KR20060126426A - Temperature detecting device - Google Patents

Abstract

A temperature detecting device having a special structure and suitable for use as a fire sensor. A pair of conductors (1) is connected to a power source device. Further, a shape memory alloy or a shape memory resin body (2) is placed around the pair of the conductors (1). When an ambient temperature of the shape memory alloy or the shape memory resin body (2) is a set temperature, the shape memory alloy or a shape memory resin body (2) restores the shape and the conductors (1) come to be in contact or connected with each other. This causes an electric current to be supplied from the power source device, and an ambient temperature is detected by the current.

Description

TEMPERATURE DETECTOR {TEMPERATURE DETECTING DEVICE}

The present invention relates to a temperature detection device.

There are various configurations of the temperature detection device. The purpose is also various. For example, many types of fire detectors also detect temperature. In the fire detector of the type that detects the temperature, when the ambient temperature of the detector rises due to the heat of the fire and the temperature reaches the set temperature, the fire detector detects the fire. Therefore, the detector can also be said to be an example of a temperature detection device.

By the way, as described in Japanese Patent Laid-Open No. 2003-36488, a fire detector is usually attached to the ceiling surface, but the installation work is not easy. Process water is required and the cost is expensive.

In addition, fire detectors are usually installed in buildings after construction. However, due to cost, fire detectors are not installed in buildings or workplaces under construction. Therefore, when a fire breaks out in a building or workplace during construction, it is not possible to cope with it accurately, and the countermeasure is strongly demanded.

For the same reason, fire detectors are never installed in exhibition halls, event venues, showrooms, temporary houses, temporary dormitories, temporary factories and temporary offices. Therefore, when a fire breaks out, it cannot cope with it correctly.

In addition, fires may occur on ships, aircraft, vehicles and workshops that are under construction.

It is therefore an object of the present invention to provide a temperature detection device suitable for use as a fire detector with a special configuration.

Another object is to provide a temperature detection device which can be easily installed when used as a fire detector, requires no process water, and is inexpensive.

Another object is to provide a fire detector suitable for use as a fire detector and for installation in a building or workplace under construction.

Another object is to provide a temperature detection device suitable for use in a temporary building such as an exhibition hall for use as a fire detector.

Another object is to provide a temperature detection device suitable for use in fire vessels, aircraft, vehicles, and workplaces that are used as fire detectors.

[Patent Document 1]

Japanese Patent Application Laid-Open No. 2003-36488

According to the present invention, a pair of conductors is connected to the power supply device. In addition, when the shape memory alloy or the shape memory resin is installed around a pair of conductors and the ambient temperature of the shape memory alloy or the shape memory resin is a set temperature, the shape memory alloy or the shape memory resin is formed by the heat. Restored, each conductor is contacted or connected. Thus, a current is supplied from the power supply, and the ambient temperature is detected by the current.

In a preferred embodiment, the conductor consists of a conductor of a pair of wires. When the shape memory alloy or the shape memory resin is installed around a pair of wires and the shape memory alloy or the shape memory resin is reconstructed, each wire is tightened by the shape memory alloy or the shape memory resin, and the conductor Contact.

The shape memory alloy or shape memory resin is coiled and wound around a pair of wires.

In addition, a plurality of shape memory alloys or shape memory resin members are arranged at intervals along the wires, and are installed around the pair of wires.

In addition, the electric wire consists of a soluble insulated wire which has a soluble insulator, and a conductor is accommodated in a soluble insulator. When the ambient temperature of the wire is a predetermined temperature, the soluble insulator is melted by the heat.

In a preferred embodiment this device is also used as a fire detector. When the ambient temperature rises due to the heat of the fire and the temperature reaches the set temperature, the shape memory alloy or the shape memory resin is restored by the heat of the fire, and the fire is detected by the current.

The conductor is made of copper or aluminum, and the electric wire is flexible and can be arbitrarily laid.

Moreover, when each conductor is connected to an alarm device, when a conductor contacts or is connected, an electric current flows into an alarm device, and an alarm is issued by an alarm device.

When a soluble insulated wire is used for the electric wire, a highly elastic metal body may be provided around the pair of electric wires. When each wire is sandwiched by a metal body, when the ambient temperature of the wire is a predetermined temperature, the soluble insulator melts by the heat, and the conductors are connected or connected by the metal body. Thus, a current is supplied from the power supply, and the ambient temperature is detected by the current.

In this case, the metal body is made of steel or stainless steel, and preferably has a coil or clip shape.

1 is a side view showing an embodiment of the present invention,

2 is an electrical circuit diagram of the fire detector of FIG.

3 is a side view showing another embodiment;

4 is a side view showing another embodiment;

5 is a side view illustrating a state in which the conductor of FIG. 4 is connected;

6 is a side view showing another embodiment.

※ Explanation of code for main part of drawing

1: conductor 2: shape memory alloy body

3: wire 4: AC adapter

7: fire lamp 8: bell or buzzer

12: metal body

Hereinafter, embodiments of the present invention will be described.

1 shows a temperature detection device according to the present invention. In this apparatus, a pair of conductors 1 are connected to a power supply. Further, when the shape memory alloy 2 is provided around the pair of conductors 1, and the ambient temperature of the shape memory alloy 2 is a set temperature, the shape memory alloy 2 is formed by the heat. The shape is restored and each conductor 1 is contacted or connected. Thus, a current is supplied from the power supply, and the ambient temperature is detected by the current.

In this embodiment, the conductor 1 consists of a conductor of a pair of wires 3. The shape memory alloy 2 is provided around the pair of wires 3. The shape memory alloy 2 is coiled and wound around a pair of electric wires 3. In this embodiment, a plurality of shape memory alloy bodies 2 are provided at intervals along the wires 3, and are wound around the pair of wires 3 and wound. In addition, the electric wire 3 consists of a soluble insulated wire which has a soluble insulator, and the conductor 1 is accommodated in the soluble insulator.

Also in this embodiment, this apparatus is used as a fire detector. The conductor 1 is made of copper or aluminum, and the electric wire 3 is flexible and can be arbitrarily laid.

In addition, each conductor 1 is connected to a power supply device and an alarm device. For example, as shown in FIG. 2, the AC adapter 4 is used for the power supply device, and each conductor 1 is connected to the relay 5, the switch 6, and the AC adapter 4. As shown in FIG. In addition, a fire lamp 7 and a bell or buzzer 8 are used for the alarm device, and each conductor 1 is connected to the relay contact 9, the fire lamp 7 and the bell or buzzer 8. In addition, a power lamp 10 is connected to the switch 6 and the AC adapter 4.

For example, in a building or work site under construction, the AC adapter 4 is plugged into an outlet, and the switch 6 is switched on. Therefore, a current is supplied from the AC adapter 4, flows to the power lamp 10 via the switch 6, and the power lamp 10 lights up by the current. The wire 3 is then laid on the floor, ceiling or wall. The electric wire 3 may be wired and laid in the air.

Therefore, when a fire occurs after that, the ambient temperature rises by the heat of the fire, and when the temperature reaches the set temperature, the shape memory alloy body 2 recovers the shape by the heat of the fire and the radius thereof decreases. Therefore, each electric wire 3 is tightened by the shape memory alloy 2, and the conductor 1 contacts. Thus, a current is supplied from the AC adapter 4 and a fire is detected by the current.

In addition, a current flows to the relay 5 through the conductor 1, the relay 5 is excited by the current, and the relay 1 contact 9 is turned on. Thus, current flows through the relay contact 9 to the fire lamp 7 and the bell or buzzer 8, and the fire lamp 7 lights up by the current, and the bell or buzzer 8 sounds. Therefore, an alarm is generated by the fire lamp 7 and the bell or buzzer 8, so that the fire can be coped with accurately.

In this embodiment, the wire 3 is a soluble insulated wire, and the conductor 1 is housed in the soluble insulator as described above. Therefore, when a fire occurs, the ambient temperature rises due to the heat of the fire, and when the temperature reaches a predetermined temperature, the soluble insulator melts due to the heat of the fire. At the same time, the shape memory alloy body 2 is reconstructed by the heat of fire, and the respective wires 3 are tightened. Therefore, each conductor 1 can be reliably contacted.

The plurality of shape memory alloys 2 are arranged at intervals along the wires 3, and are provided and wound around the pair of wires 3 as described above. Therefore, if a fire occurs in any part of the entire length of the electric wire 3, there is no problem. In that part, the shape memory alloy body 2 is reconstructed by the heat of a fire, and each electric wire 3 is tightened, and the said conductor 1 contacts. This makes it possible to reliably detect a fire.

The conductor 1 is made of copper or aluminum, and the electric wire 3 is flexible and can be arbitrarily laid as described above. Therefore, the electric wire 3 can be easily laid in a floor surface, a ceiling surface, a wall surface, or the air.

Therefore, in the case of this fire detector, it is sufficient to just lay the electric wire 3, and it can be installed easily, and the process water is not required and cost is low. As a result, this fire detector can be installed in a building or a workshop under construction. Therefore, when a fire occurs in the building under construction or its workshop, it can cope with it accurately.

This fire detector can be installed in temporary buildings such as exhibition halls, as well as in buildings under construction. Therefore, when a fire occurs in the temporary construction, it can cope with it accurately.

The fire detector can also be installed in ships, aircraft, vehicles and workshops under construction. Therefore, when a fire occurs, it can cope with it accurately.

In a building after construction, when an ordinary fire detector is provided on the ceiling surface, the fire detector may be used for the building, and the electric wire 3 may be laid on the floor or wall surface. The electric wire 3 may be wired and laid in the air. In this case, in addition to the fire detectors on the ceiling surface, it is preferable to be able to additionally detect fires in the fire detectors on the floor, wall or air.

In this embodiment, the AC adapter 4 is used as the power supply device. However, a battery such as a battery or a storage battery may be used as the power supply device, and each conductor 1 may be connected thereto.

When a fire occurs by using a radio signal transmitter and a receiver in the alarm device and the conductor 1 contacts, the radio signal may be transmitted from the transmitter and received by the receiver. The alarm may be triggered by a fire lamp, bell or buzzer based on the signal.

As shown in FIG. 3, the shape memory alloy body 2 consists of a double coil of the reverse direction, and may be a sleeve net shape. In this case, when the electric wire 3 is inserted into the shape memory alloy body 2 of a sleeve net shape, the shape memory alloy body 2 is installed and supported around the pair of electric wires 3. When the fire occurs, the shape memory alloy body 2 is restored by the heat of the fire, and the radius thereof is reduced. Accordingly, each wire 3 is tightened by the shape memory alloy 2, and the conductor 1 is contacted to detect a fire.

The shape memory alloy may be clipped. Even in the shape of a clip, it can be supported around a pair of wires. When the fire occurs, the shape memory alloy body is restored by the heat of the fire, and the radius thereof is reduced. Therefore, each wire is tightened by the shape memory alloy, and the conductor is contacted to detect a fire.

It is also conceivable to use a shape memory resin instead of a shape memory alloy.

It is conceivable not only to the fire detector but also to use this temperature detection device for other purposes.

4 shows another embodiment. Also in this embodiment, the pair of conductors 1 are connected to the power supply device, and the shape memory alloy body 2 is provided around the pair of conductors 1. The shape memory alloy body 2 is coiled. In addition, each conductor 1 penetrates the cover case 11 so that the cover case 11 is supported by the conductor 1, and the shape memory alloy 2 is accommodated in the cover case 11, It is kept in alignment.

Therefore, when the ambient temperature of the shape memory alloy body 2 is a set temperature, as shown in FIG. 5, the shape memory alloy body 2 is shape-restored by the heat | fever, and the radius decreases. Therefore, each conductor 1 is connected by the shape memory alloy 2, a current is supplied from the power supply device, and the ambient temperature is detected by the current.

In the apparatus of FIG. 4, the shape memory alloy body 2 may be in the shape of a sleeve net or may be in the form of a clip.

In the embodiment of FIG. 6, similar to the embodiment of FIG. 1, the conductor 1 is connected to the power supply device in the pair of wires 3. The electric wire 3 is the same as the electric wire of FIG. 1, and consists of a soluble insulated wire which has a soluble insulator, and the conductor 1 is accommodated in the soluble insulator. In addition, a large elastic metal body 12 is provided around the pair of electric wires 3. The metal body 12 is made of steel or stainless steel. When the electric wires 3 are sandwiched by the metal body 12 and the ambient temperature of the electric wires 3 is a predetermined temperature, the fusible insulator is melted by the heat, and at the same time, the metal body 12 is elastically elastic. ) Is reconstructed and each conductor 1 is contacted or connected by the metal body 12. Thus, a current is supplied from the power supply, and the ambient temperature is detected by the current.

In this embodiment, the metal body 12 is coiled and wound around the pair of electric wires 3. Therefore, when the soluble insulator is melted, the metal body 12 is reconstructed by elasticity and the radius thereof is reduced. Therefore, each conductor 1 is contacted or connected by the metal body 12. The metal body 12 may have a clip shape.

In this embodiment, similarly to the shape memory alloy 2 of FIG. 1, a plurality of metal bodies 12 are arranged at intervals along the wires 3 and are provided around the pair of wires 3. The conductors 1 are also connected to the power supply device and the alarm device in the same manner as in the embodiment of FIG. When it is used as a fire detector and a fire occurs, the soluble insulator is melted by the heat, and the conductors 1 are contacted or connected by the metal body 12, and a current is supplied from the power supply device by the current. A fire is detected. In addition, an electric current flows through the alarm device, and the alarm device generates an alarm.

Claims (10)

A pair of conductors connected to the power supply, It is made of a shape memory alloy or a shape memory resin member installed around the pair of conductors, When the ambient temperature of the shape memory alloy or shape memory resin is a set temperature, the shape memory alloy or shape memory resin is reconstructed by the heat to contact or connect the respective conductors, and a current is supplied from the power supply device. And the ambient temperature is detected by the current. The method of claim 1, The conductor consists of a conductor of a pair of wires, and when the shape memory alloy or shape memory resin is installed around the pair of wires, the shape memory alloy or shape memory resin is restored. And each conductor is tightened by a shape memory alloy or a shape memory resin so that the conductors come into contact with each other. The method of claim 2, And the shape memory alloy or shape memory resin is coiled and wound around the pair of wires. The method of claim 2, And a plurality of the shape memory alloys or the shape memory resins are arranged at intervals along the wires and are provided around the pair of wires. The method of claim 2, The wire is made of a soluble insulated wire having a soluble insulator, the conductor is accommodated in the soluble insulator, when the ambient temperature of the wire is a predetermined temperature, the soluble insulator is melted by the heat. Temperature detection device. The method according to any one of claims 1 to 5, When used as a fire detector, when the ambient temperature rises due to the heat of the fire and the temperature reaches the set temperature, the shape memory alloy or the shape memory resin is restored by the heat of the fire, and the current Temperature detection device characterized in that the fire is detected. The method of claim 6, The conductor is made of copper or aluminum, and the wire is flexible and can be arbitrarily laid. The method of claim 6, And each of the conductors is connected to an alarm device, and when the conductor is in contact or connected, the current flows through the alarm device so that the alarm is triggered by the alarm device. A pair of electric wires comprising an soluble insulated wire having a soluble insulator, A pair of conductors housed in the available insulator and connected to the power supply; It is installed around the pair of wires, and made of a large elastic metal body to sandwich the wires, When the ambient temperature of the wire is a predetermined temperature, the soluble insulator is melted by the heat, and each conductor is contacted or connected by the metal body, a current is supplied from the power supply, and the ambient temperature is detected by the current. A temperature detection device, characterized in that. The method of claim 9, The metal body is made of steel or stainless steel, and has a coil or clip shape.

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