KR101124427B1 - Control circuit for pre-heater of vehicle - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a preheater control circuit for automobiles. In the case of using a PTC heater in a hybrid vehicle, a high voltage 300V voltage is applied to a PTC heater through a switching element, and a PWM signal is generated by the microprocessor. When the low voltage 12V for the general vehicle and the high voltage 300V for the hybrid vehicle are applied to the circuit part, the risk of secondary accident due to the high voltage is concerned when a short circuit occurs. Therefore, in the present invention, the PWM drive is applied to the pulse generator, the output of the pulse generator to the primary side and the transformer for outputting the pulse drive signal on the secondary side, the light emitting element driven by the PWM signal of the microprocessor and the two of the transformer And a photocoupler made of a light receiving element which is driven by the light emitting element to receive the difference side output and outputs a PWM control signal to the switching element, and is configured to shield the low voltage and the high voltage by separating the primary side and the secondary side. By doing so, there is a feature in the configuration to ensure the safety.

Automotive, Hybrid, PTC Heater, PWM Control, Voltage Shield, High Voltage, Low Voltage

Description

Automotive preheater control circuit {CONTROL CIRCUIT FOR PRE-HEATER OF VEHICLE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a preheater control circuit for automobiles, and more particularly, to a preheater control circuit for automobiles in which a high voltage portion and a low voltage portion are shielded from each other to ensure safety when a PTC heater is applied to a hybrid vehicle.

In general, a vehicle is provided with a heating device that uses the heat energy of the cooling water warmed by the heat generated by the engine for heating the interior of the vehicle or dehumidifying or defrosting the windshield of the vehicle.

Such a heating device has a long time until the cooling water is heated and the room is heated because the cooling water flowing around the engine flows into the heater after the engine is operated. Accordingly, there was a disadvantage in that the cold state for a certain time after starting.

Recently, various types of preheaters have been developed to solve such problems, and a typical example is a preheater incorporating a positive thermister coefficient (PTC) element.

In order to drive the PTC preheater as described above, a PTC (Pulse With Modulation) signal is controlled by a microprocessor to drive the PTC heater.

1 is a preheater control circuit diagram according to the prior art, as shown therein,

A microprocessor (1) for generating a PWM (Pulse With Modulation) signal for PTC control; A PWM drive (2) for generating a switching drive signal by the PWM signal of the microprocessor (1); A switching element (3) for switching the battery power supply to the PTC heater (4) by the control of the PWM drive (2); The fault detection unit 5 is configured to detect a drive current of the PTC heater 4 driven by battery power supplied by the switching element 3 and feed it back to the microprocessor 1.

The preheater control circuit according to the related art generates a heat by flowing a current through the PTC heater 4, and a MOSFET or an IGBT element is used as the switching element 3 for current control. In order to drive the MOSFET or IGBT element, which is the switching element 3, the microprocessor 1 generates a PWM signal and switches the switching element 3 through the PWM drive 2 to control the flow of current. .

At this time, power is applied to the gate terminal of the MOSFET or IGBT element, which is the switching element 3, and the input power of the MOSFET or IGBT element, which is the switching element 3, and the microprocessor 1 and the PWM drive 2 used. The input power is all connected to the power of one battery and to ground.

Also, countermeasures against faults, short circuits, and disconnections at overvoltages and undervoltages of the heater are prepared. The fault detection unit 5 detects the driving state of the PTC heater 4 and feeds it back to the microprocessor 1 so that the microprocessor ( When 1) detects a fault condition and a fault occurs, the microprocessor 1 avoids the fault by stopping the output of the PWM signal, that is, stopping the driving of the switching element 3 to prevent a secondary accident such as a fire. .

However, as described above, the microprocessor 1, the PWM drive 2, the switching device 3, the PTC heater 4, and the closed loop (CLOSE-LOOP) form connected to the fault detection unit 5 are all composed of one circuit. To control it. In other words, the ground is connected using the same ground despite the fact that the used voltage is different from the low voltage 12V and the high voltage 300V.

On the other hand, the input power of the PTC heater system of a hybrid vehicle is very different from the power configuration of the PTC heater system of a general automobile. When the conventional preheater control circuit as described above is applied to the PTC heater system of the hybrid vehicle, the high battery power of 300 V or more of the hybrid vehicle is connected to the PTC heater 4. The control and sensing circuits are connected to a low voltage of about 12V in a typical car. This is because it is not possible to connect a power supply higher than 300V directly to existing microprocessors and analog circuits. The shielding between the high and low power side of the hybrid vehicle system must be performed.

When the PTC control circuit as shown in FIG. 1 is applied to the PTC heater system of a hybrid vehicle without shielding treatment, when a short circuit occurs between a high voltage and a low voltage, when a high voltage is applied to the vehicle chassis due to the use of the same ground. There is a big problem that can cause injury.

Therefore, in addition to the + terminal of the power supply, the ground must also be completely separated at the power input. This separation causes some problems. It is necessary to set the driving power to the required power supply at the gate end of the MOSFET or IGBT device, which is the switching device at the high voltage stage, and to transmit the fault detection signal to the microprocessor 1 regardless of the potential. It must be.

An object of the present invention is to provide a switching element by generating a PWM signal in a microprocessor and a high voltage power supply supplied to a PTC heater in a PTC heater control circuit of a hybrid vehicle that generates a PWM signal in a microprocessor to control a current of the PTC heater. The present invention is to provide a preheater control circuit for automobiles that shields a low voltage power supply to drive to secure protection and safety of the control circuit.

The present invention transmits a PWM signal applied to a gate end of a switching element of a PTC heater to a switching element through a transformer and a photocoupler for PWM transmission, and reliably separates the ground ends of the primary side and the secondary side to form a high voltage and a low voltage. To shield the circuit.

The object of the present invention as such,

A microprocessor for generating a PWM signal for PTC control; A PWM drive generating a switching drive signal by the PWM signal of the microprocessor; A switching element for switching a battery power supply to a PTC heater by controlling the PWM drive; In the pre-heater control circuit for automobiles comprising a fault detection unit for detecting the drive current of the PTC heater driven by the switching element is driven by the switching element and fed back to the microprocessor,

The PWM drive,

A pulse generator for generating a constant pulse;

A transformer for receiving a pulse signal of the pulse generator on a primary side and generating a drive signal on a secondary side;

A light-emitting device driven by the PWM signal of the microprocessor, and a photo-coupler for transmitting a PWM signal for outputting a gate driving signal of the switching device by receiving the secondary output of the transformer and receiving the light;

The pulse generator of the PWM drive and the light emitting device of the transformer primary side and the photocoupler are connected to the ground terminal of the low voltage circuit, and the secondary side of the transformer and the PTC heater are configured to be connected to the ground terminal of the high voltage circuit. And a high voltage circuit portion separately configured.

As described above, the present invention is configured to drive a PWM control signal of a microprocessor as a gate driving signal of a switching element using a transformer and a photo coupler in a car preheater control circuit for driving a PTC heater using a high voltage for a hybrid vehicle. Therefore, the ground terminal on the primary side and the secondary side are separated and reliably separated from the low voltage and the high voltage. Therefore, the high voltage and low voltage circuit parts of the hybrid vehicle are completely shielded. Accordingly, it is possible to secure safety, and by using a transformer to apply the gate-end drive signal of the switching element as a PWM signal, there is an effect that can be supplied at a sufficient gate drive voltage.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a circuit diagram of a preheater control circuit for automobiles according to the present invention.

A microprocessor (1) for generating a PWM signal for controlling the PTC heater (4); A PWM drive (100) for generating a switching drive signal by the PWM signal of the microprocessor (1); A switching element (3) for switching the battery power supply to the PTC heater by the control of the PWM drive (100); In the pre-heater control circuit for automobiles comprising a fault detection unit (5) for detecting the drive current of the PTC heater (4) driven by the switching element (3) is driven by the battery power supply and fed back to the microprocessor (1) In

The PWM drive 100,

A pulse generator 110 for generating a constant pulse;

A transformer 120 for receiving a pulse signal of the pulse generator 110 on a primary side and generating a drive signal on a secondary side;

The light emitting device 131 driven by the PWM signal of the microprocessor 1 and the second output of the transformer 120 are applied to the light receiving device 132 to drive the gate of the switching device 3. It is composed of a photocoupler 130 for PWM signal transmission for outputting a signal,

The microprocessor 1 and the pulse generator 110 of the PWM drive 100, the primary side of the transformer 120, and the light emitting element 131 of the photocoupler 130 are the first ground which is the ground terminal of the low voltage circuit. Connected to the terminal GND1, and the secondary side of the transformer 120 and the PTC heater 4 are connected to the second ground terminal GND2 which is the ground terminal of the high voltage circuit to separate the low voltage circuit part and the high voltage circuit part. It is characterized by.

The present invention configured as described above generates a PWM signal for driving the PTC heater 4 in the microprocessor 1. Although the PWM signal for driving the PTC heater 4 is not shown in the figure, the PWM signal for driving the PTC heater 4 is automatically generated based on the detected temperature of the temperature sensor and the set temperature of the temperature operating knob. This is controlled by a general PTC heater control method, which is not described in detail in the present invention.

In the present invention, when the PWM signal generated by the microprocessor 1 is applied to the gate terminal of the MOSFET or ITBG, which is the switching element 3 for driving the PTC heater 4, the low voltage circuit portion and the high voltage circuit portion are separated. It is characteristic. For this purpose, the PWM drive 100 generates a pulse signal from the pulse generator 110 generating a constant pulse signal, and the pulse signal is applied to the primary side of the transformer 120 to drive the primary side of the transformer. Accordingly, the pulse signal corresponding to the pulse signal of the primary side is induced on the secondary side of the transformer 120 and is applied to the light receiving element 132 of the photo coupler 130.

In this case, the PWM signal generated by the microprocessor 1 is applied to the light emitting device 131 of the photocoupler 130 to drive the light emitting device 131, and according to the driving of the light emitting device 131, the light receiving device 132. ) Is driven to switch the secondary pulse of the transformer 120 to generate a PWM control signal to apply to the gate terminal of the switching element (3).

As described above, in the present invention, the low voltage circuit part and the high voltage circuit part are separated by using the transformer 120 and the photo coupler 130, and the pulse generator 110, the primary side of the transformer 120, and the photo coupler are separated. The light emitting element 131 of 130 is connected to the first ground terminal GND1, which is a ground terminal of a low voltage (eg, battery voltage of 12V of a typical vehicle) circuit, and the secondary side of the transformer 120 and the PTC heater ( The other end of 4) is connected to the second ground terminal GND2, which is a high voltage ground terminal. The high voltage 300V of the hybrid vehicle is applied to the switching device 3 to drive the PTC heater 4 by the high voltage.

Therefore, it is possible to reliably separate and shield the ground of the low voltage circuit portion and the high voltage circuit division, and control the PTC heater 4 based on the PWM signal of the microprocessor 1, but the PTC heater 4 is a high voltage (eg 300V), so that the heater can be driven with rapid temperature response.

The present invention connects the first ground terminal GND1, which is the ground terminal of the low voltage circuit, to the light emitting element 131, which is the primary side of the transformer 120 and the primary side of the photocoupler 130, and the transformer 120. The secondary and PTC heaters 4 are configured to connect the second ground terminal GND2, which is the ground terminal of the high voltage circuit, to completely isolate and shield the circuits on the primary side and the secondary side, even if a short circuit occurs in the circuit. Since it is not applied to the microprocessor side, safety can be ensured.

In addition, in the present invention, since the PWM signal is driven by using the transformer, the gate driving voltage of the switching element 3 can be sufficiently secured, and stable PWM control is possible.

1 is a preheater control circuit diagram for a vehicle according to the prior art.

Figure 2 is a motor preheater control circuit diagram according to the present invention.

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

1 microprocessor 3 switching element

4 PTC heater 5 fault detection part

100: PWM drive 110: pulse generator

120: transformer 130: photo coupler

131: light emitting element 132: light receiving element

Claims (1)

A microprocessor (1) for generating a PWM signal for controlling the PTC heater (4); A PWM drive (100) for generating a switching drive signal by the PWM signal of the microprocessor (1); A switching element (3) for switching the battery power supply to the PTC heater by the control of the PWM drive (100); In the pre-heater control circuit for automobiles comprising a fault detection unit (5) for detecting the drive current of the PTC heater (4) driven by the switching element (3) is driven by the battery power supply and fed back to the microprocessor (1) In The PWM drive 100, A pulse generator 110 for generating a constant pulse; A transformer 120 for receiving a pulse signal of the pulse generator 110 on a primary side and generating a drive signal on a secondary side; The light emitting device 131 driven by the PWM signal of the microprocessor 1 and the second output of the transformer 120 are applied to the light receiving device 132, so that the gate driving signal of the switching device 3 is provided. It is composed of a photocoupler 130 for PWM signal transmission to output the The pulse generator 110, the primary side of the transformer 120, and the light emitting device 131 of the photocoupler 130 are connected to a first ground terminal GND1, which is a ground terminal of a low voltage circuit, and the transformer 120. ) And the other end of the PTC heater 4 is connected to the second ground terminal GND2, which is the ground end of the high voltage circuit, to separate the low voltage circuit portion and the high voltage circuit portion. .

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