KR101456559B1 - Apparatus and method for preventing fire by interrupted arc in temperature controller - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a temperature control device for an electro-thermal bedding type electro-thermal bedding for regulating the temperature of a thermally conductive fuming line, which is an electric heating element of an electro-thermal bedding such as an electric bed, It is possible to monitor the occurrence of arc intermittent current due to the contact failure of the connection part connecting the heater and the temperature control device, and to stop the heating operation when the arc intermittent current is generated to prevent arc- The present invention relates to a fire prevention apparatus and a fire prevention method.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and method for preventing fire due to arc interruption of a temperature control apparatus,

The present invention relates to a temperature control device for an electro-thermal bedding type that detects an accurate temperature of a thermo-fuming wire by detecting an accurate peak of an AC power source and adjusts the temperature of a thermo-sensitive fuming wire which is an electric heating element of an electro- More particularly, the present invention relates to a method for monitoring the generation of an arc intermittent current due to a contact failure at a connection portion connecting a heater including a thermoelectric heating element and a temperature control device, The present invention relates to an apparatus and method for preventing fire caused by arc interruption of a temperature control device for preventing a fire caused by a fire.

Recently, there has been an increase in the spread of electro-thermal bedding such as electric bills, electric plates, electric mats, etc., which can save heating cost and enable easy heating in leisure activities such as camping.

Typically, the electro-thermal bedding is provided with a heater (not shown) provided on the inner side of a mat, a yoke and a long plate, and a temperature control device for controlling the temperature of the mat, do.

In general, the temperature control device is applied with a safety device for overheating of the heater, such as a prior art document, a patent document 10-2009-0101428, a fire prevention device of a temperature control device, and the like.

However, since the temperature control device is configured to be detachable through the heater and the physical connector as described above, a connection failure may occur in the connection portion of the connector.

If a connection failure occurs at the connection portion between the heater and the temperature control device, the connection portion is interrupted, and when the connection portion is disconnected, the resistance becomes large, so that a large voltage is momentarily applied to cause a fire.

However, the fire prevention apparatus of the conventional thermostat has the overheat prevention function using the current change value of the temperature detection signal due to the change of the resistance value of the thermistor included in the thermostat heating line of the heater. However, There is a problem that it is not possible to detect whether a defect has occurred in the contact portion with the heater, only the change in the current value due to the temperature of the heater is recognized.

As described above, in the conventional temperature control device, a fire due to contact failure may occur at the connection portion with the heater, and it is impossible to detect the contact failure at the connection portion with the heater, There was no problem.

In addition, in the conventional temperature regulator for AC power source synchronization, the clock in the microcomputer is fluctuated according to the temperature, so that the peak detection of the AC power source becomes inaccurate and the temperature can not be controlled accurately. Specifically, when the microcomputer clock fluctuates and the temperature is detected before the peak value of the AC power source, it is determined that the temperature is low despite the high temperature, and the heating is continuously performed, It is determined that the temperature is high even though the temperature is low, and the power supply may be shut off.

Accordingly, an object of the present invention is to provide a method and apparatus for detecting an accurate temperature of a thermo-fuming wire by accurate peak detection of an AC power source and monitoring generation of arc interrupting current due to a contact failure at a connecting portion connecting a heater including a heat- The present invention also provides an apparatus and method for preventing fire caused by arc interruption of a temperature control device for preventing a fire caused by an arc intermittent current by stopping a heating operation when an arc intermittent current is generated.

According to an aspect of the present invention, there is provided an apparatus for preventing fire by an arc interruption of a temperature control apparatus of the present invention. A second conductor heating wire wound around the outer circumferential surface of the NTC thermistor and a second conductor heating wire wound around the outer circumferential surface of the secondary conductor heating wire, A heat-resistant bed sheet connected to the heater including the insulation-coated NTC thermal heating line, a U-turn diode connected in series at the one end of the first heater conductor heating line and the second heater conductor heating line, and a control rectifier (SCR) An apparatus for controlling a temperature, comprising: an AC power supply for supplying an AC power; a connection unit physically detachably connected to the heater; a heater connected to the heater through a connection unit; A switching unit that supplies power to the heater through the connection unit, and a controller that is connected to the heater through the connection unit, A heating current detection unit for outputting the detected heating current detection signal and a heating current value of the heating current detection signal input through the heating current detection unit in synchronization with the frequency of the AC power source, And a microcomputer for judging a contact failure when the measured heating current value is less than or equal to the reference current value and stopping the heating operation.

The apparatus further includes a temperature signal detecting unit for detecting a temperature according to a temperature change of the NTC thermistor between the first heater conductor heating line of the NTC thermostat heating line and the second heater conductor heating line to output an NTC temperature detecting signal, It is determined that the heating current detection signal and the NTC temperature signal voltage output from the temperature signal detection unit are checked at the same time and when the heating current detection signal is inputted intermittently, The heating operation is stopped and the leakage current and the short arc voltage and the occurrence of overheating are detected by the NTC temperature detection signal generated between the primary heater conductor heating line and the secondary heater conductor heating line, The heating operation is stopped.

The microcomputer counts the number of contact failure judgments for a predetermined time when the contact failure is determined and further determines whether the counted number of contact failure times exceeds the reference number and then suspends the heating operation.

The switching unit includes a thyristor connected to the thermoelectric heating element and the ac power part of the heater and receiving a trigger signal to turn on the thermoelectric heating element to supply the heating power output from the ac power part to the thermoelectric heating element, And generating the trigger signal in a period and outputting the generated trigger signal to the thyristor.

And the temperature signal detecting unit may include a temperature detecting resistor connected in series with the NTC thermistor.

And the tree rejection generates the trigger signal under the control of the microcomputer.

And the tree rejection is synchronized with the frequency of the AC power source to generate the trigger signal in the heating period.

And a U-turn diode having a cathode connected to the other end of the primary heater conductor heating line and an anode connected to one end of the secondary heater conductor heating line, wherein one end of the primary heater conductor heating line is connected to the anode of the thyristor, The detection unit includes a heating current detection resistor having one end connected to the other end of the secondary heater conductive heating wire of the thermostat heating wire and the other end connected to the negative terminal of the alternating current power source to output a heating current detection signal to the microcomputer.

And a U-turn diode having a cathode connected to the other end of the primary heater conductor heating line and an anode connected to one end of the secondary heater conductor heating line, wherein one end of the primary heater conductor heating line is connected to the anode of the thyristor, The detection unit includes a heating current detection resistor having one end connected to the cathode of the thyristor and the other end connected to the negative terminal of the AC power source to output a heating current detection signal according to detection of the heating current to the microcomputer.

The other end of the primary heater conductor heating line is connected to one end of the secondary heater conductor heating line, and the other end of the primary heater conductor heating line is connected to the anode of the thyristor, And a heating current detection resistor connected to one end and connected to a negative terminal of the AC power source to output a heating current detection signal according to the detection of the heating current to the microcomputer.

One end of the first heater conductor heating line is connected to both terminals of the ac power source part and the other end thereof is connected to the anode of the thyristor and one end and the other end of the secondary heater conductor heating wire are commonly connected to the negative terminal of the ac power source part, And a heating current detecting resistor having one end connected to the cathode of the thyristor and the other end connected to the negative terminal of the ac power source to output a heating current detection signal according to the heating current detection to the microcomputer.

A light emitting unit that emits light corresponding to a detected heating current detection signal connected in parallel with the heating current detection resistor; and a control unit that receives the emitted light and outputs a heating current detection signal according to the intensity of the light to the microcomputer And a photocoupler including a light receiving portion for receiving the light.

And a U-turn diode having a cathode connected to the other end of the primary heater conductor heating line and an anode connected to one end of the secondary heater conductor heating line, wherein one end of the primary heater conductor heating line is connected to the anode of the thyristor, One end of the primary is connected to the other end of the secondary heater conductor heating line of the thermoelectric heating element, the other end of the primary is connected to the negative terminal of the AC power source, one end of the secondary is connected to the microcomputer, And a transformer connected to the terminal for outputting a heating current detection signal to the microcomputer.

And a U-turn diode having a cathode connected to the other end of the primary heater conductor heating line and an anode connected to one end of the secondary heater conductor heating line, wherein one end of the primary heater conductor heating line is connected to the anode of the thyristor, One end of the primary side is connected to the cathode of the thyristor, the other end of the thyristor is connected to the negative terminal of the ac power source, one end of the secondary side is connected to the microcomputer and the other end is connected to the negative terminal of the ac power source, And a transformer for outputting the heating current detection signal according to the detection of the heating current to the microcomputer.

The microcomputer detects a peak value of the AC power by an internal clock and determines that there is an abnormality in the clock when the detected peak value deviates from a stored reference peak value by more than a certain range, Thereby stopping the operation.

The microcomputer starts the heating operation after releasing the overheat mode when the peak value detected after setting the overheat mode is within a predetermined range of the reference peak value.

The apparatus further includes a heating stop unit for receiving a heating stop signal from the microcomputer and turning off the power of the temperature control apparatus. The micom counts the overheat mode time after the start of the overheat mode, An alarm is generated when the alarm reference time exceeds a predetermined reference alarm time, and the heating stop signal is outputted to the heating stop section.

The apparatus may further include a heating stop unit that receives a heating stop signal from the micom and turns off the power of the temperature adjusting apparatus, and the micom outputs a heating stop signal to the heating stop unit to stop the heating.

The microcomputer controls the switching unit to shut off the heating power supplied to the heater to stop the heating.

According to an aspect of the present invention, there is provided a method of preventing fire by an arc interruption of a temperature control device of the present invention, A heating period judging step of detecting whether the micom is a heating period by the frequency of the alternating current power supply; a heating period judging step of judging whether the micom is a heating period by measuring a heating current Determining whether the measured heating current value is less than a preset reference current value when the heating current value is measured and determining whether the heater is in contact failure; And stopping the heating operation when the microcomputer determines that the contact failure is less than the reference current value.

The method may further include a second contact failure determination step of determining whether the microcomputer is interrupted when the heating current detection signal is interrupted and the heating current detection signal is input intermittently.

The method may further include a contact failure persistence determination step of counting the number of contact failure times for a predetermined period when the contact failure is determined to determine whether the number of contact failure times for the period exceeds a predetermined reference number, The heating operation is stopped when the number of contact failure times exceeds the reference number of times.

In the method, the microcomputer detects a peak value of the AC power source by an internal clock in addition to the process of determining a contact failure, and when the detected peak value deviates from a reference peak value stored in advance by a predetermined range or more, And a microcomputer overheating prevention process for stopping the heating operation after setting the overheat mode.

The method further includes a microcomputer overheating mode releasing step of releasing the overheating mode and initiating the heating operation when the peak value detected after the microcomputer overheating prevention process is within a predetermined range of the reference peak value .

INDUSTRIAL APPLICABILITY The present invention has an effect of monitoring contact failure and proximity disconnection of a connection portion by detecting an arc intermittent current due to a contact failure at a connection portion with a heater.

Accordingly, since the heating operation of the heater can be stopped when the contact failure is detected, the present invention has an effect of protecting the property of the user by preventing the fire due to the arcing due to the contact failure in advance.

Further, according to the present invention, it is possible to prevent a primary fire by sensing occurrence of a contact failure of a heater connector by detecting a heating current detection signal or an occurrence of an arcing operation by a heater disconnection, and a leakage current due to NTC temperature signal voltage and a short arc voltage And the temperature over-discharge is detected to prevent the secondary fire. Thus, it is possible to prevent the fire from being double, thereby enhancing the stability of the apparatus.

In addition, the present invention can detect a clock fluctuation in a microcomputer of a temperature controller according to a temperature to control a heating operation at a time of a clock fluctuation to detect a temperature at a more precise time point, thereby enabling a more accurate temperature control .

In addition, the present invention can control the heating operation at the time of detecting the clock fluctuation to lower the temperature inside the temperature regulator including the microcomputer, thereby stabilizing the clock of the microcomputer, thereby improving the stability and accuracy of the temperature regulator.

FIG. 1 is a block diagram showing a configuration of a fire prevention device by arc interruption of a temperature control device according to the present invention.
2 is a flowchart illustrating a fire prevention method of a fire prevention apparatus by arc interruption of a temperature control apparatus according to the present invention.
3 is a circuit diagram of an apparatus for preventing fire by arc interruption of the temperature control apparatus according to the first embodiment of the present invention.
4 is a circuit diagram of an apparatus for preventing fire by arc interruption of a temperature control apparatus according to a second embodiment of the present invention.
Fig. 5 is a diagram showing the heating current direction and the detection position in Fig. 3 in an equivalent circuit.
Fig. 6 is a diagram showing an equivalent circuit of the heating current direction and the detection position in Fig. 4. Fig.
Fig. 7 is a diagram showing the (+) heating current detection waveform in Fig.
Fig. 8 is a diagram showing the (-) heating current detection waveform in Fig. 3;
9 is a view for explaining the operation concept according to the AC power frequency of the present invention.
FIG. 10 is a circuit diagram for explaining a method of selecting a temperature for a thermal conductive heating line according to the present invention.
11 is a diagram showing a first example of a method of detecting the temperature of a heat generating heating wire according to the present invention.
12 is a diagram showing a second example of the method of detecting the temperature of the heat generating heating wire according to the present invention.
13 is a diagram showing a first example of the heating current detection method according to the present invention.
14 is a diagram showing a second example of the heating current detection method according to the present invention.
15 is a flowchart showing a fire prevention method according to the clock fluctuation detection of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the configuration and operation of a fire prevention device by arc interruption of the temperature control device of the present invention will be described with reference to the accompanying drawings, and a fire prevention method in the device will be described.

FIG. 1 is a block diagram illustrating a configuration of a fire prevention apparatus according to an embodiment of the present invention; FIG. 9 is a diagram illustrating an operation concept according to an AC power source frequency of the present invention. FIG. This will be described below with reference to Figs. 1 and 9. Fig.

The heat transfer bedding according to the present invention includes a temperature control device and a heater (60).

First, the structure of the heater 60 will be described before describing the configuration of the temperature regulating device. The heater 60 includes the thermoelectric heating wire 4 and the U-turn diode 10. However, the U-turn diode 10 may be configured in a temperature controller.

A primary heater conductor heating wire 2 is wound around the core outer circumferential surface of the thermal heating wire 4 and a synthetic resin NTC thermistor 3 such as nylon is coated on the outer circumferential surface of the primary heater wire 2, The secondary conductor heating wire 1 is wound on the outer circumferential surface and the outer circumferential surface of the secondary conductor heating wire 1 is insulated. The microcomputer 9 can measure the temperature of the thermoelectric heating line according to the change of the resistance value of the synthetic resin NTC thermistor 3 according to the temperature.

The apparatus for preventing fire by arc interruption of the temperature control apparatus according to the present invention includes a microcomputer 9, a power supply unit 20, a heating current detection unit 30, a temperature signal detection unit 31, a switching unit 40, (50) and a heating stop (55).

The microcomputer 9 controls the overall operation for detecting the arc intermittent current and stopping the heating operation according to the present invention.

Specifically, as shown in FIG. 9, the microcomputer 9 detects a temperature in a positive half period (or a negative half period) synchronized with a frequency of a sine wave AC power source, and detects a temperature in a negative half period Or a positive (+) half period - hereinafter referred to as a "heating period" in which a heating current is supplied to the heater).

9, the microcomputer 9 detects the heating current through the heating current detection unit 30 in the heating cycle and receives the heating current detection signal to calculate a current value of the heating current (hereinafter referred to as "heating current value") And judges the contact failure of the connection portion 50 of the heater 60 according to the heating current value. 9, the microcomputer 9 detects the current value of the temperature detection signal (hereinafter referred to as "temperature detection signal ") input through the heater 60 through the temperature signal detection unit 31 at a positive half- Signal current value "), and adjusts the temperature of the heater 60 in accordance with the measured temperature detection signal current value.

The microcomputer 9 according to the present invention simultaneously inspects the heating current detection signal and the NTC temperature signal voltage output from the NTC thermoelectric heating line, and when the heating current detection signal is input intermittently, It is judged that an arcing operation arises due to disconnection of the heater and the heating operation is stopped and the leakage current and short arc due to the NTC temperature signal voltage generated between the primary heater conductor heating line 2 and the secondary heater conductor heating line Detects the occurrence of overheating of the voltage and the temperature and stops the heating operation in parallel with the heating current detection signal to perform the double fire prevention operation.

In addition, the microcomputer 9 includes a clock generator (not shown) for continuously outputting a clock of a predetermined period, and operates according to the clock. In particular, the microcomputer 9 detects the temperature of the heater 60 in synchronization with the peak point of the frequency of the AC power source, which is a sinusoidal wave, in order to perform the temperature detection. At this time, the microcomputer 9 detects a peak point of the AC power source in synchronization with the clock generated by the clock generator to operate synchronously with the peak point of the AC power source. However, the microcomputer 9 may increase the internal temperature of the temperature control device due to the ambient temperature such as the temperature of the heater and the overheating on the circuit, and the clock may fluctuate as the temperature rises. In order to prevent inaccurate temperature detection due to the fluctuation of the clock, the microcomputer 9 stores the peak value of the peak point of the AC power source, which is a sine wave at the normal time, as the reference peak value, And judges whether or not they coincide with each other to indirectly judge whether the clock fluctuates. When the microcomputer 9 determines that the clock has changed, the microcomputer 9 stops the heating operation by setting the overheat mode to decrease the temperature of the temperature control device. Here, the heating operation is to minimize the operation inside the temperature control device in addition to the operation of supplying the heating current to the heater 60. [ In the overheat mode, the microcomputer 9 outputs a heating stop signal to the heating stop unit 55 and stops the heating stop signal. Alternatively, the microcomputer 9 controls the switching unit 40 (the tree reject unit 41 of FIG. 4) It is possible to stop the heating operation by interrupting only the alternating current provided to the power source.

In the latter case, the microcomputer 9 ignores the AC power in the overheat mode and stops all operations. However, the microcomputer 9 periodically checks the peak value of the AC power to check whether the clock returns to normal, resumes the heating operation when the clock returns to the normal state, and resumes the heating operation.

However, since the AC power supplied to the microcomputer 9 is also cut off in the former case, it is not necessary to set the overheat mode, and it is preferable that the overheat mode is reset when the temperature control device is restarted when the overheat mode is set.

When the overheat mode is set and the overheat mode is continued for a predetermined time or longer, the microcomputer 9 alerts the user that the overheat mode has been set and released through a buzzer (not shown), a speaker (not shown), a light emitting diode It might be. That is, the microcomputer 9 may generate an alarm when the count time counted from the overheat mode setting exceeds the preset alarm reference time.

The power supply unit 20 includes an AC power supply unit 21 for supplying AC power and a DC power supply unit 22 for receiving the AC power and generating DC power and providing the AC power to the microcomputer 9.

The connection unit 50 is configured to physically attach and detach the heater 60 and the fire prevention apparatus of the present invention and is provided with an AC And the power is supplied to the heater 60.

The switching unit 40 is provided between the AC power supply unit 21 and the connection unit 50 and supplies or cuts the heating current of the AC power inputted from the AC power supply unit 21 to the heater 60 through the connection unit 50 .

The temperature signal detecting unit 31 is connected to the heater 60 through the connection unit 50 and detects an NTC temperature detection signal (or "temperature detection signal ") corresponding to the temperature of the heater 60, Quot; signal ") to the microcomputer 9. The NTC temperature detection signal may be a voltage.

The heating current detection unit 30 detects the heating current supplied according to the present invention and outputs a heating current detection signal to the microcomputer 9. [

Under the control of the microcomputer 9, the heating stop section 55 cuts off the heating power supplied from the AC power source section 21 to the heater 60 to stop the heating operation. 3 to 4, which will be described later, the heating stop part 55 is connected to the AC power supply part 21 in parallel and is connected to the thermal fuse 56 in series with the AC power supply part 21, And a heating resistor 59 connected in series with the second switching unit 58 and disposed adjacent to and in parallel with the thermal fuse 56. The second switching unit 58 is turned on and off, And may be a fuse disconnection part which disconnects the thermal fuse 56 by heat generated in the heating resistor 59 when the heating stop signal is input from the microcomputer 9,

The microcomputer 9 should control the switching unit 40 to block the heating current supplied to the heater 60 in the heating cycle. In other words, the switching unit 40 should be configured to be able to turn on / off the function under the control of the microcomputer 9. [

2 is a flowchart illustrating a fire prevention method of a fire prevention apparatus by arc interruption of a temperature control apparatus according to the present invention. Hereinafter, description will be made with reference to Figs. 1 and 2. Fig.

First, the microcomputer 9 checks whether the current period is a heating current detection period, that is, a heating period, from among the positive half period and the negative half period of the AC power (S211).

In the heating period, the microcomputer 9 measures the heating current value of the heating current detection signal input through the heating current detection unit 30 (S213).

When the heating current value is measured, the microcomputer 9 checks whether the heating current value is smaller than the reference current value (S215) or whether the heating current is interrupted (S217).

When the heating current value is lower than the reference current value or the heating current is interrupted, the microcomputer 9 determines that a contact failure arises due to heater contact failure or heater disconnection, and the switching unit 40 or heating stop unit 55 A heating operation stop signal is output to stop the heating operation (S223).

The heating (heating) operation is stopped even if only one of the above two conditions is satisfied in S215 and S217. However, the heating operation may be stopped even when both of them are satisfied.

In order to determine a more accurate contact failure, the microcomputer 9 counts the number of times of contact failure detection for a certain period of time (S219) if the condition of at least one of S215 and S217 is satisfied, And may stop the heating operation only when the reference number is exceeded (S221) (S223). The predetermined time may be in units of seconds, minutes, etc., but preferably in seconds, and the number of times of the reference may be about 50 to 60 times.

The microcomputer 9 controls the leakage current and the short arc voltage by the NTC temperature detection signal (voltage) generated between the primary heater conductor heating wire 2 and the secondary heater conductor heating wire 1, It may be configured to detect the occurrence of overheating and suspend the heating operation in parallel with the heating current detection signal.

FIG. 3 is a circuit diagram of a fire prevention apparatus according to an embodiment of the present invention; FIG. 3 is a schematic view illustrating a fire prevention apparatus of a fire prevention apparatus of a non- Fig. 7 is a diagram showing a heating current direction and a detection position in Fig. 3 by an equivalent circuit, and Fig. 12 is a diagram showing a (-) heating (heater) current detection waveform. This will be described below with reference to Figs. 3, 5 and 8. Fig.

The microcomputer 9 according to the first embodiment receives the alternating-current power supply as the alternating-current power supply synchronization signal through the power-down resistor 5.

The temperature signal detecting unit 31 according to the first embodiment is constituted by a temperature detecting resistor 8 for detecting a temperature and the heating current detecting unit 30 is constituted by a heating current detecting resistor 7 for detecting a heating current do. That is, the heating current detecting section may be constituted by a heating current detecting resistor 7, and the temperature signal detecting section is constituted by a temperature detecting resistor 8 connected to the NTC thermistor 3. 5, one end of the heating current detection resistor 7 is connected to the (-) terminal of the AC power source unit 21 and the other end thereof is connected to the connection point 13. The heating current detection resistor 7 is connected at one end to the other end of the secondary heater conductive heating wire 1 of the heat sensing heating wire 4, And the other end thereof is connected to the negative terminal of the AC power source unit 21 and outputs a heating current detection signal to the microcomputer 9. [

The switching unit 40 includes a thyristor 6 and a tree rejecting unit 41. The thyristor 6 receives the trigger from the tree rejection 41 and is turned on or off. 8, the tree rejection unit 41 receives the AC power from the AC power source unit 21, generates a trigger in the negative period of the AC power source, and turns on the thyristor 6 so that the heating current is supplied to the heater 60 To the heat control heating line (4). The tree rejecting unit 41 may be configured to perform or stop the heating (heating) operation of supplying the heating current to the heater 60, that is, the thermal heating cable 4 under the control of the microcomputer 9, And may be configured to perform or stop the heating operation in synchronization with the AC power source. In the latter case, since the microcomputer 9 does not have the heating operation stopping means according to the detection of the contact failure, the microcomputer 9 stops the heating operation under the control of the microcomputer 9, as shown in FIGS. 1 and 3 to 4 55).

The heating stop unit 55 is connected to the AC power supply unit 21 in parallel and is controlled by the microcomputer 9 to turn on and off the AC power supply unit 21. The heating stop unit 55 includes a thermal fuse 56 connected in series with the AC power supply unit 21, And a heating resistor 59 connected in series with the second switching unit 58 and disposed adjacent to and in parallel with the thermal fuse 56. The microcomputer 9 is connected to the second switching unit 58, And a fuse disconnecting part for disconnecting the thermal fuse 56 by heat generated in the heating resistor 59 upon input of a heating stop signal from the heating resistor 59.

8, when a trigger is generated from the tree rejection 41 in the negative period of the AC power source and the thyristor 6 of the switching unit 40 is turned on, the microcomputer 9 is synchronized with the AC power source, The current value of the heating current is measured at the position of the other end of the heating current detection resistor 7 in the negative period.

When the current value of the heating current is measured, the microcomputer 9 determines whether or not the contact portion 50 is in contact failure as shown in FIG. 2, and determines whether the heating operation is continued or not according to the determination.

4 is a circuit diagram of an apparatus for preventing fire by arc interruption of a temperature control apparatus according to a second embodiment of the present invention, and shows a circuit diagram of a fire prevention apparatus of a non-magnetic heat- Fig. 6 is a diagram showing the heating current direction and the detection position in Fig. 4 by an equivalent circuit, and Fig. 7 is a diagram showing the (+) heating current detection waveform in Fig. This will be described below with reference to Figs. 4, 6, and 7. Fig.

7, since one end of the heating current detection resistor 7 as the heating current detection unit 30 is connected to the negative terminal of the AC power source unit 21, And the other end is connected to the cathode terminal of the thyristor 6 of the switching unit 40. [ That is, one end of the heating current detecting resistor 7 is connected to the cathode of the thyristor 6, and the other end is connected to the negative terminal of the AC power source 21 so that the microcomputer 9 detects the heating current detection signal, .

In the fire prevention device according to the second embodiment of the present invention, a heating current path is formed in the half cycle of the alternating current power supply as in the equivalent circuit of Fig.

Therefore, the microcomputer 9 can detect the heating current by the heating current detection resistor 7. [

FIG. 10 is a circuit diagram for explaining a method for selecting a temperature detection of a thermally insulated heating line according to the present invention. In FIG. 10, And the voltage of the temperature detection signal is determined by the value.

11 is a view showing a first example of a method of detecting the temperature of a heat generating heating wire according to the present invention, in which a temperature detection signal is outputted at both ends of a U-turn diode 10 in the case of constituting a non- 2 is a diagram illustrating a second example of a method of detecting a temperature of a thermal conductive heating wire according to the present invention. In the case of configuring a general thermostat heating wire, a temperature detection signal is output at both ends of a first conductive heating wire 2 and a second conductive heating wire 1 will be.

13 is a diagram showing a first example of the heating current detection method according to the present invention.

The method of measuring the heating current according to the first example is a method of detecting a heating current by connecting an optocoupler having a good insulation coefficient to the heating current detection resistor 7 in parallel. The detected heating current is input to the microcomputer 9.

14 is a diagram showing a second example of the heating current detection method according to the present invention.

The heating current measuring method according to the second example is a method of detecting the heating current by connecting the primary side of the transformer to the "AA" -AA position instead of the heating current detecting resistor 7. The detected heating current is input to the microcomputer 9.

15 is a flowchart showing a fire prevention method according to the clock fluctuation detection of the present invention.

Referring to FIGS. 1 and 15, the microcomputer 9 detects a peak value of an AC power input when power is supplied to the temperature controller (S311).

When the peak value is detected, the microcomputer 9 loads the stored reference peak value and compares the reference peak value with the detected peak value to determine whether the detected peak value is out of the reference peak value (S313). The microcomputer 9 judges that the detected peak value coincides with the reference peak value within a certain range and determines that the reference peak value falls outside the range.

If it is determined that the range is out of the range of the reference peak value, the microcomputer 9 sets the overheat mode to stop the operation synchronized with the AC power (S315), and outputs a heating stop signal to the heating stop unit 55 to stop heating the heater (S317).

Even when the overheat mode is set, the microcomputer 9 continuously detects only the AC power peak value to determine whether the peak value of the AC power is normally detected (S513). If the peak value of the AC power is returned to normal After the overheating mode is released (S319), the heating stop section 55 is controlled to supply the heating current to the heater 60 to resume heating (S321).

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. It will be easily understood. It is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, it is intended to cover various modifications within the scope of the appended claims.

1: Secondary heater conductor heating wire 2: Primary heater conductor heating wire
3: Synthetic resin NTC thermistor 4: Thermal thermal line
5: Resistor 6: Thyristor
7: Heating current detection resistor 8: Temperature detection resistor
9: Micom 10: U-turn diode
12, 13: connection point 20: power source section
21: AC power source unit 22: DC power source unit
30: heating current detecting unit 31: temperature signal detecting unit
40:
41: tree rejection 50: connection
55: heating stop 56: thermal fuse
58: second switching unit 59: heating resistor
60: heater

Claims (24)

A second conductor heating wire wound around the outer circumferential surface of the NTC thermistor and a second conductor heating wire wound around the outer circumferential surface of the secondary conductor heating wire, An NTC thermally insulated heating line which is insulated, a U-turn diode connected in series at one end of the first heater conductor heating line and a second heater conductor heating line, and a thermostat for the heating bedding connected to the heater including a heater heating current detection resistor In this case,
An AC power supply unit for supplying AC power,
A connecting portion physically attached to and detached from the heater,
A switching unit connected to the heater through a connection unit and adapted to receive the AC power and to be turned on in a heating cycle of the AC power supply to supply the heating power to the heater through the connection unit;
A heating current detector connected to the heater through the connection unit to detect the heating current and output the detected heating current detection signal,
Wherein the control unit measures the heating current value of the heating current detection signal input through the heating current detection unit when the heating current value is lower than the reference current value or continuously interrupted And a microcomputer for judging the contact failure and stopping the heating operation,
Further comprising a temperature signal detecting unit for detecting a temperature of the NTC thermistor between the first heater conductor heating line and the second heater conductor heating line of the NTC thermostat heating line and outputting an NTC temperature detecting signal,
The microcomputer,
The heating current detection signal and the NTC temperature signal voltage output from the temperature signal detection unit are checked at the same time,
When the heating current detection signal is inputted intermittently, it is judged that the heating operation is stopped due to the contact failure of the heater connector or the occurrence of the recontacting arc due to the heater disconnection,
A leakage current, a short arc voltage and an overheating occurrence are detected by the NTC temperature detection signal generated between the primary heater conductor heating line and the secondary heater conductor heating line, and the heating operation is stopped in parallel with the heating current detection signal The fire prevention device by the arc interruption of the temperature control device.
delete A second conductor heating wire wound around the outer circumferential surface of the NTC thermistor and a second conductor heating wire wound around the outer circumferential surface of the secondary conductor heating wire, An NTC thermally insulated heating line which is insulated, a U-turn diode connected in series at one end of the first heater conductor heating line and a second heater conductor heating line, and a thermostat for the heating bedding connected to the heater including a heater heating current detection resistor In this case,
An AC power supply unit for supplying AC power,
A connecting portion physically attached to and detached from the heater,
A switching unit connected to the heater through a connection unit and adapted to receive the AC power and to be turned on in a heating cycle of the AC power supply to supply the heating power to the heater through the connection unit;
A heating current detector connected to the heater through the connection unit to detect the heating current and output the detected heating current detection signal,
Wherein the control unit measures the heating current value of the heating current detection signal input through the heating current detection unit when the heating current value is lower than the reference current value or continuously interrupted And a microcomputer for judging the contact failure and stopping the heating operation,
The microcomputer,
Wherein the control unit counts the number of times of contact failure determination for a predetermined period of time when the contact failure is determined and further determines whether the counted number of contact failure times exceeds the reference number and then stops the heating operation. Prevention device.
A second conductor heating wire wound around the outer circumferential surface of the NTC thermistor and a second conductor heating wire wound around the outer circumferential surface of the secondary conductor heating wire, An NTC thermally insulated heating line which is insulated, a U-turn diode connected in series at one end of the first heater conductor heating line and a second heater conductor heating line, and a thermostat for the heating bedding connected to the heater including a heater heating current detection resistor In this case,
An AC power supply unit for supplying AC power,
A connecting portion physically attached to and detached from the heater,
A switching unit connected to the heater through a connection unit and adapted to receive the AC power and to be turned on in a heating cycle of the AC power supply to supply the heating power to the heater through the connection unit;
A heating current detector connected to the heater through the connection unit to detect the heating current and output the detected heating current detection signal,
Wherein the control unit measures the heating current value of the heating current detection signal input through the heating current detection unit when the heating current value is lower than the reference current value or continuously interrupted And a microcomputer for judging the contact failure and stopping the heating operation,
The switching unit includes:
A thyristor connected to the thermoelectric heating element and the ac power part of the heater, the thyristor being turned on by receiving a trigger signal and providing the heating power output from the ac power part to the thermoelectric heating element;
And a tree rejection unit receiving the AC power and generating the trigger signal in the heating cycle and outputting the trigger signal to the gate of the thyristor.
The method according to claim 1,
Wherein the temperature signal detecting unit comprises a temperature detecting resistor connected in series with the NTC thermistor.
5. The method of claim 4,
And the tree rejection generates the trigger signal under the control of the microcomputer.
5. The method of claim 4,
Wherein the tree rejection is synchronized with the frequency of the AC power source to generate the trigger signal in the heating period.
5. The method of claim 4,
Wherein one end of the primary heater conductor heating line is connected to an anode of the thyristor,
The heating current detection unit,
And a heating current detecting resistor having one end connected to the other end of the secondary heater conductor heating line of the thermoelectric heating element and the other end connected to the negative terminal of the AC power source to output a heating current detection signal to the microcomputer. Fire prevention device by arc interruption.
5. The method of claim 4,
One end of the primary heater conductor heating line is connected to the anode of the thyristor,
The heating current detection unit,
And a heating current detection resistor connected to the cathode of the thyristor at one end and connected to the negative terminal of the ac power source to output a heating current detection signal according to detection of the heating current to the microcomputer. Device for preventing fire by intermittent operation.
5. The method of claim 4,
The other end of the first heater conductor heating line is connected to one end of the secondary heater conductor heating line, the other end of the first heater conductor heating line is connected to the anode of the thyristor,
The heating current detection unit,
And a heating current detection resistor connected to one end of the primary heater conductor heating line at one end and connected to a negative terminal of the AC power source at the other end to output a heating current detection signal according to the heating current detection to the microcomputer Device for preventing fire by arc interruption of device.
11. The method according to any one of claims 8 to 10,
A light emitting portion for emitting light corresponding to a detected heating current detection signal connected in parallel with the heating current detection resistor,
Further comprising a photocoupler for receiving the emitted light and outputting a heating current detection signal according to the intensity of the light to the microcomputer.
5. The method of claim 4,
Wherein one end of the primary heater conductor heating line is connected to an anode of the thyristor,
The heating current detection unit,
One end of the primary is connected to the other end of the secondary heater conductor heating line of the thermoelectric heating cable, the other end of the primary is connected to the negative terminal of the AC power source, one end of the secondary is connected to the microcomputer, and the other end is connected to the negative terminal of the AC power source And a transformer for outputting a heating current detection signal to the microcomputer.
5. The method of claim 4,
One end of the primary heater conductor heating line is connected to the anode of the thyristor,
The heating current detection unit,
One end of the primary side is connected to the cathode of the thyristor, the other end of the thyristor is connected to the negative terminal of the ac power source, one end of the secondary side is connected to the microcomputer, and the other end is connected to the negative terminal of the ac power source, And a transformer for outputting the detected heating current detection signal to the microcomputer.
A second conductor heating wire wound around the outer circumferential surface of the NTC thermistor and a second conductor heating wire wound around the outer circumferential surface of the secondary conductor heating wire, An NTC thermally insulated heating line which is insulated, a U-turn diode connected in series at one end of the first heater conductor heating line and a second heater conductor heating line, and a thermostat for the heating bedding connected to the heater including a heater heating current detection resistor In this case,
An AC power supply unit for supplying AC power,
A connecting portion physically attached to and detached from the heater,
A switching unit connected to the heater through a connection unit and adapted to receive the AC power and to be turned on in a heating cycle of the AC power supply to supply the heating power to the heater through the connection unit;
A heating current detector connected to the heater through the connection unit to detect the heating current and output the detected heating current detection signal,
Wherein the control unit measures the heating current value of the heating current detection signal inputted through the heating current detection unit when the heating current value is lower than the reference current value or continuously interrupted And a microcomputer for judging a contact failure and stopping the heating operation,
A thermal fuse connected in series with the AC power source,
A second switching unit connected in parallel to the AC power supply unit and turned on / off under the control of the microcomputer,
And a heating resistor connected in series with the second switching unit and configured to be adjacent to the thermal fuse,
Wherein the microcomputer turns off the thermal fuse by causing the heating resistor to generate heat by turning on the second switching unit when the contact failure is determined, thereby disconnecting the thermal fuse.
A second conductor heating wire wound around the outer circumferential surface of the NTC thermistor and a second conductor heating wire wound around the outer circumferential surface of the secondary conductor heating wire, An NTC thermally insulated heating line which is insulated, a U-turn diode connected in series at one end of the first heater conductor heating line and a second heater conductor heating line, and a thermostat for the heating bedding connected to the heater including a heater heating current detection resistor In this case,
An AC power supply unit for supplying AC power,
A connecting portion physically attached to and detached from the heater,
A switching unit connected to the heater through a connection unit and adapted to receive the AC power and to be turned on in a heating cycle of the AC power supply to supply the heating power to the heater through the connection unit;
A heating current detector connected to the heater through the connection unit to detect the heating current and output the detected heating current detection signal,
Wherein the control unit measures the heating current value of the heating current detection signal inputted through the heating current detection unit when the heating current value is lower than the reference current value or continuously interrupted And a microcomputer for judging the contact failure and stopping the heating operation,
The microcomputer,
When the peak value of the AC power source is detected by the internal clock and the reference peak value stored beforehand is out of a certain range or more, it is determined that there is an abnormality in the clock, Wherein the temperature control device is a device for preventing fire by arc interruption of the temperature control device.
16. The method of claim 15,
The microcomputer,
Wherein when the peak value detected after setting the overheat mode is within a predetermined range of the reference peak value, the heating operation is started after releasing the overheating mode.
16. The method of claim 15,
Further comprising a heating stop unit for receiving a heating stop signal from the microcomputer and turning off the power of the temperature control apparatus,
The microcomputer,
Wherein the control unit counts the overheat mode time after the start of the overheat mode and generates an alarm when the counted time exceeds a preset alarm reference time and outputs the heating stop signal to the heating stop unit Fire protection device.
16. The method of claim 15,
Further comprising a heating stop unit for receiving a heating stop signal from the microcomputer and turning off the power of the temperature control apparatus,
The microcomputer,
And stops the heating by outputting a heating stop signal to the heating stop section.
16. The method of claim 15,
The microcomputer,
Wherein the control unit controls the switching unit to shut off the heating power supplied to the heater to stop the heating.
A heating cycle judging process of detecting whether the micom is a heating cycle based on the frequency of the AC power source,
A heating current value measuring step of measuring the current value of the heating current by receiving the heating current detection signal detected by the microcomputer through the heating current detection unit if the heating period is a period,
If the heating current value is measured, the microcomputer checks whether the measured heating current value is smaller than a preset reference current value to determine whether the heater is in contact failure.
And stopping the heating operation when the measured heating current value is less than the reference current value and the microcomputer determines that the contact is defective,
Further comprising a second contact failure judging step of judging the contact failure when the microcomputer judges whether or not the heating current detection signal is intermittent and intermittently inputs a heating current detection signal. How to prevent fire.
delete A heating cycle judging process of detecting whether the micom is a heating cycle based on the frequency of the AC power source,
A heating current value measuring step of measuring the current value of the heating current by receiving the heating current detection signal detected by the microcomputer through the heating current detection unit if the heating period is a period,
If the heating current value is measured, the microcomputer checks whether the measured heating current value is smaller than a preset reference current value to determine whether the heater is in contact failure.
Determining whether the number of contact failures during the period exceeds a predetermined reference count by counting the number of contact failures during a predetermined period if the contact failure is determined to be the contact failure;
And stopping the heating operation when the measured heating current value is less than the reference current value and the contact failure number is greater than the reference number. A method for preventing fire by arc interruption of a device.
A heating cycle judging process of detecting whether the micom is a heating cycle based on the frequency of the AC power source,
A heating current value measuring step of measuring the current value of the heating current by receiving the heating current detection signal detected by the microcomputer through the heating current detection unit if the heating period is a period,
If the heating current value is measured, the microcomputer checks whether the measured heating current value is smaller than a preset reference current value to determine whether the heater is in contact failure.
And stopping the heating operation when the measured heating current value is less than the reference current value and the microcomputer determines that the contact is defective,
The microcomputer,
The peak value of the AC power source is detected by the internal clock in addition to the process of determining the contact failure, and when the detected peak value is out of a certain range or more than the stored reference peak value, it is determined that there is an abnormality in the clock, Further comprising a microcomputer overheat prevention step of performing the heating operation stopping step.
24. The method of claim 23,
The microcomputer,
Further comprising a microcomputer overheat mode releasing step of releasing the superheat mode and initiating a heating operation when the detected peak value is within a predetermined range of the reference peak value after the microcomputer overheating prevention process, Fire prevention method by interruption.

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