KR101957564B1 - Temperature controller with enhanced fire protection function - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a temperature regulator used for an electro-thermal bedding such as an electric bed, an electric bed, an electric mat, an electric fomentation apparatus or the like, or a temperature regulator used for various electric heaters, Preventing the fire of the temperature controller due to SCR heat by detecting the heat due to arc caused by short circuit due to overheating and burning of the switching controlled SCR (Silicon Controlled Rectifier) To an enhanced temperature controller.

Description

{TEMPERATURE CONTROLLER WITH ENHANCED FIRE PROTECTION FUNCTION}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a temperature regulator used for an electro-thermal bedding such as an electric bed, an electric bed, an electric mat, an electric fomentation apparatus or the like, or a temperature regulator used for various electric heaters, Preventing the fire of the temperature controller due to SCR heat by detecting the heat due to arc caused by short circuit due to overheating and burning of the switching controlled SCR (Silicon Controlled Rectifier) To an enhanced temperature controller.

Generally, electro-thermal bedding (heating device) such as electric bed, electric bed, electric mattress, electric fomentation, etc. is used for warming a living room or a bedroom. Such a heat transfer bedding is a device using heat generated by the electric resistance of a heat wire, and includes a mat having a built-in heating wire, a temperature for regulating a heating temperature according to a user's setting by supplying an AC power to the mat stably, Regulators are available in one set.

Electric heating bedding is one of the closest household appliances used in the home. It can be made by fire due to overheat or arc caused by local heat of heating wire, disconnection or short circuit, etc., It is more important than fire prevention to shut off the power supplied to the heat line after detecting the occurrence of the abnormality in advance.

Accordingly, recently introduced thermostats require more enhanced safety functions. For example, in addition to the basic function of automatically controlling the heating temperature and operating time corresponding to the human body's harmful electromagnetic wave interception function, sleeping or normal use selection mode, it is possible to prevent local fire, And the function of cutting off the current supplied to the hot wire in the event of overheating due to heat, etc.

However, in the conventional temperature controller according to the related art, only a safety device for preventing fire due to disconnection or short circuit of the hot wire is provided, and various components built in the temperature controller, in particular, There is not provided a device that can detect the heat due to the arc generation due to the overheat and the short circuit due to burnout of the SCR (Silicon Controlled Rectifier) that switches the power supplied to the hot wire, There was a problem of being exposed unprotected to the occurrence.

KR 10-0938713 B1, 2010. 01. 18. p4 ~ p7, Figure 1 KR 10-1083361 B1, 2011. 11. 08. p3 ~ p4, Figure 1 KR 10-1064351 B1, 2011. 09. 05. p3 ~ p5, Figure 1

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in order to solve the problems of the related art, and it is an object of the present invention to provide an arc control circuit for controlling an arc (arcing) caused by a short circuit due to overheating and burnout of a silicon controlled rectifier (SCR) The present invention provides a temperature controller having a fire prevention function capable of preventing a fire of a temperature controller due to heat generation of the SCR in advance by detecting a heat generated due to the occurrence of a fire.

In addition, the present invention provides a fire prevention function capable of preventing a fire by the hot wire by shutting off the power after double detection of an abnormality due to local overheating, disconnection or short-circuit of a heat ray installed inside the mat, There are other purposes to provide a regulator.

According to an aspect of the present invention, there is provided an AC power supply system including an AC-DC converter for converting AC power supplied through a power cord into DC power, a rectifier for stabilizing the AC power, A power supply unit including a power supply unit for supplying the half-wave power to the hot wire via a SCR (Silicon Controlled Rectifier); A microcomputer operated by the DC power source converted through the AC-DC converter and controlling the power supplied to the hot wire through the SCR according to a predetermined operation time; And a thermal fuse connected to an output terminal connected to the heat line for sensing the heat generation of the hot wire and a thermal fuse for sensing the heat generated by the heat generating resistor and interrupting the half-wave power supplied from the SCR to the output terminal. Wherein the thermal resistor, the thermal fuse, and the SCR are molded in one piece to form a module and are integrally modularized.

The microcomputer may further include a current sensor connected in series to the middle of the hot wire through the output terminal to detect a current change due to a short-circuit or a short-circuit of the hot wire and transmit the sensed current to the microcomputer. And controls the operation of the SCR in response to the detection signal of the SCR to intermittently supply the half-wave power supply to the output stage through the SCR.

In addition, the current sensor may include a current transformer formed of a choke coil.

And a polarity checking unit for detecting a polarity of the power cord connected to the socket, and a polarity checking unit for checking whether the polarity of the power cord matches the polarity of the polarity sensing unit, The checking unit is turned on when the polarity of the power cord matches the circuit polarity of the polarity sensing unit, and is turned off when the polarity of the power cord and the polarity of the polarity sensing unit do not match. .

Also, the electromagnetic wave confirmation display unit may further include a ground line connecting the ground terminal and the output terminal resistance of the polarity sensing unit, and the ground line may have a length of 10 cm to 100 cm.

As described above, the temperature regulator according to the present invention modularizes a thermal fuse, an exothermic resistance, and a SCR into a single mass and integrally modulates the heat, thereby generating heat due to arc generation due to overheating and short circuit of the SCR, It is possible to detect in advance through the resistor and the thermal fuse, thereby preventing the fire due to the SCR, thereby preventing the fire of the temperature regulator.

Further, the temperature controller according to the present invention includes a heating resistor and a thermal fuse installed at an output terminal to which a hot wire is connected, and detects the overheating of the hot wire through the heating resistor and the thermal fuse in advance, Fire can be prevented.

In the temperature controller according to the present invention, a current transformer applying and developing a choke coil is connected in series to the middle end of a hot wire, and when a disconnection or a short circuit occurs at any position of the hot wire, a change in the current flowing through the hot wire is detected, It is possible to prevent the fire due to the disconnection or short circuit of the hot wire.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view for explaining a temperature controller according to an embodiment of the present invention; FIG.
2 is an equivalent circuit diagram of the temperature regulator shown in Fig.
Fig. 3 is an enlarged circuit diagram of the power supply unit shown in Fig. 2. Fig.
4 is an enlarged circuit diagram of the microcomputer shown in Fig.
5 is an enlarged circuit diagram of the hot-wire anomaly detection unit shown in Fig.
6 is a view for explaining the molding process of the heat resistance, the thermal fuse and the SCR shown in Fig. 1; Fig.

The temperature controller according to the present invention prevents a fire due to an arc caused by a short circuit due to overheating and burnout of a SCR (Silicon Controlled Rectifier) mounted on a printed circuit board built in a temperature controller , A triple safety device is provided to prevent fire from local overheating, disconnection or short circuit of the hot wire built in the mat.

The temperature regulator according to the present invention modularizes a thermal fuse, an exothermic resistance, and a SCR into a mass by molding by using an insulator to integrally modulate the exothermic heat generated by the arc caused by the overheating and the short circuit of the SCR, It is pre-sensed through a thermal fuse, which prevents SCR fires and prevents the fire of thermostats.

Further, the temperature controller according to the present invention includes a heating resistor and a thermal fuse installed at an output terminal to which a hot wire is connected, and detects the overheating of the hot wire through the heating resistor and the thermal fuse in advance, Fire can be prevented.

In the temperature controller according to the present invention, a current transformer applying and developing a choke coil is connected in series to the middle end of a hot wire, and when a disconnection or a short circuit occurs at any position of the hot wire, a change in the current flowing through the hot wire is detected, Disconnect the supplied power.

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

FIG. 1 is a view for explaining a temperature controller according to an embodiment of the present invention, and FIG. 2 is an equivalent circuit diagram of the temperature controller shown in FIG.

1 and 2, a temperature controller 10 according to an embodiment of the present invention includes a power supply unit 11, a microcomputer 12, and a hot-wire anomaly detection unit 13 for detecting the occurrence of an anomaly- do.

3 is an enlarged circuit diagram of the power supply unit shown in Fig.

Referring to FIGS. 2 and 3, the power supply unit 11 includes an AC-DC converter 111 for receiving a commercial commercial AC power source 220V and converting the supplied commercial AC power source 220 into a DC power source of about 5V, a rectifying unit for rectifying and stabilizing the commercial commercial AC power source And a power supply unit 113 for supplying the stabilized half-wave power through the rectifying unit 112 to the unshielded heating wire through the switching operation of the SCR (SCR).

4 is an enlarged circuit diagram of the microcomputer shown in FIG.

Referring to FIGS. 2 to 4, the microcomputer 12 controls a power source supplied through a SCR (SCR) according to a preset program (operation time, temperature, etc.) by a user. That is, the SCR (SCR) of the power supply unit 113 operates by receiving the trigger pulse TRIGGER L output from the microcomputer 12 to supply or cut off the half-wave power by the unshielded heating wire.

The microcomputer 12 receives the DC voltage by the switching operation of the operation switching unit 14 and operates (Tunr-ON / OFF). The operation time set by the operation time setting unit 15 and the operation time set by the temperature setting unit 16 ) Controls the operation of SCR (SCR) according to the set temperature of each mode (sleep mode / normal mode / high temperature mode) At this time, the temperature setting unit 16 sets the set temperature for each mode corresponding to the resistance ratio of the volume switch VR.

The microcomputer 12 receives the DC voltage of about 5 V according to the operation of the operation switching unit 14 and operates to set the data (operation time, temperature, temperature) set by the operation time setting unit 15 and / Etc.) to each port. At this time, when the microcomputer 12 is operated by the operation switching unit 14, the power indicator D9 is turned on and the operation time set by the operation time setting unit 15 corresponds to 3h / 6h / 9h And the setting display lights D5, D8 and D10 are turned on, respectively.

Subsequently, the SCR (SCR) of the power supply unit 113 is operated by the trigger pulse TRIGGER L of the microcomputer 12 and the half-wave power source of approximately 156 V rectified by the rectifying unit 112 is connected to the hot wire anomaly detection unit 13 To the output terminal 17. Accordingly, the half-wave power is supplied to the half-wave power source through the output terminal 17, and the half-wave power source is heated to a temperature corresponding to the set temperature.

5 is an enlarged circuit diagram of the hot wire anomaly detection unit shown in Fig.

2 to 5, the hot-wire anomaly detection unit 13 includes a heat-generating resistor 131 connected to an output terminal 17 for sensing the heat generation of the heat- A temperature fuse 132 for interrupting the half-wave power outputted to the output terminal 17 through the SCR (SCR), and a temperature fuse 132 connected in series with the non-magnetic heat line through the output terminal 17 to change the current due to the disconnection or short- And a current sensor 133 for detecting the current signal and transmitting the detected current signal to the microcomputer 12.

The thermal fuse 132 is connected in series between the power supply terminal H1 of the output stage 17 and the output terminal of the SCR SCR and is connected to the heat generated in the heat generating resistor 131 connected in parallel to the power supply terminals H1 and H2 To cut off the half-wave power supplied from the SCR (SCR) to the power supply terminal H1.

The current detector 133 includes a current transformer composed of a choke coil which is mounted on an AC power input terminal and used as an electric field reduction device and is connected to the current detection terminals H3 and H4 of the output terminal 17, To the microcomputer 12, a sensing signal corresponding to a change in the current flowing through the unshielded heating wire when the unshielded heating wire is disconnected or short-circuited.

The microcomputer 12 controls the operation of the SCR (SCR) in response to the change in the current of the unheated hot wire sensed by the current sensor 133. [ For example, when the current flowing through the unshaped heating line changes abnormally due to the disconnection or short-circuit of the unshaped heating wire, the operation of the SCR (SCR) is controlled so that the power supply terminal H1 of the output stage 17 via the SCR Wave power supply that is supplied to the power supply unit 30.

In this way, in the present invention, the overheat of the unshaped hot wire is sensed through the heating resistor 131 and the thermal fuse 132 of the hot wire abnormality sensing unit 13, and the current sensor 133 composed of the choke coil It is possible to prevent a fire due to overheating of the unheated hot wire and the occurrence of an arc by detecting an abnormality caused by disconnection or short circuit of the hot wire.

Meanwhile, the temperature controller 10 according to the embodiment of the present invention may further include an electromagnetic wave confirmation display unit 18.

The electromagnetic wave confirmation display unit 18 is for checking whether the polarity of an outlet (not shown) to which the power cord 19 of the temperature controller 10 is connected matches the circuit polarity of the temperature controller 10, It is known that electromagnetic waves are generated when the polarity of the polarity and the circuit polarity do not coincide with each other, and the electromagnetic wave is decreased when the polarities are not equal to each other.

Accordingly, the electromagnetic wave confirmation display unit 18 includes a polarity sensing unit 181 for sensing the polarity of the power cord 19 connected to the outlet, and a polarity sensing unit 181 for sensing the polarity of the power cord 19 And a polarity checking unit 182 for determining whether or not the polarity of the portion 181 matches.

The polarity verifying unit 182 is turned on when the polarity of the power cord 19 matches the circuit polarity of the polarity sensing unit 181. When the polarity of the power cord 19 does not match, (D2) to provide a match between the polarity of the current source cord (19) and the polarity of the polarity sensing unit (181).

As described above, in the present invention, whether or not the polarity of the power cord 19 and the circuit polarity of the polarity sensing unit 181 are identical or not is determined in real time through the electromagnetic wave confirmation display unit 18, It is possible to change the connecting direction of the power cord 19 connected to the socket and to minimize or prevent the generation of electromagnetic waves due to different polarities by matching the polarities.

1 and 2, it is preferable that the length of the ground line 184 connecting the ground terminal 183 and the output terminal resistance R8 of the polarity sensing unit 181 is increased, . For example, the ground wire 184 may have a length in the range of 5 cm to 100 cm, and it is confirmed that the electromagnetic wave shielding effect is excellent as the length increases. When the length is long, the ground wire 184 is wound in the form of a coil, As shown in FIG.

As shown in FIG. 1, the temperature controller 10 according to the embodiment of the present invention includes a heating resistor 131, a resistor R, and a resistor R to prevent a fire due to an arc due to a short circuit due to overheating and burnout of the SCR (SCR) The thermal fuse 132 and the SCR (SCR) are molded by molding into a single mass and are integrally modularized.

1, the heat generating resistor 131, the thermal fuse 132, and the SCR (SCR) are integrally molded by molding using an insulator such as silicone, epoxy, or the like, The SCR (SCR) or the heat generated by the heating resistor 131 rapidly rises and is transferred to the thermal fuse 132. As a result, And the power supplied to the heat-resistant heat conductor is cut off.

FIG. 6 is a view for explaining the process of molding the heat resistance, the thermal fuse and the SCR shown in FIG. 1, in which the heat generating resistor 131, the thermal fuse 132 and the SCR (SCR) Before being mounted on the circuit board 1, they are adhered to each other for easy work and then inserted into the mold. Then, a synthetic resin such as silicon or epoxy is injected into the mold to modularize the heat generating resistor 131, the thermal fuse 132, and the SCR (SCR) in one lump.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

10: thermostat 11: power supply
12: Micom 13: Hot wire abnormality sensing unit
14: Operation switching unit 15: Operation time setting unit
16: Temperature setting section 17: Output terminal
18: Electromagnetic wave confirmation display 19: Power cord
111: AC-DC converter 112: rectifying part
113: power supply unit 131: heating resistance
132: Thermal fuse 133: Current sensor
181: polarity detecting unit 182: polarity checking unit
183: ground terminal 184: ground wire
SCR: SCR

Claims (5)

An alternating-current (DC) converter for converting an AC power supplied through a power cord into a DC power source, a rectifier for stabilizing the AC power source, and a half-wave power source stabilized through the rectifier for supplying the stabilized half-wave power through a silicon controlled rectifier A power supply unit including a power supply unit for supplying power to the power supply unit;
A microcomputer operated by the DC power source converted through the AC-DC converter and controlling the power supplied to the hot wire through the SCR according to a predetermined operation time;
And a thermal fuse connected to an output terminal connected to the heat line for sensing the heat generation of the hot wire and a thermal fuse for sensing the heat generated by the heat generating resistor and interrupting the half-wave power supplied from the SCR to the output terminal. Sensing unit; , ≪ / RTI &
The thermal resistor, the thermal fuse, and the SCR are adhered to each other, inserted into a metal mold, synthetic resin is inserted into the metal mold, and the heat resistance, the thermal fuse and the SCR are molded into a lump, Mounting on a printed circuit board,
Which is characterized by a fire prevention function.
The method according to claim 1,
The microcomputer may further include a current sensor connected in series to the middle of the hot wire through the output terminal to sense a current change due to a short-circuit or disconnection of the hot wire and transmit the detected current change to the microcomputer. Wherein the controller controls the operation of the SCR in response to the signal to intermittently supply the half-wave power supplied to the output terminal through the SCR.
3. The method of claim 2,
Characterized in that the current sensor comprises a current transformer comprised of a choke coil.
4. The method according to any one of claims 1 to 3,
A polarity sensing unit for sensing the polarity of the power cord connected to the socket; and a polarity checking unit for determining whether the polarity of the power cord matches the polarity of the polarity sensing unit, And an indicator that turns on when the polarity of the power cord matches the circuit polarity of the polarity sensing unit and turns off when the polarity of the power cord does not match the circuit polarity of the polarity sensing unit Features a thermostat with enhanced fire protection.
5. The method of claim 4,
Wherein the electromagnetic wave confirmation display unit further includes a ground wire connecting the ground terminal and the output terminal resistance of the polarity sensing unit, and the ground wire has a length of 10 cm to 100 cm.

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