KR980010229A - Fan heater overheat controller - Google Patents

Abstract

The present invention relates to an apparatus for controlling the overheating of a fan heater, wherein when a vaporization duct is overheated, the thermoelective sensing element is switched to an off state so that a high level signal is provided to the microcomputer, and the microcomputer controls the first relay The switching control signal S _RY1 for switching to the off state is provided to the first relay RY1 so that the external power provided from the external power supply is cut off and the driving of the fan heater is stopped and based on the display control signal from the microcomputer The superheat of the vaporization duct is displayed on the display unit and switched to the first SSR (SSR1) and the second SSR (SSR2) ion state based on the switching control signals S _B and S _F from the microcomputer, FM) is driven so that the burner is cooled by the outside air, and the vaporizing duct is cooled, so that the external power supplied to the fan heater is blocked at the time of overheating of the vaporizing duct, So that the user can judge if the fan heater is not driven due to overheating of the vaporizing duct.

Description

Fan heater overheat controller

An object of the present invention is to provide a fan heater for a fan heater which is suitable for cooling the fan heater when the fan heater is overheated by detecting an overheated state of the fan heater (for example, overheating of the burner or the vaporizing duct) .

Generally, a fan heater is a device in which liquid fuel (for example, petroleum, kerosene, etc.) from a fuel tank provided by driving of an electromagnetic pump is vaporized through a heater preheated to about 280 ° C and then burned through a burner to generate heat Next, it refers to a type of heating device that discharges the gas to the outside through a vaporizing duct.

At this time, the liquid fuel supplied from the fuel tank is mixed with the outside air provided by the driving of the blow motor to be supplied to the heater, and the heat generated by burning through the burner is supplied to the outside through the vapor duct by driving the fan motor.

On the other hand, when the fan heater is overheated (for example, when the burner or the vaporizing duct is overheated) in which heat generated by burning the fuel through the burner is supplied to the outside through the vaporizing duct, the electronic component or element in the fan heater is damaged Or a fire occurs due to overheating.

As an apparatus for preventing the overheating of the fan heater, there is a conventional conventional fan heater overheating prevention apparatus as shown in FIG.

3, the external power supply V provides an external power source necessary for driving the fan heater. At this time, the capacitor C removes the normal noise of the external power supplied from the external power supply V, The thermoelectric sensing element (TH) is mounted on a predetermined portion of the vaporizing duct and is switched according to the temperature of the vaporizing duct to provide or shut off external power supplied to the fan. More specifically, the temperature of the vaporizing duct is set to a predetermined value 70 ° C.), the external power is supplied to the fan heater, and when the temperature of the vaporization duct exceeds a preset predetermined temperature (70 ° C.), it is switched to the off state to shut off the external power supplied to the fan heater.

A low voltage transformer (hereinafter referred to as LVT) transforms an external power supply from an external power supply provided through a condenser C and a thermoelectric sensing element TH, thereby driving a microcomputer The first relay RY1 is switched on the basis of a switching control signal S _RY1 from a microcomputer (not shown) to supply external power supplied from the external power supply to the heater H and the electronic pump EP, And the second relay RY2 is switched on the basis of the switching control signal from the microcomputer to supply or cut off the external power supplied from the external power source to the heater H. [

Further, the blow motor BM and the fan motor FM are supplied from the external power supply V when the first solid state relay (SSR) and the second SSR (SSR2) are turned on The first SSR (SSR1) and the second SSR (SSR2) are switched on the basis of the switching control signals (S _B , S _F ) from the microcomputer or when the control signal is not inputted from the microcomputer State.

The blow motor (BM) is driven on the basis of the external power source of claim 1SSR (SSR1) on the basis of the switch control signal (S _B) from the microcomputer is provided is turned on providing a fan heater to the outside air at the time of combustion and the The fan motor FM is driven based on the external power source supplied with the second SSR (SSR2) turned on in response to the switching control signal S _F from the microcomputer, so that the heat generated during the combustion is supplied through the vaporizing duct To the outside.

The operation of the conventional fan heater overheating prevention device including the above-described components will be described in detail with reference to FIG.

First, when an operation signal is input from a key operation means (not shown) based on a user operation signal, the first relay RY1 is switched to the ON state based on the switching control signal S _RY1 from the microcomputer, EP and the heater H are supplied with external power from the external power supply V and the second relay RY2 is switched on based on the switching control signal S _RY2 from the microcomputer, An external power source from the supply V is provided to the heater H. [

The first SSR SSR1 and the second SSR SSR2 are turned on based on the switching control signals SB and SF from the microcomputer so that the external power supplied from the external power supply V is supplied to the blow motor BM, And the fan motor FM, respectively, so that the blow motor BM and the fan motor FM are driven.

At this time, if the heater is preheated to about 280 ° C to 290 ° C, the second relay RY2 is switched to the off state based on the switching control signal S _RY2 from the microcomputer.

Then, the electromagnetic pump EP is driven on the basis of the external power supplied from the external power supply V to vaporize the liquid fuel from the fuel pump through the heater H, Air is mixed with air and burned through the burner, and the generated heat is supplied to the outside through the vaporizing duct by driving the fan motor (FM).

Meanwhile, when the temperature of the vaporization duct increases to exceed a preset predetermined temperature (70 deg. C), the thermoelectric sensing element 120 mounted on the predetermined portion of the duct is switched to the off state, and the external power supplied to the LVT, The power supplied to the electronic pump EP and the heater H is cut off through the first relay RY1 and the second relay RY2 and the predetermined power for driving the microcomputer provided from the LVT to the microcomputer is shut off, Do not.

Therefore, since the control signal is not supplied from the microcomputer, the first SSR (SSR1) and the second SSR (SSR2) are switched on, and the blow motor BM and the fan motor FM is driven and the burner is cooled by the external air provided by the drive of the blow motor BM and the vapor duct is cooled by the driving of the fan motor FM.

Then, when the vaporization duct is cooled to a temperature lower than a preset predetermined temperature (70 ° C), the thermoelectric sensing element mounted on the predetermined portion of the vaporization duct is switched to the on state, and the external power is supplied to the LVT, And is switched from the key input means to the standby state for receiving the operation signal.

However, when the thermoelectric sensing element TH is turned off due to overheating of the fan-heater, that is, due to overheating of the burner or the vaporization duct, the display of the fan-heater is not shown, so the user can not grasp the cause There is a problem.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a device for controlling overheating of a fan heater, which can display an overheated state of a fan heater, have.

To achieve the above object, according to the present invention, an electronic pump is driven on the basis of a drive signal based on an external operation signal so that liquid fuel from a fuel tank is supplied to a heater and is vaporized, The fan heater is installed in a predetermined portion of the vaporizing duct, and the temperature of the vaporizing duct is set to a predetermined temperature, for example, A logic signal generating means for generating a logic signal corresponding to a switching signal of the thermoelectrics sensing element and a logic signal generating means for generating a logic signal corresponding to the switching signal, For switching off the external power provided to the electronic pump A microcomputer for generating a control signal and a display control signal for indicating overheating of the vaporization duct, switching means for switching off external power provided to the electronic pump based on a switching control signal from the microcomputer, And a display means for indicating overheating of the vaporizing duct based on the signal.

FIG. 1 is a circuit diagram of an apparatus for controlling the overheating of a fan heat according to a preferred embodiment of the present invention; FIG.

FIG. 2 is a schematic block diagram of an apparatus for controlling overheating of a fan heat according to a preferred embodiment of the present invention; FIG.

FIG. 3 is a circuit diagram of a conventional fan heat overheat prevention device. FIG.

DESCRIPTION OF THE REFERENCE NUMERALS

110: Key operating part 120: Thermoelectric sensing element

130: Microcomputer 140: Display unit

These and other objects and advantages of the present invention will become more apparent from the following description of the preferred embodiments of the present invention with reference to the accompanying drawings.

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

FIG. 1 is a schematic block diagram of an apparatus for controlling the overheating of a fan heater according to a preferred embodiment of the present invention. The apparatus includes a key operation unit 110, a thermoelectric sensing element 120, a microcomputer 130, and a display unit 140.

1, the key operation unit 110 includes a drive key and a reset key for driving the fan heater. When a corresponding key is input based on a user's operation signal, the key operation unit 110 provides a corresponding key signal to the microcomputer 130, When the temperature of the vaporization duct is less than a predetermined temperature (for example, 70 deg. C), the device 120 is maintained in an on state, and a low-level signal is supplied to the microcomputer 130 through the resistor R4 And when the temperature of the vaporization duct exceeds a predetermined predetermined temperature (70 DEG C), it is switched to an OFF state and a high level signal is provided to the microcomputer through the resistor R3.

The microcomputer 130 sends a switch control signal S _RY1 for providing power to the electric motor EP and the heater H to the first relay _RY1 based on the drive key signal from the key operation unit 110 And generates a switching control signal S _RY2 for preheating the heater H to the second relay RY2.

The microcomputer 130 generates a switching control signal S _F for driving the fan motor by generating a switching control signal S _B for driving the blow motor BM in the first SSR SSR1 at the time of burning the fan heater The microcomputer 130 generates a control signal for indicating overheat of the vaporizing duct when a high-level signal provided for switching the thermoelectric sensing element 120 is input.

1, the display unit 140 is a display device such as an LCD (Liquid Crystal Display) or an LED (Light Emission Diode), and displays an overheated state of the vaporization duct based on a display control signal from the microcomputer 130. 2 is a circuit diagram of an apparatus for controlling the overheating of the fan heater according to the present invention. The apparatus includes an external power supply V, an LVT, a first relay RY1, a second relay RY2, an electronic pump EP, H, a blow motor BM, and a fan motor FM.

Here, each constituent member of the circuit diagram for the fan heater overheating control apparatus according to the present invention shown in Fig. 2 and each constituent member of the circuit diagram for the conventional typical fan heater overheating prevention apparatus shown in Fig. 3 described above is substantially So that the description here will be omitted in order to avoid redundant descriptions.

1 and 2, and a conventional fan heater overheat prevention apparatus shown in FIG. 3, the difference is that the thermoelectrically sensitive element TH is turned on and off A predetermined power source for driving the microcomputer 130 is provided to the microcomputer 130 from the LVT and the switching state of the thermoelective sensing element 120 is sensed through the microcomputer 130 to perform a corresponding function, ) Indicates the overheating state of the vaporizing duct.

Accordingly, the following description focuses on the operation process of these constituent members.

First, when the drive key is operated from the key operation unit 110 based on the operation signal of the user, the external power from the external power supply V is supplied to the electronic pump EP (EP) based on the drive key signal from the key input unit 110, And generates switching control signals S _RY1 and S _RY2 to be supplied to the heater H and the first relay RY1 and the second relay RY2 respectively.

The first relay RY1 is switched to the ON state based on the switching control signal S _RY1 from the microcomputer 130 and is supplied to the external power supply V from the external power supply V via the electromagnetic pump EP and the heater H, The second relay RY2 is switched to the ON state on the basis of the switching control signal S _RY2 from the microcomputer 130 and is supplied from the external power supply V Is provided as an external pre-heater (H) and the heater (H) is preheated.

Next, the heater H is preheated and the liquid fuel supplied from the fuel tank (not shown) is vaporized by the drive of the electromagnetic pump EP through the heater H, and then supplied by the drive of the blow motor BM And heat is generated through the burner to generate heat. Heat generated from the burner by the driving of the fan motor FM is supplied to the outside through the vaporizing duct. The second relay RY2 is switched to the OFF state based on the switching control signal S _RY2 from the microcomputer 130 to be heated to the heater H The external power from the provided external power supply V is cut off.

When the temperature of the vaporization duct increases to exceed a preset predetermined temperature (70 deg. C), that is, the thermoelectric sensing element 120 mounted on a predetermined portion of the vaporization duct is switched to the off state, The microcomputer 130 generates a switching control signal S _RY2 for turning off the first relay RY1 based on the high level signal and generates a control signal S _RY2 for indicating overheating of the vaporizing duct, .

The first relay RY1 is switched to the OFF state based on the switching control signal S _RY2 from the microcomputer 130 so that the external power from the external power supply V provided to the electronic pump EP is cut off And the overheat of the vaporizing duct is displayed through the display unit 140 based on the display control signal from the microcomputer 130. [ For example, a text message is displayed on the LCD or an LED corresponding to an overheating of the vaporizing duct is emitted.

At this time, based on the switching control signals S _B and S _F from the microcomputer 130,

The blower motor BM and the fan motor FM are driven so that the overheating of the fan heater H is cooled by switching the first SSR1 and the second SSR2 to the ON state. The burner is cooled based on the air and the vapor duct is cooled by the driving of the fan motor.

When the vaporization duct is cooled to a temperature lower than a predetermined temperature (70 ° C), the thermoelectric sensing element 120 is switched to the on state and a low level signal is provided to the microcomputer 130. Based on the low level signal, The first relay RY1 generates a switching control signal S _RY1 for switching the first relay RY1 to the ON state.

The first relay RY1 is switched to the ON state based on the switching control signal S _RY1 from the microcomputer 130 so that the external power from the external power supply V is supplied to the electronic pump EP, (130) is switched from the key operation unit (110) to a standby state for receiving a key signal.

When the user presses the reset key through the key operation unit 110, a reset key signal is supplied to the microcomputer 130 from the key operation unit 110 and a switching control signal S (i) of the microcomputer 130 based on the reset key signal from the key operation unit _RY2 ), the heater H is preheated, the liquid fuel supplied from the fuel tank is vaporized through the heater, then mixed with the external power supplied by the drive of the blow motor BM, and burned through the burner to generate heat And the heat generated from the burner by the driving of the fan heater (FM) is supplied to the outside through the vaporizing duct, whereby the fan (FM) is driven.

As described above, when the vaporization duct is overheated, the thermoelectrics sensing element 120 is switched to the OFF state, and a high level signal is provided to the microcomputer 130. Based on the high level signal, the microcomputer 130 controls the first relay The switching control signal SRY1 for switching the RY1 to the OFF state is provided to the first relay RY1 to shut off the external power supplied from the external power supply V to stop the operation of the fan heater, from the basis of display control signals in overheating of the vaporization duct it is shown in the display 140 of the 1SSR on the basis of the switching control signal (S _B, S _F) from the microcomputer (130) (SSR1) and the 2SSR (SSR2) The blow motor BM and the fan motor FM are driven so that the burner is cooled by the outside air and the vaporizing duct is cooled.

Therefore, according to the present invention, since the external power supplied to the fan heater is cut off when the vaporizing duct is overheated and the overheat of the vaporizing duct is displayed, the user can judge that the fan heater can not be driven due to overheating of the vaporizing duct. .

Claims (4)

The electronic pump is driven based on the drive signal based on the external operation signal to cause liquid fuel from the fuel tank to be supplied to the heater to be vaporized and then mixed with external air provided by driving the blow motor to burn through the burner A fan heater for supplying heat to the outside through a vaporizing duct by driving a fan motor, the fan heater being mounted on a predetermined portion of the vaporizing duct and generating a switching signal corresponding to the predetermined temperature when the temperature of the vaporizing duct exceeds a predetermined temperature A thermoelectric sensing element; A logic signal generating means for generating a logic signal corresponding to the switching signal of the thermoelectric sensing element; A microcomputer for modifying a switching control signal for shutting off external power provided to the electronic pump based on a logic signal corresponding to the switching signal to the thermoelectric sensing means and a display control signal for indicating overheat of the vaporization duct; And display means for displaying overheating of the vaporization duct based on a switching display control signal from the microcomputer. The fan heater overheating control apparatus according to claim 1, wherein the switching means is a relay. The fan heater overheating control apparatus according to claim 1, wherein the display means is an LCD. The fan heater overheating control device according to claim 1, wherein the display means is an LED. ※ Note: It is disclosed by the contents of the first application.