KR101061772B1 - Inverter type electric mat control device - Google Patents

Abstract

The present invention relates to a technology for ensuring safe driving and economical efficiency without causing a fire or an electric shock in implementing an electric mat. The present invention includes a rectifying unit for converting a commercial power input from the outside into a DC voltage to supply to one side of the primary winding of the transformer; A trans drive controller for generating a square wave with an oscillation signal having a relatively high frequency and driving the transformer through a first transistor; A heater driving power supply unit for generating a DC voltage required for driving the heater by using an AC voltage output from the secondary winding side of the transformer, and a power supply unit for generating a DC voltage required in each unit of the system; A heater driving control unit for switching the second transistor with a driving control signal supplied from the central processing unit to drive the heating wire of the heater; A current / voltage detection unit connected to the other side of the heating wire of the heater through the second transistor to detect a voltage or a current according to a change in the resistance value of the heating wire and output a voltage of the corresponding level; A signal amplifying and comparing unit for amplifying a voltage of the detection signal output from the current / voltage detecting unit and comparing the preset reference voltage with a preset reference voltage; By a central processing unit that recognizes the temperature set by the remote controller or the temperature setting unit and outputs a driving control signal according to the heater driving control unit, and controls the output of the driving control signal according to the output signal of the signal amplification and comparing unit. Is achieved.

Description

Inverter type electric mat control device {A CONTROL APPARATUS OF INVERTER TYPE ELECTRIC MAT}

The present invention relates to a control technology of an electric mat employing an inverter driving method, and more particularly, to an electric mat control device of an inverter type to ensure safe driving and economical efficiency without causing a fire or electric shock.

In recent years, as the social structure has been gradually urbanized and the family structure has been nuclear family, various heating facilities or devices have been developed. Among them, electric mats are widely used because of their convenience in use. .

However, in the conventional electric mat, the heating wire and the sensing wire of the heater are designed to be adjacent to each other. Therefore, there has been a problem that a fire occurs due to a short circuit between the heating wire and the detection wire of the heater due to hardening phenomenon or heavy objects due to long use.

In addition, in the temperature control method, there is a problem that the response speed is slow and the stability is poor.

In addition, when there is a risk that a safety accident such as a heater heating wire is shorted, or the heat sink is overheated, there is a problem that is not vulnerable to the safety accident because it is not equipped with a function to diagnose or take measures by itself.

In addition, since the heating wire of the heater is driven by the half wave of the square wave, a lot of electromagnetic waves are generated, thereby degrading the health of the user.

Accordingly, an object of the present invention is to provide an electric mat that can be designed in a structure that is safe from fire or electric shock, and can diagnose and take a self-assessment such as a short circuit of a heater heating wire or an overheating of a heat sink.

The present invention for achieving the above object, the rectifying unit for converting the commercial power input from the outside into a DC voltage to supply to one side of the primary winding of the transformer; A trans-drive controller for switching the first transistor by generating a square wave with an oscillation signal having a relatively high frequency; A first transistor switched by the trans drive controller to drive the transformer; A heater driving power supply unit for generating a DC voltage required for driving the heater by using an AC voltage output from the secondary winding side of the transformer, and a power supply unit for generating a DC voltage required in each unit of the system; A heater driving control unit for switching and driving the second transistor by using the driving control signal supplied from the central processing unit; A second transistor switched by the heater driving control unit to drive a heating wire of the heater; A current / voltage detection unit connected to the other side of the heating wire of the heater through the second transistor to detect a voltage or a current according to a change in the resistance value of the heating wire, and output a voltage of the corresponding level; A signal amplifying and comparing unit for amplifying a voltage of the detection signal output from the current / voltage detecting unit and comparing the preset reference voltage with a preset reference voltage; And a central processing unit for recognizing the temperature set by the remote controller or the temperature setting unit, outputting a driving control signal according to the heater driving control unit, and controlling the output of the driving control signal according to the output signal of the signal amplification and comparing unit. It is characterized by the configuration.

Since the present invention senses the temperature through the other end of one heater heating wire without using a separate temperature sensing wire, there is an effect that the fire generated by the temperature sensing wire is essentially solved and the cost is reduced.

In addition, by driving the heating wire of the electric mat at a low voltage in the form of a square wave, the amount of electromagnetic waves is greatly reduced and the occurrence of fire is significantly reduced.

In addition, by immediately detecting that the heater heating wire is shorted or opened to generate a warning sound or display a warning, there is an effect that the user can immediately respond to a safety accident.

The above objects, features, and advantages will be described in detail with reference to the accompanying drawings, and thus, those skilled in the art may easily implement the present invention. In describing the present invention, when it is determined that the detailed description of the air technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing an embodiment of an inverter-type electric mat control apparatus of the present invention, as shown in this, the rectifier 1 for driving the transformer 3, the trans-drive controller 2 and the first A transistor FET1; A heater driving power supply unit 4 for converting an AC voltage output from the secondary coil side of the transformer 3 into a DC voltage of a required level and supplying the driving voltage of the heater 7 and the driving voltage of the system, respectively; Power supply unit 5; A heater drive controller (6) and a second transistor (FET2) for driving the heater (7); A current / voltage detector 8 and a signal amplifier and comparer 9 for detecting the drive level of the heater 7; A central processing unit (10) for controlling the driving of the heater driving control unit (6) to maintain the set temperature of the user requested by the temperature setting unit (14); An infrared receiver 11 for receiving an infrared signal input by a user through a remote controller, a temperature display unit 12 for displaying a set temperature, and a warning device 13 for informing a warning situation.

The rectifying unit 1 generates a DC voltage by full-wave rectifying and smoothing the commercial power (AC 110 ~ 220V) supplied from the outside, the DC voltage generated in this way is supplied to one side of the primary winding of the transformer (3).

The trans drive controller 2 generates a square wave by using an oscillation signal having a relatively high frequency (20 to 100 KHZ) required for switching driving of the first transistor FET1, and outputs the square wave to the gate of the first transistor FET1. To this end, the trans-drive control unit 2 includes an oscillator or receives an oscillation signal from the outside.

The first transistor FET1 is switched by a square wave pulse supplied from the trans drive control unit 2, and the drain thereof is connected to the other side of the primary coil of the transformer 3. Therefore, the transformer 3 is driven by the switching driving of the first transistor FET1, and a voltage having a level corresponding to the winding ratio is output to the secondary winding side thereof. The transformer 3 may be implemented using various kinds of cores (for example, iron core cores). However, the transformer 3 may be implemented using a ferrite core that operates at a relatively high frequency and is advantageous in small size, light weight, and high efficiency. .

For reference, the rectifier 1, the trans drive controller 2, the first transistor FET1, and the transformer 3 driving as described above are configurations of the inverter.

The heater driving power supply unit 4 converts an AC voltage output from the secondary winding side of the transformer 3 into a DC voltage, and converts the level of the DC voltage to a level suitable for driving the heater 7 (for example, DC 28V). ) And output to one side of the heater coil.

The power supply unit 5 converts an AC voltage output from the secondary winding side of the transformer 3 into a DC voltage, and converts the level of the DC voltage into a level required by each part of the system (for example, DC 12V). Output

The user can set the desired temperature desired by using the temperature setting switch provided in the temperature setting unit 14 or by operating the remote controller.

The central processing unit 10 recognizes the temperature set in the temperature setting unit 14, or recognizes the temperature set by the infrared signal input from the remote control through the infrared receiver 11, and then applies the heater drive control signal accordingly. Output to heater drive control part 6.

The heater driving control unit 6 generates a gate signal corresponding to the heater driving control signal supplied from the central processing unit 10 and outputs the gate signal to the gate of the second transistor FET2.

Accordingly, the second transistor FET2 is switched according to the gate signal, thereby driving the heater 7.

As a result, the temperature of the electric mat approaches the temperature set by the user using the temperature setting unit 14 or the remote controller. Thereafter, the central processing unit 10 controls the driving of the heater 7 through the following process to maintain the temperature of the electric mat and the temperature set by the user.

That is, the inherent resistance value of the heating wire of the heater 7 changes according to the driving level, and the current / voltage detection unit 8 is connected to the other side of the heating wire of the heater 7 through the second transistor FET2. Then, the voltage or the current according to the change in the resistance value of the hot wire is detected and the voltage of the corresponding level is output.

The signal amplifier and comparator 9 amplifies the voltage of the detection signal output from the current / voltage detector 8 and compares it with a preset reference voltage to output the corresponding voltage. For example, when the temperature of the electric mat exceeds a predetermined value higher than the temperature set by the user using the temperature setting unit 14 or the remote controller, the voltage of the detected amplified signal is higher than the preset reference voltage. At this time, the signal amplification and comparator 9 outputs a "low" signal.

At this time, the central processing unit 10 recognizes the "low" signal output from the signal amplification and comparing unit 9 and outputs the heater driving control signal to the heater driving control unit 6 to block the gate signal. Be sure to As a result, the switching operation of the second transistor FET2 is stopped, and thus, the driving of the heater 7 is stopped. Accordingly, the temperature of the electric mat begins to gradually decrease.

Thereafter, the CPU 10 performs the control operation at predetermined intervals. That is, when the temperature of the electric mat starts to fall and the user falls below a predetermined value below the temperature set by the temperature setting unit 14 or the remote controller, the voltage of the detected amplified signal is lower than the preset reference voltage. . At this time, the signal amplifier and comparator 9 outputs a "high" signal.

At this time, the central processing unit 10 recognizes the "high" signal output from the signal amplification and comparing unit 9 and outputs the gate signal to the heater driving control signal to the heater driving control unit 6 again. Be sure to As a result, the second transistor FET2 switches again, thereby driving the heater 7 again. Accordingly, the temperature of the electric mat starts to rise toward the set temperature again.

Thereafter, the control operation as described above is repeatedly performed to maintain the temperature of the electric mat at a temperature slightly higher or lower than the temperature set by the user.

If the heating wire of the heater 7 is short-circuited or opened, the voltage detected by the current / voltage detector 8 rapidly rises or falls, and a detection signal corresponding thereto is output. At this time, the signal amplification and comparing unit 9 amplifies the signal detected that the sharp rise or fall is converted into a signal of a form that the central processing unit 10 can recognize the central processing unit 10 To pass on.

At this time, the central processing unit 10 outputs a warning sound through the warning device 13, or flashes an emergency light (for example, LED) to allow the user to take immediate action, a safety accident such as a fire occurs Can be prevented.

Meanwhile, the CPU 10 accumulates the driving time of the heater 7 and forcibly stops the driving when the continuous driving time exceeds a predetermined time (for example, 20 hours), thereby allowing the user to use it for a long time without knowing it. When you go out with or without turning off, safety accidents such as fire are prevented from occurring.

The temperature display unit 12 is driven by the central processing unit 10 to display the temperature of the current electric mat.

Although the preferred embodiment of the present invention has been described in detail above, the scope of the present invention is not limited thereto, but may be implemented in various embodiments based on the basic concept of the present invention defined in the following Utility Model Registration Claims. Such embodiments are also within the scope of the present invention.

1 is a block diagram of an electric mat control device of the inverter method of the present invention.

*** Description of the symbols for the main parts of the drawings ***

1: rectification part 2: trans drive control part

3: transformer 4: heater driving power supply

5: power supply unit 6: heater driving control unit

7: heater 8: current / voltage detection unit

9: signal amplification and comparison unit 10: central processing unit

11: infrared receiver 12: temperature display

13: warning device 14: temperature setting unit

Claims (4)

A rectifying unit converting the commercial power input from the outside into a DC voltage and supplying it to one side of the primary winding of the transformer; A trans-drive controller for switching the first transistor by generating a square wave with an oscillation signal having a relatively high frequency; A first transistor switched by the trans drive controller to drive the transformer; A heater driving power supply unit for generating a DC voltage required for driving the heater by using an AC voltage output from the secondary winding side of the transformer, and a power supply unit for generating a DC voltage required in each unit of the system; A heater driving control unit for switching and driving the second transistor by using the driving control signal supplied from the central processing unit; A second transistor switched by the heater driving control unit to drive a heating wire of the heater; A current / voltage detection unit connected to the other side of the heating wire of the heater through the second transistor to detect a voltage or a current according to a change in the resistance value of the heating wire and output a voltage of the corresponding level; A signal amplifying and comparing unit for amplifying a voltage of the detection signal output from the current / voltage detecting unit and comparing the preset reference voltage with a preset reference voltage; And a central processing unit for recognizing the temperature set by the remote controller or the temperature setting unit, outputting a driving control signal according to the heater driving control unit, and controlling the output of the driving control signal according to the output signal of the signal amplification and comparing unit. Inverter type electric mat control device characterized in that the configuration. The apparatus of claim 1, further comprising a warning device configured to output a warning sound or display a warning sound under the control of the central processing unit when the disconnection of the heater heating wire is likely to cause a safety accident such as a fire by opening. Inverter type electric mat control device characterized in that. According to claim 1, Inverter type electric mat control device characterized in that it further comprises an infrared receiver for receiving the infrared signal of the remote control output to the user to control the driving of the mat to the central processing unit. . The inverter type electric mat control apparatus according to claim 1, wherein the transformer is formed of a ferrite core.

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