KR950004826Y1 - Preheating device - Google Patents

Abstract

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Description

Port protection circuit of heater

1 is a conventional circuit diagram.

2 is a port protection circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

11: micom 12: voltage detection unit

AC: AC power supply PC11, PC12: Photocoupler

POT11: port RY2: preheat relay

TRI11: Triac

The present invention is a heating device such as a petroleum fan heater that burns and heats fuel such as petroleum oil, and the power is continuously applied to a pot, which is a preheating heater for preheating the burner so that the burner can smoothly inject and completely burn fuel. It relates to a port protection circuit of the heating device to prevent damage.

Conventionally, as shown in FIG. 1, a power switch to which an AC power source AC is applied is connected to a movable terminal of a relay switch RYS1a, and a relay switch (RSS2) and a port POT1 are connected to each other. The fixed terminal b1 (a2) of the relay switch RYS1a (RYS1b) is connected to both terminals of the power supply transformer T1, respectively, and the fixed terminal a1 of the relay switch RYS1a is connected to the movable terminal of the RYS1b). Is connected to the middle terminal of the power supply transformer T1, the fixed terminal b2 of the relay switch RYS1b is connected to the triac TRI1, and the light receiving element PTR1 of the resistor R1 and the photocoupler PC1 is connected. Is connected in series with the gates of the resistors R2 and triac TR11, and in series with the 110 / 220V switching relay RY1 and the preheating relay RY2 to the microcomputer 1 controlling the operation of the heating apparatus. The connected resistor R3 and the light emitting element PD1 of the photocoupler PC1 were connected.

In the conventional circuit configured as described above, when the AC power input AC is 110V, the microcomputer 1 operates the 110 / 220V switching relay RY1 so that the movable terminals of the relay switches RYS1a and RYS1b are fixed terminals a1. Since 110V AC power is applied to the middle terminal and the other terminal of the power transformer T1, and the AC power source is 220V, the microcomputer 1 switches 110 / 220V. Since the movable terminals of the relay switches RYS1a and RYS1b are connected to the fixed terminals b1 and b2 by not operating the relay RY1, 220 V AC power is applied to both terminals of the power supply transformer T1. Therefore, the rated voltage is always input to the power supply unit regardless of the AC power source of 110V and 220V.

When the AC power source AC is 110V when the burner is preheated to burn fuel, the microcomputer 1 operates the preheating relay RY2 to connect the relay switch RYS2 and generate heat to the port POT1. If the AC power supply AC is 220V, the microcomputer 1 operates the preheating relay RY2 to connect the relay switch RYS2 and controls the photocoupler PC1 to conduct and shut off the triac TRI1. The pot POT1 is heated and the burner is preheated.

That is, when the AC power source AC is 110V, the 110 / 220V switching relay RY1 is synchronous and the movable terminals of the relay switches RYS1a and RYS1b are connected to the fixed terminals a1 and a2, respectively. 1) As the preheating relay RY2 is operated to connect the relay switch RY22, 110V AC power is applied to the port POT1 to preheat the heat generation and the burner, and thus the AC power supply AC. At 220V, the microcomputer 1 is a preheating relay because the 110 / 220V switching relay RY1 does not operate and the movable terminals of the relay switches RYS1a and RYS1b are connected to the fixed terminals b1 and b2, respectively. RY2 is operated to connect the relay switch RY2, and the phase control of the triac TRI1 is performed via the photocoupler PC1. The port POT1 has a 220V AC power supply suitable for its rated voltage of 110V. ) Is phase-controlled and applied and generates heat to preheat the burner.

However, in the conventional circuit as described above, when the switch of the preheating relay applying the AC power to the port is kept connected by fusion or the like, the AC power is continuously applied to the port to generate heat, so that the port is overheated, damaged, and disconnected. There are various problems such as shortening the service life of the product.

The present invention has been made to solve the above-mentioned conventional problems, by connecting a switch and a triac of the preheating relay to the port in series to operate the preheating relay during the preheating of the burner to continue connecting the relay switch and In addition, when AC power is 110V, the triac continues to be in a conductive state so that 110V AC power is applied to the port, and when AC power is 220V, the triac phase is controlled to make the conduction and cutoff state, while the AC is 220V. The purpose of the present invention is to provide a port protection circuit for controlling the power applied to the port by the triac even when the switch of the preheating relay is continuously connected by welding, such that the power is applied to the phase control and the port. It will be described in detail with reference to the drawings.

2 is a port protection circuit diagram of the present invention, as shown therein, the power supply according to the output signal of the microcomputer 11 for controlling the combustion operation of the heating device, and the voltage sensing unit 12 for detecting AC power (AC). 110V / 220V switching relay RY11 for selectively applying AC power to one side and an intermediate terminal of the transformer T11, and AC microcomputer 11 according to the output signal of the voltage sensing unit 12. A photocoupler PC11 indicating the level of the power source AC, a preheating relay RY12 operating in response to the output signal of the microcomputer 11 to preheat the burner, and applying an AC power source AC to the port POT11; And a photocoupler RY12 for triggering the triac TR11 connected in series with the photo POT11 according to the output signal of the microcomputer 11, and the microcomputer 11 has an output signal of the photocoupler PC11. To determine the level of the AC power supply and determine the Continue conducting the SOUILLAC (TRI11) and was adapted to be applied in the case of 220V triac (TRI11) the phase control to the AC power supply of 220V (AC) is suitably port (POT11) to 110V.

In the drawings of FIG. 2, reference numerals R11-R15 are resistors, Q11 is a transistor, TH is a temperature sensor for detecting the temperature of the burner, and B1 ⁺ and B2 ⁺ are power sources.

According to the present invention configured as described above, when the AC power input is 110V, the voltage sensing unit 12 outputs a high potential so that the transistor Q11 is turned on, and the 110 / 220V switching relay RY11 operates to relay the switch. Since the movable terminal of RYS11 is connected to the fixed terminal a11, an AC power source of 110 V is applied to the intermediate terminal of the power transformer T11, and the voltage sensing unit 12 when the AC power source AC is 220V. ) Outputs a low potential, the transistor Q11 is turned off, and the 110 / 220V switching relay RY11 does not operate so that the movable terminal of the relay switch RYS11 is connected to the fixed terminal b11, so that the AC power supply of 220V ) Is applied to one terminal of the power transformer T11 so that the rated voltage is always applied to the power supply unit regardless of the level of the AC power source AC. At this time, the photocoupler PC11 is turned on by turning on and off the transistor Q11. While operating and stopping, the level of AC power supply 110V Be informed whether 220V.

When the burner is preheated in such a state, the microcomputer 11 operates the preheating relay RY12 to connect the relay switch RYS12, and then triacs through the photocoupler PC12 according to the level of the AC power source AC. By controlling the TRI11, the port POT11 is heated.

That is, when the level of the AC power source AC is 110V, the microcomputer 11 continues to operate the photocoupler PC12 to continuously trigger the triac TRI12, so that the triac TRI11 continues to be in a conductive state. 110V AC power is applied to POT11 as it is to preheat the heat generation and the burner.

When the AC power level is 220V, the photocoupler PC12 is phase-controlled according to the phase of the AC power source AC, and the triac TR11 is phase-controlled so that it is in the conduction and blocking state. The AC power source AC is applied to the phase control and the port POT11 so as to be suitable for its rated voltage of 110V.

As described in detail above, the present invention controls the AC power applied to the port by the triac as well as the preheating relay, thereby generating heat, so that the AC power applied to the port by the triac is controlled even if the switch of the preheating relay is continuously connected by welding. This prevents the port from overheating or damage.

Claims (1)

Photocoupler for notifying the level of AC power AC to the microcomputer 11 according to the output signal of the microcomputer 11 for controlling the combustion operation of the heating device and the voltage sensing unit 12 for detecting AC power AC. PC11, a preheating relay RY12 that operates according to the output signal of the microcomputer 11 to apply an AC power source to the port POT11 when the burner is preheated, and is connected in series with the port POT11. The photocoupler PC12 which triggers the evil TR11 according to the output signal of the microcomputer 11, The microcomputer 11 determines the level of the AC power source AC by the output signal of the photocoupler PC11. In case of 110V, the triac (TRI11) continues to conduct through the photocoupler (PC12), and in the case of 220V, the triac (TRI11) is phase-controlled so that the AC power of 220V is suitable for 110V (POT11). Port protection circuit of the heating apparatus, characterized in that configured to be applied to.