KR101823371B1 - Load fault diagnosis device for temperature and humidity controller - Google Patents

Abstract

The present invention relates to an apparatus for diagnosing a load failure of a temperature and humidity controller. According to the present invention, when a first photocoupler is turned on after a first relay is turned off to stop the driving of a heater, and a predetermined magnitude of DC power is applied to a control unit, it is determined that the heater is normal. When the first photocoupler is turned off and the predetermined magnitude of DC power is not applied to the control unit, it is determined that the heater is disconnected or failed, so a heater failure alarm is generated. In addition, when a second photocoupler is turned on after a second relay is turned off to stop the driving of a fan, and the predetermined magnitude of DC power is applied to the control unit, it is determined that the fan is normal. Furthermore, when the second photocoupler is turned off and the predetermined magnitude of DC power is not applied to the control unit, it is determined that the fan is disconnected or failed, so a fan failure alarm is generated. The apparatus of the present invention comprises: a DC power generating unit for generating and supplying DC power; a heater driving unit; a fan driving unit; a heater failure diagnosis unit; a fan failure diagnosis unit; and a control unit for controlling on/off of first and second relays.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a load fault diagnosis apparatus,

The present invention relates to a load fault diagnosis apparatus for a temperature and humidity controller, and more particularly, to a load fault diagnosis apparatus for a temperature and humidity controller that detects a failure or a break in a load and flashes an LED and generates an alarm.

Various loads used in electric devices may cause disconnection or other failure of internal circuits due to long use. Conventionally, it is not easy to take an immediate action after a break or a breakdown occurs in an electric device. Since it was usual for the operator to regularly check and check for any malfunctions, it was not possible to take immediate action in the event of a malfunction.

Also, these methods were very cumbersome and inefficient because they were dependent on human experience and manpower.

Recently, a current sensing device is inserted into a load line by a failure or non-check method of the load, and the voltage detected by the current sensing device is fed back to check for failure.

There is a method of using a resistance, a CT (CURRENT TRANS) or a hall sensor as a load current sensing method.

Specifically, when a resistor is used, the difference in detection voltage between the initial driving and the driving is great depending on the type of the load. In order to obtain the minimum detection voltage, a large-capacity device must be used. There is a lot of consumption, there is a heating problem with sensing resistance, and an excessive voltage is applied to the control IC (MICOM), which may damage the IC, so the maximum voltage applied to the IC must be controlled.

In addition, since it is costly and requires a lot of space when using a CT or Hall sensor, it is difficult to manufacture the sensor in a very small size, and it is necessary to select a sensor having a proper magnification according to the load (generally, 300: 1 or 1000: 1 magnification) As with the use of resistors, the control of the transient voltage is necessary.

The above methods are generally used when the load is 100 W or more, which is difficult to recognize when the load is small, such as a small fan.

In addition, when the secondary detection voltage is low, there is a risk of malfunction of the system due to the problem of non-recognition of CONTROL IC and risk of IC breakdown when the secondary detection voltage is high.

Japanese Patent Application Laid-Open No. 10-1998-0055123 (Method and apparatus for diagnosing faults in electrical equipment according to change of load current state)

The present invention has been made in order to overcome the above problems, and it is an object of the present invention to minimize the space use by minimizing the space usage so that it can be manufactured in a very small size and to prevent the malfunction of the CONTROL IC And to provide a load fault diagnosis device for a temperature and humidity controller that can ensure stable operation of the entire system by preventing breakage.

Specifically, when the first relay is turned off and the heater is stopped, the first photocoupler is turned on, and when the DC power of a predetermined magnitude is applied to the control unit, the heater is determined to be normal and the first photocoupler is turned off, And a heater failure alarm is generated when a DC power of a predetermined size is not applied to the heater.

When the second photocoupler is turned on while the second relay is turned off to stop the operation of the fan and the DC power of a predetermined magnitude is applied to the control unit, the fan is determined to be normal, the second photocoupler is turned off, And to provide a load fault diagnosis device for a temperature and humidity controller that determines that a fan is broken or malfunctions when a DC power of a predetermined size is not applied to generate a fan failure alarm.

In order to achieve the above-mentioned object, a load fault diagnosis apparatus for a temperature and humidity controller according to the present invention comprises: a DC power supply for generating and supplying a DC power of a predetermined size for driving a relay, part; A heater driving unit for driving the heater, which is a load, when the first relay is on, and stopping the heater when the first relay is off; A fan driving unit for driving the fan, which is a load, when the second relay is on, and stopping the fan when the second relay is off; When the first relay is turned off and the heater stops driving, the current supplied from the input AC power source flows through the heater and the first photocoupler in turn when the heater is normal, so that the first photocoupler is turned on, A heater failure diagnosis unit in which the first photocoupler is turned off when a current supplied from the input AC power source can not flow through the first photocoupler in the event of a failure; When the second relay is turned off and the fan stops driving, the current supplied from the input AC power source flows through the fan and the second photocoupler in order when the fan is normal, so that the second photocoupler is turned on, A fan failure diagnosis unit in which a current supplied from the input AC power source can not flow through the second photocoupler and the second photocoupler is turned off when the failure occurs; And controlling the ON and OFF of the first relay and the second relay with the DC power generated by the DC power generating unit and turning off the first relay and stopping the driving of the heater, when the first photocoupler is turned on When the heater is determined to be normal and the first photocoupler is turned off, the heater is determined to be broken or broken and a heater failure alarm is generated. In a state where the second relay is turned off to stop driving the fan, The controller determines that the fan is normal when the second photocoupler is turned on and generates a fan failure alarm by determining that the fan is broken or broken when the second photocoupler is turned off.

Specifically, the heater driving unit includes: a base receiving a signal for a first relay on / off from the control unit; a collector connected to the first relay; and a first transistor formed of an emitter connected to a ground side; And a first relay connected between the collector of the first transistor and the heater, wherein the fan driving unit comprises: a base for receiving a signal for a second relay on / off from the control unit; A second transistor having a collector connected to the ground and an emitter connected to the ground; And a second relay connected between the collector of the second transistor and the fan. When the controller supplies a current to the base of the first transistor and the collector and the emitter are conductive, A DC power source of a predetermined size generated in the first relay is applied to the coil of the first relay to short a contact of the first relay and then the input AC power flows through the heater and the first relay and the fuse to drive the heater, When the control unit supplies a current to the base of the second transistor to make the collector and the emitter conductive, the DC power source of a predetermined size generated by the DC power generating unit is applied to the coil of the second relay, And then the input AC power is allowed to flow through the fan, the second relay and the fuse to drive the fan.

A thermistor disposed in the DC power generator and having a resistance varying according to an ambient temperature; And a temperature setting unit for the user to input a temperature set value. The controller compares the resistance value of the thermistor corresponding to the temperature set value input by the user with the current resistance value measured using the thermistor, If the resistance value corresponding to the temperature set value is smaller than the current resistance value, it is determined that the current temperature is lower than the set value. If the collector and the emitter are conducted by supplying current to the base of the first transistor, A DC power source of a predetermined size generated by the first relay is applied to the coil of the first relay to short the contact of the first relay and then the heater is driven by allowing the input AC power to flow through the heater and the first relay and the fuse The controller increases the resistance value of the thermistor corresponding to the temperature set value input by the user, And determines that the current temperature is higher than the set value when the resistance value corresponding to the temperature set value is larger than the current resistance value and judges that the current is supplied to the base of the second transistor When the collector and the emitter are connected to each other, DC power of a predetermined magnitude generated by the DC power generator is applied to the coil of the second relay to short-circuit the contact of the second relay, The second relay and the fuse to drive the fan to lower the temperature to the set temperature.

The control unit further includes a display unit for displaying the presence or absence of failure of the heater and the fan, wherein the control unit turns on the first relay and drives the heater to raise the temperature to the set temperature, When the photocoupler is turned on, it is determined that the state of the fan is normal and the LED corresponding to the fan of the display unit is turned off. When the second photo-coupler is turned off by the fan failure diagnosis unit, The control unit turns on the second relay and drives the fan to lower the temperature to the set temperature. In the heater failure diagnosis unit, When the first photocoupler is turned on, it is determined that the state of the heater is normal and the LED corresponding to the heater of the display unit is turned off, When the first photo coupler is off in part, the state of the heater and to cut off or determines that the failure blinking the LED corresponding to the heater of the display unit, characterized in that for generating an alarm.

When the first photo coupler is turned on by the heater failure diagnosis unit in a state where both the first relay and the second relay are turned off and the driving of the heater and the fan is stopped, the controller determines that the state of the heater is normal The LED corresponding to the heater of the display unit is turned off, and when the first photo coupler is turned off in the heater trouble diagnosis unit, it is determined that the state of the heater is broken or broken and the LED corresponding to the heater of the display unit is blinked And when the second photocoupler is turned on in the fan failure diagnosis unit, it is determined that the state of the fan is normal and the LED corresponding to the fan of the display unit is turned off. In the fan failure diagnosis unit, When the photocoupler is turned off, it is determined that the state of the fan is broken or broken, and the LED corresponding to the fan of the display unit is blinked to generate an alarm And a gong.

The controller may be configured such that the first relay and the second relay are both turned off and the first photo coupler is turned off in the heater failure diagnosis unit while the heater and the fan are stopped, 2 photocoupler is turned off and both the heater and the fan are determined to be broken or broken, the LED corresponding to the heater and the fan of the display unit is blinked to generate an alarm, and the first photo coupler is turned on Or when the second photocoupler is turned on by the fan failure diagnosis unit and both of the first photocoupler and the second photocoupler are turned on or when both the first photocoupler and the second photocoupler are turned on, And the LEDs corresponding to the LEDs are kept in the OFF state.

Further, when the first relay is on, a current supplied from the input AC power source flows through the heater to the heater driving unit, and when the first relay is off, the current supplied from the input AC power source flows through the heater A heater branching section for causing the heater failure diagnosis section to flow; And when the second relay is on, a current supplied from the input AC power source flows to the fan driving unit through the fan, and when the second relay is off, a current supplied from the input AC power source flows through the fan And a fan branching section for allowing the fan branching diagnosis section to flow to the fan failure diagnosis section.

According to the present invention having the above-described configuration, the following effects can be achieved.

In the conventional method, it is necessary to select the type of the sensor according to the size of the load, and in the case of the variable load, it is difficult to discriminate the failure or the malfunction. However, Is not influenced by the variable load at all, regardless of the load size. There is no fear of malfunction. The photocoupler, which is an inexpensive component, does not use the existing expensive sensor, and the cost is reduced, Respectively.

Furthermore, if the current temperature is lower than the set temperature, the heater is turned on until the set temperature is reached. At this time, the non-operating fan is detected as faulty, and if it fails, the fan display LED flashes and the buzzer sounds, When the temperature is higher than the set temperature, the fan is turned to lower the set temperature until the set temperature is reached. At this time, if there is a malfunction of the non-operating heater, the heater display LED flashes and the buzzer sounds, Can be easily confirmed.

1 is a block diagram of an apparatus for diagnosing a load failure of a temperature and humidity controller according to the present invention.
2 is a circuit diagram of a DC power generator constituting an apparatus for diagnosing a load fault of a temperature and humidity controller according to the present invention.
3 is a circuit diagram of a heater driving unit and a fan driving unit which constitute a load fault diagnosis apparatus for the temperature and humidity controller according to the present invention.
4 is a circuit diagram of a heater failure diagnosis unit and a fan failure diagnosis unit that constitute a load failure diagnosis apparatus for a temperature and humidity controller according to the present invention.
5 shows a state where the photocoupler is turned on when the heater or the fan is normal and the DC 5V signal supplied to the control unit is supplied and the photocoupler is turned off when the heater or the fan is broken, Fig.
FIG. 6 is a flowchart of a method for diagnosing a load failure of the temperature and humidity controller according to the present invention when both the heater and the fan are in an off state and both are in an on state.
7 is a flowchart illustrating a method for diagnosing a load failure of an on / humidity controller according to the present invention, which diagnoses whether or not any other load not driven when a load of a heater or a fan is in operation is detected, It is a flowchart.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to accomplish them, will become apparent by reference to the embodiments described in detail below with reference to the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below, but may be embodied in various forms.

The present embodiments are provided so that the disclosure of the present invention is thoroughly disclosed and that those skilled in the art will fully understand the scope of the present invention.

And the present invention is only defined by the scope of the claims.

Thus, in some embodiments, well known components, well known operations, and well-known techniques are not specifically described to avoid an undesirable interpretation of the present invention.

In addition, throughout the specification, like reference numerals refer to like elements, and the terms (mentioned) used herein are intended to illustrate the embodiments and not to limit the invention.

In this specification, the singular forms include plural forms unless the context clearly dictates otherwise, and the constituents and acts referred to as " comprising (or having) " do not exclude the presence or addition of one or more other constituents and actions .

Unless defined otherwise, all terms (including technical and scientific terms) used herein may be used in a sense commonly understood by one of ordinary skill in the art to which this invention belongs.

Also, commonly used predefined terms are not ideally or excessively interpreted unless they are defined.

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

1 to 7, an apparatus 100 for diagnosing a load fault of the temperature and humidity controller according to the present invention includes an AC power source 105, a DC power source generating unit 110, a heater driving unit 115, a fan driving unit 120 A heater 125, a fan 130, a heater failure diagnosis unit 135, a fan failure diagnosis unit 140, a control unit 145, a temperature setting unit 150, a display unit 155 and a buzzer 160 And further includes a heater branching section 165 and a fan branching section 170.

The DC power generating unit 110 generates and supplies DC 5V power for driving the relay unit from the input AC power source 105 to the controller 145 and peripheral circuits.

2, the input AC power source 105 is rectified by diode D3 via thermistor TH1, smoothed by capacitors C4 and C5, and connected to the DRAIN terminal of PWM IC U1.

When the built-in FET of the PWM IC U1 is turned on, the output capacitor C2 is charged through the coil L1 and a current is passed through the rectifying diode D4 through the 5V load. The voltage across the capacitor C2 When the voltage reaches 5V, the voltage distributed between the resistors R1 and R3 through the feedback diode D2 is supplied to the feedback terminal of the PWM IC to turn off the built-in FET (Field Effect Transistor).

The voltage stored in the coil L1 flows through the diode D1 through the 5V load from the positive terminal of the output capacitor C2 until the FET of the IC U1 is turned on to maintain the voltage across the output capacitor C2 do. When the voltage of the driven capacitor C2 drops to less than 5V, the internal FET of the IC U1 is turned on again to repeat the above operation to maintain the voltage of the output capacitor C2 at 5V.

Referring to FIG. 3, the heater driving unit 115 and the fan driving unit 120 for controlling temperature and humidity are shown.

The heater driving unit 115 drives the heater 125 as a load when the first relay RL1 is turned on and stops driving the heater 125 when the first relay RL1 is turned off.

The fan driving unit 120 drives the fan 130, which is a load, when the second relay RL2 is turned on, and stops driving the fan 130 when the second relay RL2 is turned off.

The control unit 145 can simultaneously and selectively drive and control the heater driving unit 115 and the fan driving unit 120.

The control unit 145 receives the signal and controls the first relay RL1 for driving the heater and the second relay RL2 for driving the fan.

Specifically, the control unit 145 receives a signal from the 5V power source generated by the DC power generation unit 110 to turn on and off the transistors Q1 and Q2 to control the driving of the heater 125 and the fan 130 do.

In case of temperature control, the resistance value of the temperature sensor (thermistor, TH1) is fixed (ex: 10KΩ at 25˚C). If the setting value is set to 25˚C, if the current temperature is 0˚C, the thermistor TH1) is about 36 K [Omega] and higher than the set value of 10 K [Omega] in the controller 145, it is recognized that the current temperature is lower than the set value.

Then, the controller 145 applies the 5V power to the signal S1 to the heater 125 and supplies the current to the base of the transistor Q1 through the resistor R1 to turn on the transistor Q1, and the first relay RL1 5V power is applied to the coils of the first relay RL1 and the second relay RL1 and the contacts "A" and "B" are short-circuited so that the AC 220V power source flows through the heater 125, the first relay RL1 and the fuse F1 to drive the heater 125 Increase the temperature.

On the contrary, when the current temperature is higher than the set temperature, the 5V power supply is applied to the signal terminal S2 of the fan 130 and a current is supplied to the base of the transistor Q2 through the resistor R2 so that the transistor Q2 conducts 5V power is applied to the coil of the second relay RL2 so that the contacts "A" and "B" are short-circuited so that the AC 220V power source flows through the fan 130, the second relay RL2 and the fuse F1 The fan 130 rotates to lower the temperature.

Referring to FIG. 4, there is shown a heater failure diagnosis unit 135 for diagnosing a failure of the heater 125 and a fan failure diagnosis unit 140 for diagnosing a failure of the fan 130.

When the control unit 145 turns off the first relay RL1, the heater 125 stops driving.

The heater failure diagnosis unit 135 can diagnose the failure of the heater 125 when the first relay RL1 is turned off and the heater 125 stops driving. The heater failure diagnosis unit 135 can not diagnose the failure in the state that the heater 125 is being driven.

(1) A current supplied from the input AC power source 105 when the heater 125 is in a normal state, not a disconnection or a failure, and the AC 220V-N LINE is an upper voltage is supplied to the heater 125, the resistor R1, The collector 4 of the first photocoupler OPT1 and the emitter 3 are electrically connected to each other through the cathode 1 of the photocoupler OPT1 and the anode 2 to flow to AC 220V- And is applied to the control unit 145 through the resistor RS.

Conversely, if AC 220V-L LINE is an upper voltage and N LINE is a lower voltage, the current flows to the AC 220V-N LINE through the resistor R2, the resistor R1 and the heater 125, The collector 4 and the emitter 3 of the control unit 145 are turned off and the 5V power supplied to the control unit 145 through the resistor RS is cut off.

Referring to FIG. 5, when the heater 125 is in a steady state, the 5V power supplied to the controller 145 is applied 60 times per second, which is the frequency of the AC power.

(2) Since the current supplied from the input AC power supply 105 can not flow through the cathode 1 and the anode 2 of the first photocoupler OPT1 when the heater 125 is broken or broken, The collector 4 and the emitter 3 of the photocoupler OPT1 are turned off and the controller 145 is maintained in a state in which the 5V power is not supplied.

If there is no signal input for one second, the controller 145 determines that the heater 125 as a load is faulty and generates an alarm. The occurrence of the alarm will be described in detail below.

When the controller 145 turns off the second relay RL2, the fan 130 stops driving.

The fan failure diagnosis unit 140 can diagnose the failure of the fan 130 when the second relay RL2 is turned off and the fan 130 stops driving. The fan failure diagnosis unit 140 can not diagnose the failure in the state that the fan 130 is being driven.

(1) The current supplied from the input AC power source 105 when the fan 130 is in a normal state, not a disconnection or a failure, and the AC 220V-N LINE is an upper voltage is the fan 130, the resistor R3, The collector 4 of the second photocoupler OPT2 and the emitter 3 are turned into a conductive state by flowing AC220V-L through the cathode 1 of the photocoupler OPT2 and the anode 2, And is applied to the control unit 145 through the resistor RS.

On the other hand, if AC 220V-L LINE is an upper voltage and N LINE is a lower voltage, the current flows to the AC 220V-N line through the resistor R4, the resistor R3 and the fan 130, The collector 4 and the emitter 3 of the control unit 145 are turned off and the 5V power supplied to the control unit 145 through the resistor RS is cut off.

(2) Since the current supplied from the input AC power supply 105 can not flow through the cathode 1 and the anode 2 of the second photocoupler OPT2 when the fan 130 is broken or broken, The collector 4 and the emitter 3 of the photocoupler OPT2 are turned off and the 5V power is not supplied to the controller 145. [

The controller 145 determines that there is a failure of the fan 130, which is a load, when the signal is not input for one second, and generates an alarm. The occurrence of the alarm will be described in detail below.

The control unit 145 controls on / off of the first relay RL1 and the second relay RL2 by the DC power generated by the DC power generating unit 110. [

When the first photocoupler OPT1 is turned on with the first relay RL1 turned off and the heater 125 stopped driving, the heater 125 is determined to be normal and the first photocoupler OPT1 The heater 125 is judged to be broken or broken and the heater 125 failure alarm is generated.

The control unit 145 determines that the fan 130 is normal when the second photocoupler OPT2 is turned on while the second relay RL2 is turned off and the fan 130 stops driving and the second photocoupler OPT2 is turned off, the fan 130 is judged to be broken or broken, and the fan 130 alarms.

The heater driving unit 115 includes a base for receiving a signal for on / off of the first relay RL1 from the controller 145, a collector connected to the first relay RL1, and an emitter connected to the ground side And a first relay RL1 connected between the collector of the first transistor Q1 and the heater 125. The first transistor Q1 is connected to the first transistor Q1,

The fan driving unit 120 includes a base for receiving a signal for on / off of the second relay RL2 from the controller 145, a collector connected to the second relay RL2, and an emitter connected to the ground side And a second relay (RL2) connected between the collector of the second transistor (Q2) and the second transistor (Q2) and the fan (130).

When the control unit 145 supplies current to the base of the first transistor Q1 and the collector and the emitter are conductive, the DC power of a predetermined size generated by the DC power generation unit 110 is supplied to the coil of the first relay RL1 To short the contact of the first relay RL1 and then the input AC 220V power supply flows through the heater 125 and the first relay RL1 and the fuse F1 to drive the heater.

When the control unit 145 supplies current to the base of the second transistor Q2 and the collector and the emitter are conductive, the DC power of a predetermined size generated by the DC power generation unit 110 is supplied to the coil of the second relay RL2 To short the contacts of the second relay RL2 and then causes the input AC 220V power to flow through the fan 130 and the second relay RL2 and the fuse F1 to drive the fan 130. [

Referring to FIG. 2, the thermistor TH1 is located in the DC power generator 110 and the resistance value changes according to the ambient temperature. The thermistor TH1 is constituted by an NTC (Negative Temperature Coefficient Thermistor) device whose resistance value decreases as the temperature rises. The principle of the thermistor TH1 is well known to a person skilled in the art, so a detailed description thereof will be omitted.

The temperature setting unit 150 has an interface through which a user can input a temperature set value.

The controller 145 compares the resistance value of the thermistor TH1 corresponding to the temperature set value input by the user with the current resistance value measured using the thermistor TH1.

When the resistance value of the thermistor TH1 corresponding to the temperature set value inputted by the user through the temperature setting unit 150 is smaller than the current resistance value, it is determined that the current temperature is lower than the set value. The DC 5 V power supply generated by the DC power generator 110 is applied to the coil of the first relay RL 1 to short-circuit the contact of the first relay RL 1 to the collector of the first relay RL 1, .

The input AC 220V power supply flows through the heater 125, the first relay RL1 and the fuse F1, thereby driving the heater 125 to raise the temperature to the set temperature.

When the resistance value of the thermistor TH1 corresponding to the temperature set value inputted by the user through the temperature setting unit 150 is larger than the current resistance value, the controller 145 compares the resistance value as described above, When the collector and the emitter are electrically connected to each other by supplying a current to the base of the second transistor Q2, the DC 5V power generated by the DC power generator 110 is supplied to the second relay RL2 And the contact of the second relay RL2 is short-circuited by being applied to the coil.

The input AC 220V power source flows through the fan 130, the second relay RL2 and the fuse F1 to drive the fan 130 to lower the temperature to the set temperature.

The display unit 155 displays the presence or absence of failure of the heater 125 and the fan 130 using LEDs, respectively.

The following is an example of an auto mode for diagnosing the failure of the fan 130 that is not driven while the heater 125 is driven and for diagnosing a failure of the heater 125 that is not driven while the fan 130 is being driven ).

The controller 145 turns on the first relay RL1 and drives the heater 125 so that the temperature rises to the set temperature. In the fan failure diagnosis unit 140, the second photocoupler OPT2 is turned on The control unit 130 determines that the state of the fan 130 is normal and turns off the LED corresponding to the fan 130 of the display unit 155. [

When the second photocoupler OPT2 is turned off in the fan failure diagnosis unit 140, it is determined that the state of the fan 130 is broken or broken, and the LED corresponding to the fan 130 of the display unit 155 is blinked, The buzzer 160 sounds.

The control unit 145 turns on the second relay RL2 and drives the fan 130 to lower the temperature to the set temperature so that the first photo coupler OPT1 is turned on in the heater trouble diagnosis unit 135, , It is determined that the state of the heater 125 is normal and the LED corresponding to the heater 125 of the display unit 155 is turned off.

When the first photocoupler OPT1 is turned off in the heater failure diagnosis unit 135, it is determined that the state of the heater 125 is broken or broken and the LED corresponding to the heater 125 of the display unit 155 is blinked, The buzzer 160 sounds.

The control unit 145 controls the first relay RL1 and the second relay RL2 so that both the first relay RL1 and the second relay RL2 are turned off to stop the operation of the heater 125 and the fan 130, Diagnose the fault.

The following describes an off mode for diagnosing a failure of the heater 125 and the fan 130 in a state in which both the heater 125 and the fan 130 are not driven.

In the case where the control unit 145 is configured to read and recognize the fault state of the heater 125 and the fan 130 at different ports, the operation is as follows.

The control unit 145 determines that the state of the heater 125 is normal and turns on the LED corresponding to the heater 125 of the display unit 155 when the first photo coupler OPT1 is turned on in the heater failure diagnosis unit 135 Off.

The control unit 145 determines that the state of the heater 125 is broken or broken when the first photo coupler OPT1 is turned off in the heater failure diagnosis unit 135 and the heater 125 of the display unit 155 The LED is blinked, and the buzzer 160 is sounded.

The control unit 145 determines that the state of the fan 130 is normal and turns on the LED corresponding to the fan 130 of the display unit 155 when the second photo coupler OPT2 is turned on in the fan failure diagnosis unit 140 Off.

The control unit 145 determines that the state of the fan 130 is broken or broken when the second photocoupler OPT2 is turned off in the fan failure diagnosis unit 140, The LED is blinked, and the buzzer 160 is sounded.

An off mode for diagnosing the failure of the heater 125 and the fan 130 in a state in which both the heater 125 and the fan 130 are not driven will be described below.

In the case where the controller 145 is configured to read and recognize the fault state of the heater 125 and the fan 130 with the same port, the operation is as follows.

The control unit 145 causes the heater fault diagnosis unit 135 to turn off the first photocoupler OPT1 and the fan fault diagnosis unit 140 to turn off the second photocoupler OPT2, The heater 125 of the display unit 155 and the LED 130 corresponding to the fan 130 are blinked and the buzzer 160 is sounded.

The control unit 145 determines whether the first photocoupler OPT1 is turned on in the heater failure diagnosis unit 135 or the second photocoupler OPT2 is turned on in the fan failure diagnosis unit 140, Or both the first photo coupler OPT1 and the second photo coupler OPT2 are turned on, it is determined that both the heater 125 and the fan 130 are normal, The LED is kept off.

When the heater 125 and the fan 130 can not read and recognize the fault state of the fan 130 with the same port in consideration of the mounting area of the component in the hardware configuration, Flashes, and the buzzer sounds. If both the heater 125 and the fan 130 are faulty, the control unit 145 determines that all of the signals are malfunctioning because no DC 5V signal is input.

That is, when hardware is configured to read and recognize the fault state of the heater 125 and the fan 130 at the same port, if either the heater 125 or the fan 130 is faulty and the other is normal, If both the controller 125 and the fan 130 are normal, a signal of DC 5V is input to the controller 145. Therefore, the controller 145 determines that the signal is normal and turns off the LED and keeps the buzzer silent.

4, when the first relay RL1 is on, the heater branching unit 165 causes the current supplied from the input AC 220V power supply to flow to the heater driving unit 115 via the heater 125, When the relay RL1 is turned off, the current supplied from the input AC 220V power source flows through the heater 125 to the heater failure diagnosis unit 135. [

When the second relay RL2 is on, the fan branching unit 170 causes a current supplied from the input AC 220V power supply to flow to the fan driving unit 120 through the fan 130, and when the second relay RL2 is off A current supplied from an input AC 220 V power source flows through the fan 130 to the fan failure diagnosis unit 140.

The above-described features of the present invention will be summarized with reference to FIG. 6 and FIG.

Referring to FIG. 6, a method of diagnosing a load failure of the temperature and humidity controller according to the present invention will be described when both the heater and the fan are in an off state and both are in an on state.

First, a DC 5V power source is generated from an input AC 220V power source (S610).

And controls driving of the heater 125 and the fan 130 as a load (S620).

If both the heater 125 and the fan 130 are in the OFF state (OFF mode) (S630), the heater 125 and the fan 130 are diagnosed for failure (S640).

If it is determined that any one of the heater 125 and the fan 130 has failed, the corresponding LED blinks and the buzzer sounds (S650). Of course, the load LEDs that have not failed are kept off. If not all the LEDs are off, the buzzer does not sound (S650). In the case where the controller 145 is configured to read and recognize the fault state of the heater 125 and the fan 130 at different ports, this operation is possible.

However, when the heater 125 and the fan 130 can not be read and recognized by the same port in view of the mounting area of the components in terms of hardware configuration, if both the heater 125 and the fan 130 fail The LED is turned on only, and the buzzer sounds (S650). If both the heater 125 and the fan 130 are faulty, the control unit 145 determines that all of the signals are malfunctioning because no DC 5V signal is input.

That is, when hardware is configured to read and recognize the fault state of the heater 125 and the fan 130 at the same port, if either the heater 125 or the fan 130 is faulty and the other is normal, If both the controller 125 and the fan 130 are normal, a signal of DC 5V is input to the controller 145. Therefore, the controller 145 determines that the signal is normal and turns off the LED and keeps the buzzer silent.

If all the loads are on (S660), it is impossible to diagnose the failure of the heater 125 and the fan 130, which are loads (S670). In this case, the LED flashes and the buzzer sounds (S680).

If not all loads are off and temperature is not available, proceed to step S700. Will be described with reference to FIG.

7, it is possible to diagnose whether or not any other load not driven when the load of either the heater or the fan is running is diagnosed and the load failure of the temperature and humidity controller according to the present invention, Describe the diagnostic method.

If the current temperature is lower than the preset temperature (S710), the controller turns on the heater 125 until the set temperature is reached, (S720). At this time, the heater display LED is turned on.

At this time, it is diagnosed whether there is a failure of the fan 130 which is not driven (S730). If the fan 130 is normal, the LED corresponding to the fan 130 is kept off. If the fan 130 is malfunctioning, the buzzer sounds while blinking the LED (S740).

Conversely, if the current temperature is higher than the set temperature (S710), the fan is turned to lower the temperature (S750).

At this time, it is diagnosed whether the heater 125 which is not driven is faulty (S760). If the heater 125 is normal, the LED corresponding to the heater 125 is turned off. If the heater 125 is malfunctioning, the LED flashes and the buzzer sounds (S770).

The present invention is summarized as follows. When it is desired to check whether or not a load is faulty, the temperature setting value is set to be lower than the current temperature to check whether the heater is not driven in a state where the fan is driven, It is possible to check whether or not the fan that is not driven in the state where the heater is driven with the temperature higher than the current temperature is failed.

Although the present invention has been described in detail with reference to the preferred embodiments thereof, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. It is to be understood that the embodiments are to be considered in all respects as illustrative and not restrictive.

The scope of the present invention is defined by the appended claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents are included in the scope of the present invention. .

100 ... Load and fault diagnosis device of on and humidity controller
105 ... AC power source
110 ... DC power generator
115 ... heater driving part
120 ... fan drive
125 ... heater
130 ... Fans
135 ... heater trouble diagnosis unit
140 ... Fan trouble diagnosis part
145 ... control unit
150 ... Temperature setting unit
155 ... display
160 ... buzzer
165 ... heater breaker
170 ... fan branch donation

Claims (7)

A DC power generator for generating and supplying a DC power of a predetermined size for driving the control unit, peripheral circuits, and relays from the input AC power supply;
A heater driving unit for driving the heater, which is a load, when the first relay is on, and stopping the heater when the first relay is off;
A fan driving unit for driving the fan, which is a load, when the second relay is on, and stopping the fan when the second relay is off;
When the first relay is turned off and the heater stops driving, the current supplied from the input AC power source flows through the heater and the first photocoupler in turn when the heater is normal, so that the first photocoupler is turned on, A heater failure diagnosis unit in which the first photocoupler is turned off when a current supplied from the input AC power source can not flow through the first photocoupler in the event of a failure;
When the second relay is turned off and the fan stops driving, the current supplied from the input AC power source flows through the fan and the second photocoupler in order when the fan is normal, so that the second photocoupler is turned on, A fan failure diagnosis unit in which a current supplied from the input AC power source can not flow through the second photocoupler and the second photocoupler is turned off when the failure occurs; And
The first relay and the second relay are turned on and off by the DC power source generated by the DC power generator, and when the first photocoupler is turned on while the heater is stopped, When the first photocoupler is turned off, the heater is judged to be broken or broken and a heater failure alarm is generated. When the second relay is turned off to stop driving the fan, the second photocoupler And a controller for determining that the fan is normal when the second photocoupler is turned on and generating a fan failure alarm when the second photocoupler is turned off when the second photocouler turns off, .
The method according to claim 1,
The heater driving unit includes:
A first transistor having a base for receiving a signal for a first relay on / off from the control unit, a collector connected to the first relay, and an emitter connected to the ground; And
And a first relay connected between the collector of the first transistor and the heater,
The fan-
A second transistor having a base for receiving a signal for a second relay on / off from the control unit, a collector connected to the second relay, and an emitter connected to the ground; And
And a second relay connected between the collector of the second transistor and the fan,
When the control unit supplies a current to the base of the first transistor and the collector and the emitter are electrically connected to each other, DC power of a predetermined size generated by the DC power generation unit is applied to the coil of the first relay, The input AC power flows through the heater, the first relay and the fuse to drive the heater,
When the control unit supplies a current to the base of the second transistor to make the collector and the emitter conductive, the DC power source of a predetermined size generated by the DC power generating unit is applied to the coil of the second relay, And the fan is driven by allowing the input AC power to flow through the fan, the second relay, and the fuse, thereby driving the fan.
The method of claim 2,
A thermistor located in the direct current power generation unit and having a resistance value changed according to an ambient temperature; And
Further comprising a temperature setting unit in which a user inputs a temperature set value,
The controller compares the resistance value of the thermistor corresponding to the temperature set value input by the user with the current resistance value measured using the thermistor and if the resistance value corresponding to the temperature set value is smaller than the current resistance value When a current is supplied to the base of the first transistor to determine that the current temperature is lower than the set value and the collector and the emitter are electrically connected to each other, To short the contact of the first relay, the input AC power flows through the heater, the first relay and the fuse, thereby driving the heater to raise the temperature to the set temperature,
The controller compares the resistance value of the thermistor corresponding to the temperature set value input by the user with the current resistance value measured using the thermistor and if the resistance value corresponding to the temperature set value is larger than the current resistance value When a current is supplied to the base of the second transistor to determine that the current temperature is higher than the set value and the collector and the emitter are electrically connected to each other, And the second AC power source flows through the fan, the second relay, and the fuse, thereby driving the fan to lower the temperature to the set temperature. Fault diagnosis device.
The method of claim 3,
Further comprising a display unit for indicating whether or not the heater and the fan are faulty,
The control unit turns on the first relay and drives the heater to raise the temperature to the set temperature. When the second photocoupler is turned on in the fan failure diagnosis unit, the control unit determines that the state of the fan is normal, When the second photocoupler is turned off in the fan failure diagnosis unit, it is determined that the state of the fan is disconnection or failure and the LED corresponding to the fan of the display unit is blinked and an alarm is generated And,
The controller turns on the second relay and drives the fan to lower the temperature to the set temperature. When the first photocoupler is turned on by the heater failure diagnosis unit, the controller determines that the heater is in a normal state, The LED corresponding to the heater is turned off, and when the first photo coupler is turned off in the heater trouble diagnosis unit, it is determined that the state of the heater is broken or broken and the LED corresponding to the heater of the display unit is blinked, And a load failure diagnosis device for the temperature and humidity controller.
The method of claim 4,
The control unit stops the operation of the heater and the fan such that both the first relay and the second relay are turned off,
When the first photocoupler is turned on in the heater failure diagnosis unit, it is determined that the heater is in a normal state and the LED corresponding to the heater of the display unit is turned off. When the first photo coupler is turned off in the heater failure diagnosis unit , It is determined that the state of the heater is disconnection or failure and the LED corresponding to the heater of the display unit is blinked to generate an alarm,
When the second photocoupler is turned on in the fan failure diagnosis unit, it is determined that the state of the fan is normal and the LED corresponding to the fan of the display unit is turned off. When the second photo coupler is turned off in the fan failure diagnosis unit The controller determines that the state of the fan is disconnection or failure, and turns on the LED corresponding to the fan of the display unit to generate an alarm.
The method of claim 4,
The control unit stops the operation of the heater and the fan such that both the first relay and the second relay are turned off,
When the first photocoupler is turned off in the heater failure diagnosis unit and the second photocoupler is turned off in the fan failure diagnosis unit and both the heater and the fan are determined to be broken or broken, Flashes, generates an alarm,
The first photo coupler is turned on in the heater failure diagnosis unit or the second photo coupler is turned on in the fan failure diagnosis unit so that either one of the two is on or both of the first photo coupler and the second photo coupler are on, The controller determines that both the heater and the fan are normal, and maintains the LEDs corresponding to the heater and the fan in the off state.
The method according to claim 1,
And the first relay is turned on, the current supplied from the input AC power supply flows to the heater driving unit via the heater, and when the first relay is off, the current supplied from the input AC power supply is supplied to the heater A heater branching section for causing the heater to flow to the failure diagnosis section; And
If the second relay is on, the current supplied from the input AC power source flows through the fan to the fan driving unit, and if the second relay is off, the current supplied from the input AC power source flows through the fan Further comprising a fan branching section for allowing the fan branching section to flow to the fault diagnosis section.

Images