch mode power supply circuit according to the present invention

In order to take power from the power source and to change the current or voltage characteristics and transmit it to the medical device, the pass transistor is repeatedly turned on / off repeatedly to vibrate between the low loss point and the high loss point, And the output voltage is rectified by the power that is continuously lost in the pass transistor, the frequency fluctuates by more than 30%, and the irregular region, for example, a bad region such as Cambodia, Laos, Myanmar, etc. So as to have a more stable and easy-to-use relationship, which provides a very useful expected effect.

1 is a block diagram of a switch-mode power supply for medical instrument control according to the present invention;
2 to 13 are circuit diagrams of respective components of a switch-mode power supply for medical-instrument control according to the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a switch mode power supply circuit for medical instrument control according to the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, with reference to the accompanying drawings, a schematic configuration of the present invention will be described.

The power supply input unit 1, the power supply cutoff unit 2, the control unit power supply 3, the SMPS 4, the first overcurrent detection unit 5, the temperature sensor unit 6, The DC output unit 11, the temperature sensor input unit 12, the negative electric-current generating unit 7, the power-off signal unit 8, the second overcurrent detecting unit 9, the DC output 10, A circuit connection is made of the circuit 13, the temperature regulation volume 14, the circuit temperature sensor unit 15, the button input unit 16, the FND display unit 17 and the LCD display unit 18 .

Here, the power input unit 1 is a circuit that supplies power required for driving a medical mat. The power input unit 1 serves to generate necessary output power from the input power. Thus, the power input unit 2, Is configured to have a functional configuration for supplying electric power of 220 V which is an AC power source for the circuit from the outside.

When the medical mats controlled by the medical device control switch mode power supply circuit according to the present invention are over-heated due to a failure or the like, or when the current supplied to the medical mat exceeds a reference value The power source of the AC 220V is cut off.

In addition, the control unit power supply 3 is configured to convert the AC 220V power input through the power input unit 1 into a DC power required for the control unit and supply the converted DC power.

In addition, the SMPS 4 converts a power source of AC 220 V input through the power input unit 1 into a DC power source, for example, a power source for operating (heating) the medical mat, for example, AC 220 V And a functional configuration.

The first overcurrent detecting unit 5 is configured to detect the overcurrent and deliver it to the MCU when the current supplied for the heating operation of the medical mat is an overcurrent.

In this case, the MCU refers to a general dedicated processor for controlling a specific system, for example, a microcontroller unit. In the present invention, such an MCU is used to control various functions and characteristics of a medical mat Memory semiconductors.

The temperature sensor unit 6 is configured to be mounted on a medical mat. The temperature sensor unit 6 is formed as a function sheet for measuring a heat generation temperature of a medical mat performing a heat generating function.

The over-temperature detection cut-off signal part 7 has a function of transmitting the over-temperature signal to the above-mentioned power cut-off part 2 when the heating temperature of the medical mat becomes over a set temperature, As shown in FIG.

The overcurrent detection signal section 8 is a circuit for detecting the overcurrent in a series of circuit configurations according to the present invention. The overcurrent detection signal is transmitted to the above-described power cut-off section 2, As shown in FIG.

The second overcurrent detecting unit 9 has the same functional configuration as that of the first overcurrent detecting unit 5 described above. The second overcurrent detecting unit 9 also has a function similar to that of the first overcurrent detecting unit 5 , And when the current supplied for the heating operation of the medical mat is an overcurrent, the overcurrent is detected and transmitted to the MCU.

The DC OUT 10 is formed in a functional configuration for generating a DC output by the operation of the above-described SMPS 4 in a series of circuit configurations according to the present invention.

The DC output unit 11 is formed to have a functional configuration that transfers the DC power output by the function of the DC OUT 10, for example, the operation of the SMPS 4, to the medical mat and flows the DC power.

The temperature sensor input unit 12 is configured to have a function of causing the thermometer sensor to detect the heat generation temperature of the medical mat and to transmit the detected heat value of the medical mat to the MCU as described above .

The negative potential generating unit 13 is formed to have a functional configuration for generating a negative potential from a medical mat according to a series of circuit control according to the present invention. When a negative potential is added to the body to stimulate the body, an anion effect occurs in the living body, thereby having a beneficial effect on body fluid, cells, nerves, and the like, and the body performs a health promoting action.

The temperature regulation volume 14 and the heating temperature of the medical mat required by the user can be adjusted in a continuously variable manner according to the selection.

The circuit temperature sensor unit 15 is configured to detect the temperature of the controller and the SMPS and to temporarily stop the SMPS when the detected temperature is overheated at a high temperature.

The button input unit 16 is formed of a functional configuration for operating functions such as power on / off for operating the medical mat, selection of the heating time of the medical mat, and generation of the negative potential.

When the temperature of the medical mat is controlled through the button input unit 16, the FND display unit 17 displays the set temperature of the medical mat as a numerical value. In addition, ), The time of the heat generation operation is displayed in numerical form.

Finally, when the medical mat is operated by a series of circuit controls according to the present invention, the LCD display 18 displays the display of the power source, the display of the time, the display of the warm-up operation relationship, The switch mode power supply circuit for medical instrument control according to the present invention is realized by the circuit connection relationship of a series of constituent elements as described above.

1: Power input part 2: Power cutoff part 3: Control part power
4: SMPS (4) 5: first overcurrent detection unit (5) 6: temperature sensor unit (6)
7: Over-temperature detection cutoff signal part 8: Power cutoff signal part 9: First overcurrent detection part
10: DC OUT (10) 11: DC output part (11) 12: Temperature sensor input part
13: Negative potential generation part 14: Temperature regulation volume 15: Circuit temperature sensor part
16: Button input unit 17: FND display unit 18: LCD indicator

Claims (1)

A power input section 1 for supplying a circuit AC power source of 220 V;
A power cut-off unit (2) for shutting off the heating mat if the heating temperature of the medical mat is excessive or the supplied current exceeds a reference value;
A control unit power source 3 for converting and supplying the AC 220 V power supplied through the power input unit 1 to the DC power required for the control unit;
An SMPS 4 for converting an AC 220 V power input through the power input unit 1 into a DC power required for a medical mat operation and supplying the DC power;
A first overcurrent detecting unit 5 for detecting an overcurrent of the medical mat and transmitting the overcurrent to the MCU;
A temperature sensor unit (6) for measuring an exothermic temperature of the medical mat;
When the heating temperature of the medical mat is over the set temperature, the over-temperature detection interrupting signal unit 7 transmits the over-temperature signal to the power interrupting unit 2 to turn off the power supply;
A power shutoff signal part (8) for transmitting an overcurrent detection signal to the power shutoff part (2) to cut off the power supply;
A second overcurrent detecting unit 9 for detecting an overcurrent of the medical mat and transmitting the overcurrent to the MCU;
A DC OUT 10 for generating a DC output by the operation of the SMPS 4;
A DC output unit 11 for transmitting the DC power outputted by the operation of the SMPS 4 to the medical mat;
A temperature sensor input unit 12 for detecting the heat generation temperature of the medical mat by the thermistor sensor and transmitting the temperature to the MCU;
A negative potential generating unit (13) for generating a negative potential on the medical mat;
A temperature adjustment volume (14) for selectively controlling the heat generation temperature of the medical mat;
A circuit temperature sensor unit (15) for temporarily stopping the SMPS (4) when the temperature of the SMPS (4) is detected to be an overtemperature;
A button input unit (16) for controlling the power on / off of the medical mat, the heat generation time, and the negative potential generation function;
An FND display unit 17 for displaying the set temperature and the heating time of the medical mat in numerical form;
And an LCD indicator (18) for identifying the display of the power source according to the operation of the medical mat, the display of the time, the display of the warm operating relationship, and the display of the negative potential operating relationship by the light emitting action. .

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