KR20210117518A - Fixed temperature detector with self test function - Google Patents

Abstract

The present invention relates to a constant temperature sensor with a check function that the operating state can be checked even without using a separate tester. The sensor includes: a temperature sensor having electrical characteristics changing in response to the ambient temperature; a microcomputer generating a temperature signal having a magnitude corresponding to the changed electrical characteristics of the temperature sensor, comparing the generated temperature signal to a reference value, and outputting a predetermined fire detection signal in a case where the temperature signal crosses the reference value; a first power supply unit allowing the microcomputer to operate by adjusting a voltage supplied from a main power supply and applying a basic voltage to the microcomputer; a heating element disposed near the temperature sensor and generating heat to at least the temperature corresponding to the reference value when a heating voltage is applied; a second power supply unit applying the heating voltage to the heating element; and a check switch turning on or off the heating voltage application to the heating element.

Description

FIXED TEMPERATURE DETECTOR WITH SELF TEST FUNCTION

The present invention relates to a constant temperature sensor, and more particularly, to a constant temperature sensor having a self-check function. In particular, such a constant temperature sensor is designed to be explosion-proof to be installed and operated in a space separated from the outside.

In general, a fire detector for detecting the occurrence of a fire as a kind of disaster prevention or firefighting equipment is installed on a ceiling or wall surface of a specific space. As a kind of such a fire detector, there is a constant temperature detector that outputs a specific fire detection signal when a temperature greater than or equal to a preset reference temperature is sensed. This fire detection signal of the constant temperature detector is transmitted to the fire alarm, and the fire alarm outputs an alarm indicating the occurrence of a fire.

These constant temperature sensors must be able to accurately detect a temperature exceeding the reference temperature at any time, so they must always be operating normally. Accordingly, equipment for testing whether the constant temperature sensor is operating normally is provided.

On the other hand, as an example of such a test equipment, there may be mentioned Patent Registration No. 10-1927781 (name: constant temperature explosion-proof sensor tester) (hereinafter referred to as the prior art). The tester of the prior art, as shown in Figure 1, the upper portion is open and the casing portion 130 to which the control line is connected; a heat transfer unit 120 having a lower side inserted into the casing and an insertion unit such that the sensing unit protruding downward of the sensor is inserted; a cover unit 110 coupled to the casing so as to be disposed on the outer side of the heat transfer unit; a coil unit 160 coupled to the insertion unit to generate heat according to control power; and a heat transfer medium (150) accommodated inside the insertion unit and disposed to surround the outer periphery of the sensing unit as the water level rises according to the insertion of the sensing unit, and to evenly transfer the heat generated from the coil unit to the sensing unit in a conductive manner; consists of including

In operation, after the administrator operates the coil unit 160 of the testing machine to generate heat, and then covers the constant temperature sensor 101 to be tested with the cover portion 110, heat from the inside of the testing machine is transferred to the constant temperature sensor 101 ), and thereafter, if the constant temperature sensor 101 outputs an alarm in response to the heat, it is determined that the constant temperature sensor 101 is operating normally.

However, in the test method using such a tester according to the prior art, a tester, which is a separate device, must be prepared, and the administrator takes this tester directly to each place where each constant temperature sensor is installed and brings it directly to each constant temperature sensor. It's uncomfortable to see. In addition, since the tester operates using a battery, it is necessary to prepare a large and heavy battery, to transport the battery to each test site together with the tester, and to frequently charge or replace the battery.

Accordingly, there has been a demand for a method capable of testing the operating state of a constant temperature sensor without using a separate tester.

The present invention, in response to the above-mentioned needs, in a constant temperature sensor connected alone or in plurality in a space separated from the outside, it is possible to check the operation state of the constant temperature sensor without using a separate tester. We would like to provide a solution.

A constant temperature sensor having a check function according to an embodiment of the present invention for achieving the above object includes: a temperature sensor whose electrical characteristics change in response to ambient temperature; A temperature signal having a magnitude corresponding to the changed electrical characteristic of the temperature sensor is generated, the generated temperature signal is compared with a reference value, and when the temperature signal crosses the reference value, a predetermined fire detection signal a microcomputer that outputs; a first power supply unit that adjusts a voltage supplied from a main power supply and applies a basic voltage to the microcomputer, thereby enabling the microcomputer to operate; a heating element disposed in the vicinity of the temperature sensor and generating heat above a temperature corresponding to the reference value when a heating voltage is applied; a second power supply unit for applying the heating voltage to the heating element; and a check switch for turning on or off the application of the heating voltage to the heating element.

Here, the heating voltage may be a voltage supplied from an auxiliary power source separate from the main power source, or a voltage supplied from the main power source.

In addition, the first power supply unit and the second power supply unit may be a single component.

In particular, the heating element may be a PTC resettable fuse.

On the other hand, the constant temperature sensor, all components except for the conductors for connection with the main power and auxiliary power and the conductors for outputting the fire detection signal, or components with a possibility of fire or explosion, the explosion-proof case It may be an explosion-proof structure surrounded by

In addition, the constant temperature sensor having a check function according to another embodiment of the present invention for achieving the above object, in addition to the above structure, the microcomputer further includes an external interrupt terminal, in particular , it may be implemented to output the fire detection signal when a predetermined signal is input to the external interrupt terminal.

In this case, it may further include a manually operable switch to input the external interrupt signal.

In addition, the constant temperature sensor having a check function according to another embodiment of the present invention for achieving the object as described above, a temperature sensor for detecting the surrounding temperature, and the temperature sensed through the temperature sensor is a reference a heating element having a microcomputer for outputting a fire detection signal when the temperature is higher than the temperature, the heating element being disposed in the vicinity of the temperature sensor and generating heat above the reference temperature when a heating voltage is applied; It may be configured to further include a check switch for turning on or off the application of the heating voltage to the heating element.

In this case, the heating element may be a PTC resettable fuse.

In particular, the microcomputer may further include a switch configured to input a predetermined signal to an external interrupt terminal that triggers the fire detection signal.

The constant temperature sensor having a check function according to the present invention as described above enables the operation state of the constant temperature sensor to be checked only by a simple switching operation without using a separate tester having a heating function.

1 is a view showing a schematic structure of a constant temperature explosion-proof sensor tester according to the prior art.
2 is a view schematically showing the external appearance and arrangement of a temperature sensor inside a constant temperature sensor having a check function according to an embodiment of the present invention.
3 is a view schematically showing an outer shape of a circuit board and arrangement of a heating element of a constant temperature sensor having a check function according to an embodiment of the present invention.
4 is a block diagram for explaining the components of a constant temperature sensor having a check function according to an embodiment of the present invention.
5 is a diagram showing a circuit configuration for implementing the basic function of a constant temperature sensor having a check function according to an embodiment of the present invention.
6 is a diagram illustrating a method of connecting a fire alarm to operate a constant temperature sensor having a check function according to an embodiment of the present invention.
7 is a circuit diagram illustrating a method of implementing a check function using an interrupt terminal of a microcomputer in a constant temperature sensor having a check function according to another embodiment of the present invention.

Hereinafter, a preferred embodiment of a constant temperature sensor having a check function according to the present invention will be described with reference to the accompanying drawings. For reference, since the terms referring to each component of the present invention are named by way of example in consideration of their functions, they should not be understood as predicting and limiting the description of the present invention by the terms themselves.

First, with reference to FIG. 2 , an external shape of a constant temperature sensor having a check function according to an embodiment of the present invention and a structure in which a temperature sensor and a heating element are disposed inside the constant temperature sensor will be schematically described. The constant temperature sensor 10 according to the present invention, as shown in FIG. The other side (or the front side) is configured to be exposed in a rod shape (in the figure, the pillar portion 18). The explosion-proof enclosure may be installed, for example, on a wall or ceiling of a fire detection target area, and therefore, the pillar portion 18 is disposed to face the detection target area. At the distal end of the pillar portion 18, a slightly more protruding sensing portion 19 is formed.

The explosion-proof constant temperature sensor 10 is disposed in a space that can be separated from the outside, and is configured to detect high heat caused by fire or the like in the space. For example, it may be installed in a box-type space in which mechanical equipment for performing a predetermined process is installed, and may be installed to detect a fire caused by the mechanical equipment. Meanwhile, a fire alarm installed alone may be provided in the space, and the explosion-proof constant temperature sensor 10 and the fire alarm may be connected to each other in a one-to-one manner to mutually operate. Of course, two or more explosion-proof constant temperature detectors 10 may be installed in the space, and they may be connected to each other in parallel or in series to be coupled to the fire alarm. The fire alarm may be implemented to be connected to a remote central management device to communicate a fire detection situation. In the following description, the explosion-proof constant temperature sensor with the inspection function of the present invention will be abbreviated as "sensor".

On the other hand, when explaining the internal structure of the sensing unit 19, as shown in (b) of FIG. 2, the temperature sensor 16 is disposed. With this configuration, heat generated in the sensing target area is transferred to the sensing unit 19 , and heat conducted through the material of the sensing unit 19 to the inside of the sensing unit reaches the temperature sensor 16 . The temperature sensor may be a component whose electrical characteristics (eg, electrical resistance) change according to the temperature, and the microcomputer 15 provided in the detector 10 detects the changed electrical characteristics to measure the change in temperature. there will be When it is sensed that the measured temperature is higher than or equal to the preset reference temperature, the microcomputer 15 considers that a fire has occurred in the detection target area and outputs a predetermined fire detection signal.

Meanwhile, according to the present invention, the heating element 14 is disposed in the inside of the sensing unit 19 , adjacent to the temperature sensor 16 , preferably in contact with one side of the temperature sensor 16 . The heating element 14 is a component that generates heat when power is applied by a manual operation of an administrator who wants to check the state of the constant temperature sensor 10 , and the heat generated from the heating element 14 is transmitted to the temperature sensor 16 . is structured to be

According to the present invention, by adding such a heating element 14, there is no need to bring a separate tester to the outside of the constant temperature sensor (this eliminates the need to prepare a tester), only operating the heating element 14 to test the status of the temperature sensor.

Next, with reference to FIG. 3, the form of the circuit board of the constant temperature sensor having a check function according to an embodiment of the present invention will be described. With reference to the shape of the circuit board, the arrangement of the temperature sensor and the heating element will be further described.

The circuit board 2 is similar to the cross-sectional shape of the constant temperature sensor 10 shown in FIG. 2 . On the circuit board 2, components 5 and wirings constituting various components for operating the constant temperature sensor 10 of the present invention are arranged. One side of the circuit board 2 is configured to be exposed to the outside from the rear of the constant temperature sensor, and may be provided with at least two contacts that can be connected to an external power source. Each of the contact points may have two conductive wires for connection with an external power source, respectively.

On the other hand, the other side of the circuit board 2 may pass through the inside of the cylindrical column part 18 of the constant temperature sensor and extend toward the end of the sensing part 19 . In particular, a temperature sensor 16 may be disposed at the other end of the circuit board 2 , and the temperature sensor 16 enters the inside of the sensing unit 19 and is installed to contact the inner wall of the sensing unit 19 . can be On the other hand, a heating element 14 may be additionally disposed at the other end of the circuit board 2 . Since the heating element 14 is for directly heating the temperature sensor 16 , the heating element is also a sensing unit 19 . ) can be arranged to enter the inside. Preferably, the heating element 14 may contact one side of the temperature sensor 16 .

At the lower end of FIG. 3 , in the circuit board 2 , the portion where the temperature sensor 16 and the heating element 14 are arranged is shown. As shown in the figure on the right, it may be configured in a split form at the distal end of the substrate 2 , and the temperature sensor 16 connected to the electrodes 16-1 and 16-2 may be disposed between the cracks. In addition, by bonding both ends of the heating element 14 to the electrodes 12-1 and 14-2 disposed on the substrate on both sides of the cracked portion, respectively, the heating element can be disposed so as to be in contact with the temperature sensor.

Next, with reference to the block diagram of FIG. 4, the components and functions of the constant temperature sensor having a check function according to an embodiment of the present invention will be described. The constant temperature sensor 10 having a check function according to the present invention includes a first power supply unit 11 , a microcomputer 15 , a temperature sensor 16 , a second power supply unit 12 , and a check switch 13 . ) and a heating element 14 .

The first power supply unit 11 may be connected to the main power supply for supplying power for operating the temperature sensing function of the constant temperature sensor through the conductors 11-1 and 11-2, configured to generate a base voltage of a predetermined voltage. The basic voltage is at least a voltage for operating the microcomputer 15 . The basic voltage includes, for example, a voltage for operating the internal functional unit of the microcomputer 15 and/or a voltage serving as a reference voltage of the AD converter (excluding the voltage for operating the heating element described below). It can be understood to include all kinds of voltages necessary to realize the temperature sensing function of the constant temperature sensor.

The temperature sensor 16 is a component whose electrical characteristics change in response to ambient temperature. The electrical characteristic herein may be, for example, electrical resistance.

The microcomputer 15 is a control element that realizes the temperature sensing function of the constant temperature sensor 10 according to the present invention, and can periodically monitor the electrical characteristics of the temperature sensor 16, and corresponds to the size of the changed electrical characteristics. generates an electrical signal (that is, a temperature signal), compares the generated temperature signal with a preset reference value, and when the temperature signal becomes greater than the reference value (or when the temperature signal is lower than the reference value), the constant temperature sensor 10 is A fire detection signal can be output by considering that a fire has occurred in the installed monitoring target space.

The fire detection signal output from the microcomputer 15 turns on a separate light emitting diode (for example, the LED 17), or an external (for example, a fire alarm (not shown) not)) can be transmitted.

Meanwhile, in the above description, if the temperature sensor 16 is designed to reduce electrical resistance as the surrounding temperature increases, the microcomputer 15 will output a fire detection signal when the value of the temperature signal becomes lower than the reference value. Conversely, if the temperature sensor 16 is designed to increase the electrical resistance as the ambient temperature increases, the microcomputer 15 will output a fire detection signal when the value of the temperature signal becomes higher than the reference value. Here, the phenomenon in which the value of the temperature signal is higher than the reference value and then becomes lower than the reference value, and the phenomenon in which the value of the temperature signal is in the state lower than the reference value and becomes larger than the reference value, is referred to as “the temperature signal crosses the reference value ( cross) is defined.

The second power supply unit 12 may be connected to an auxiliary power source, which is a separate power source from the main power source, through the conductors 12-1 and 12-2, and generates a heating voltage of a predetermined voltage from the power supplied from the auxiliary power source. configured to create The heating voltage is connected to the heating element 14 to operate (ie, generate heat) the heating element 14 .

The heating element 14 is a component that generates heat as a predetermined voltage, that is, the heating voltage is supplied, and may be, for example, a PTC resettable fuse. By using a PTC resettable fuse as a heating element, even when the check switch is kept on for a long period of time or when the check switch is fixed in the on state, the heating element 14 is kept at a preset temperature (i.e., of the PTC resettable fuse). When the temperature is determined by the characteristic), the voltage and/or current can be automatically cut off, so that the heating operation can be stopped safely.

The inspection switch 13 is a switch capable of turning on or off the heating voltage applied to the heating element 14 from the second power supply unit 12 , and is preferably configured such that an administrator can manually operate it. That is, the inspection switch 13 is provided to be manually operated only when the administrator wants to inspect the constant temperature sensor 10 .

Meanwhile, in the description of the present invention, the first power supply unit 11 and the second power supply unit 12 have been described as being connected to the main power supply and the auxiliary power supply, respectively (that is, the main power supply for supplying the basic power and the heating voltage (Auxiliary power supply for supplying is separately provided), the second power supply unit 12 may also be connected to the main power supply. That is, the constant temperature sensor of the present invention may be driven using a single power source.

Next, with reference to the circuit diagram provided in FIG. 5 , a circuit configuration for implementing each function that can be provided by the constant temperature sensor having a check function according to an embodiment of the present invention will be described. Terms in the description with reference to FIG. 5 may be slightly different from other drawings, but those skilled in the art with reference to the function of each component will be able to fully understand by appropriately relating the different terms.

A circuit for inputting a basic voltage is shown in the upper part of the figure. This may correspond to the first power supply unit 11 . When an external voltage of, for example, 24V is applied from the main power supply, it may be converted into a voltage of 3.3V and provided to the respective components.

1) Detector input line: The sensor input line is also where the sensor power is supplied and indicates the output.

2) Input line protection element: It is composed of a varistor and protects the detection circuit from the disturbance coming from the input side.

3) Power supply circuit: By composing a bridge circuit using diodes, the detector operates normally even if the polarity of the input voltage is changed. With this structure, even if the leads 11-1 and 11-2 of the first power source of the constant temperature sensor are connected to the polarity of the main power supply opposite to the polarity of the main power, the constant temperature sensor can operate normally.

4) Power supply constant voltage circuit: Stabilizes the input voltage by lowering it to the voltage to be supplied to the detector circuit.

On the other hand, the left middle of FIG. 5 shows a circuit for generating and supplying an additional voltage required to perform AD conversion in the microcomputer. That is, 5) a constant voltage circuit for AD conversion power supply.

Also, on the right side of the upper circuit of FIG. 5 , an LED 17 configured to emit light when the fire detection signal SIG is output is shown. On the other hand, according to this circuit, when the fire detection signal (SIG) is generated, the switching element is operated to operate the LED, thereby generating a fire alarm. In addition, it may be implemented to turn on the power of the fire alarm when the LED operates or when a fire detection signal (SIG) is generated.

6) Output circuit: It receives the output of the microprocessor that detected the temperature and stabilizes it. Turn on the LED to monitor. At this time, the output is maintained until the current is cut off.

A circuit including a microcomputer, a temperature sensor, and a heating element is shown at the bottom of FIG. 5 . The microcomputer compares the temperature signal related to the electrical resistance of the temperature sensor with a preset reference value, and when the value of the temperature signal crosses the reference value, it outputs a fire detection signal (SIG). Here, a heating element 14 (TF) is disposed in the vicinity of the temperature sensor 16 (TH).

7) Temperature detection circuit: A thermistor whose resistance value changes according to temperature is configured in series with a fixed resistance value to indicate an output value corresponding to the temperature change.

8) Microprocessor circuit: It receives the voltage output from the temperature detection circuit, compares it with the set detection temperature value through AD conversion, and determines whether to output to the output circuit by the program and outputs it.

Next, with reference to FIG. 6 , an example of a connection relationship connected to a fire alarm in order to actually operate the constant temperature sensor having a check function according to an embodiment of the present invention will be schematically illustrated and described.

The connection between the constant temperature sensor 10 and power sources is, for example, among the conductors shown in FIG. 3, the conductors 11-1 and 11-2 are connected to the main power supply, and the conductors 12- 1 and 12-2) are made in such a way that they are connected to the auxiliary power source. In the drawings, the first power supply unit generating the basic voltage and the second power unit generating the heating voltage are omitted.

The basic voltage generated from the main power is input to the microcomputer 15 , and the microcomputer 15 may receive a temperature signal from the temperature sensor 16 and output a detection signal. The detection signal operates the switching element, whereby the light emitting diode 17 emits light, and when the light emitting diode 17 operates, the fire alarm may operate at the same time.

Meanwhile, to the heating element 14 disposed adjacent to the temperature sensor 16 , a voltage from an auxiliary power source may be connected through the check switch 13 . When the inspection switch 13 is turned on, the heating element 14 generates heat, and when the inspection switch 13 is turned off, the heating element 14 does not generate heat.

Here, the voltage from the auxiliary power source may be converted into a basic voltage and applied to the microcomputer 15. In this case, the operation of the check switch 13 may be configured to operate a relay capable of cutting off the supply of the main power. have. In this configuration, when the check switch 13 is operated, the microcomputer 15 is not operated by the voltage from the main power supply, but is operated by the voltage from the auxiliary power supply.

In addition, in another embodiment of the constant temperature sensor having a check function according to the present invention, even if the heating element 14 is not provided, the same self-check function by installing a switch in the external interrupt terminal of the microcomputer 15 is configured to implement 7 is a circuit diagram schematically showing such a structure.

Referring to the drawing, a connector CN2 connected to the interrupt terminal of the microcomputer 15 can be seen, and a switch, for example, a push switch, can be connected to this connector (not shown). The push switch may be manually operated by an administrator, and an interrupt signal of a predetermined voltage is input to the microcomputer 15 by the operation of the switch, and the microcomputer 15 outputs a fire detection signal (SIG) based on the interrupt signal. do.

According to this configuration, it is possible to check the state of the constant temperature sensor 10 only by a simple switch operation by an administrator, so maintenance is convenient.

The embodiments of the present invention described above are merely illustrative of the technical idea of the present invention, and the protection scope of the present invention should be interpreted by the following claims. In addition, various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains, and all technical ideas within the scope equivalent to the present invention are should be construed as being included in the scope of the rights of

Claims (10)

a temperature sensor whose electrical characteristics change in response to ambient temperature;
A temperature signal having a magnitude corresponding to the changed electrical characteristic of the temperature sensor is generated, the generated temperature signal is compared with a reference value, and when the temperature signal crosses the reference value, a predetermined fire detection signal a microcomputer that outputs;
a first power supply unit that adjusts a voltage supplied from a main power supply and applies a basic voltage to the microcomputer, thereby enabling the microcomputer to operate;
a heating element disposed in the vicinity of the temperature sensor and generating heat above a temperature corresponding to the reference value when a heating voltage is applied;
a second power supply for applying the heating voltage to the heating element; and
A constant temperature sensor having a check function, comprising a check switch for turning on or off the application of the heating voltage to the heating element. According to claim 1,
The heating voltage is
or a voltage supplied from an auxiliary power source separate from the main power source,
A constant temperature sensor with a check function, characterized in that the voltage supplied from the main power supply. According to claim 1,
The first power supply unit and the second power supply unit, characterized in that the single component, a constant temperature sensor with a check function. According to claim 1,
The heating element is a PTC resettable fuse, characterized in that, a constant temperature sensor with a check function. According to claim 1,
The constant temperature sensor,
All components except for the conductors for connection with the main power and auxiliary power and the conductors for outputting the fire detection signal, or the components with a possibility of fire or explosion, have an explosion-proof structure surrounding an explosion-proof case, characterized in that A constant temperature sensor with a check function. According to claim 1,
The microcomputer further includes an external interrupt terminal,
When a predetermined signal is input to the external interrupt terminal, it characterized in that the output of the fire detection signal, a constant temperature detector with a check function. 7. The method of claim 6,
A constant temperature sensor with a check function, characterized in that it further comprises a manually operable switch to input the external interrupt signal. In a constant temperature sensor having a temperature sensor for detecting the surrounding temperature, and a microcomputer that outputs a fire detection signal when the temperature sensed through the temperature sensor is higher than the reference temperature:
a heating element disposed in the vicinity of the temperature sensor and generating heat above the reference temperature when a heating voltage is applied; and
A constant temperature sensor having a check function, further comprising; a check switch for turning on or off the application of the heating voltage to the heating element. 9. The method of claim 8,
The heating element is a PTC resettable fuse, characterized in that, a constant temperature sensor with a check function. 9. The method of claim 8,
A constant temperature detector with a check function, further comprising a switch configured to input a predetermined signal to an external interrupt terminal for triggering the fire detection signal in the microcomputer.

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