RU124045U1 - HEAT LINEAR DETECTOR - Google Patents

Abstract

1. A thermal linear detector comprising at least one control section of a thermal cable connected to an acceptance monitoring device, consisting of two insulated conductors connected to an electrical connector with insulation made of fusible polymer material, with the possibility of shorting the conductors when melting the insulation, and the remote ends of the conductors are closed in the circuit with a terminal resistor mounted on a printed circuit board connected to the conductors by soldering and equipped with an electrically insulating sealed enclosure, filled in nutri sealing mass. 2. The detector according to claim 1, characterized in that it is equipped with an intermediate resistor connected between the acceptance control device and one of the conductors of the thermal cable, mounted on a printed circuit board, connected to the conductors by soldering and provided with an electrically insulating hermetic enclosure filled with a sealing mass inside. The detector according to claim 2, characterized in that the intermediate resistor is made with a resistance of 0.02-0.2 of the resistance of the terminal resistor. The detector according to any one of claims 1 to 3, characterized in that the thermal cable is enclosed in a fire and moisture resistant flexible external protective braid made of material from the group: PVC, nylon, polypropylene. 5. The detector according to claim 1, characterized in that it contains several series-connected control sections of the thermal cable, each of which is made of two insulated conductors connected to the electrical connector, while the insulation of the conductors is made of fusible material, with the possibility of shorting the conductors when melting the insulation.

Description

The utility model relates to electrical engineering and can be used as a signal closing device in a fire alarm system, in fire fighting equipment, mainly in automatic alarm and fire extinguishing devices, and is designed to alert about emergency overheating or fire of equipment in protected compartments of a vehicle (trolley bus, bus, car, on traction rolling stock of railway transport, on suburban electric trains, on rolling stock of the metro on etc.) and launching fire extinguishing means. Actual is the problem of installing a fire alarm in hard-to-reach places, such as cable routes, warehouses, escalators, elevator shafts; at explosive facilities and places with aggressive environments: oil storages, tunnels, elevators, as well as at extended facilities: open parking lots, conveyor belts, conveyors, open storage racks, etc.

A temperature sensor is known, including a housing in which two contacts and a heat-sensitive solder are fixed, its body is made with an internal channel, in the upper part of which a heat-sensitive solder is fixed, which in the molten state closes the contacts fixed in the lower part of the channel, while the internal channel is made of material not wettable by solder (RU No. 2301473).

Known thermal linear fire detector, made in the form of a thermal cable, which is a single continuous sensor, consisting of two or three steel conductors, each of which is covered with a thermoplastic material. The conductors are twisted together to create mechanical stress between them and additionally covered with an external protective sheath. The control current from the interface module is constantly passing through the thermal cable. At the response temperature, the thermoplastic material is pressed through due to the mechanical tension of the conductors and they close (RU 2283674).

Known thermal fire detector containing a thermal cable connected to a terminal resistor and connected to a control panel that measures the electrical resistance and generates a signal "Fire" and "Damage", this thermal cable is divided into controlled zones, at the borders of the controlled zones the signal cable breaks are included resistors, forming with him and the terminal resistor a serial electric circuit (RU 79203, prototype).

The disadvantages of the known detectors are the low probability of trouble-free operation due to the unprotected performance of the connections of resistors and the thermal cable, which leads to low accuracy in determining the ignition site along the length of the thermal cable.

The technical task of the utility model is to create an effective thermal linear detector and expand the arsenal of thermal linear detectors.

The technical result, which provides a solution to the problem, consists in increasing the probability of failure-free operation of the control of fire extinguishing means and, thereby, increasing the accuracy of determining the ignition site along the length of the thermal cable due to measurements at optimal absolute values of resistance - optimal from the point of view of sensitivity for converting the fault currents control device.

The essence of the utility model is that the thermal linear detector contains at least one control section of the thermal cable connected to the control panel, consisting of two insulated conductors connected to the electrical connector with insulation made of fusible polymer material, with the possibility of closing the conductors during melting insulation, and the remote ends of the conductors are closed in a circuit by a terminal resistor mounted on a printed circuit board connected to the conductors by soldering and provided with an electrical insulation sealed enclosure filled inside with a sealing mass.

Preferably, the thermal linear detector is equipped with an intermediate resistor connected between the control panel and one of the conductors of the thermal cable, mounted on a printed circuit board connected to the conductors by soldering and provided with an electrically insulating hermetic casing, which is filled inside with a sealing mass, and the intermediate resistor is made with a resistance of 0, 02-0.2 resistance of the terminal resistor. In this case, the thermal cable is enclosed in a fire and moisture resistant flexible external protective braid made of material from the group: PVC, nylon, polypropylene.

In special cases of the implementation of the thermal linear detector contains several series-connected control sections of the thermal cable, each of which is made of two insulated conductors connected to the electrical connector, while the insulation of the conductors is made of fusible material, with the possibility of shorting the conductors during insulation melting.

The drawing shows a schematic diagram of a thermal linear detector.

The thermal linear detector contains connected, for example, two-wire cable 1 with the control panel 2, at least one control section of the thermal cable, consisting of two or more insulated conductors 4 of the thermal cable connected to the electrical connector 3, made with insulation (not shown ) from a fusible polymer material, with the possibility of shorting the conductors 4 when melting the insulation. The ends of the conductors 4 remote from the device 2 are closed in a circuit by a terminal resistor 5 mounted on a printed circuit board 6 connected to the conductors 4 by soldering and provided with an electrically insulating hermetic casing 7, which is completely filled inside with a sealing mass.

Between the control device 2 and one of the conductors 4 of the thermal cable, an intermediate resistor 8 is included, mounted on an intermediate circuit board 9, connected to the conductors 4 and the wires of the cable 1 by soldering and equipped with an electrically insulating hermetic casing 10 that is completely filled inside with a sealing mass. Through the board 9, both conductors 4 can be connected to the connector 3. The intermediate resistor 8 is connected to the control panel 2 through the connector 3 and one of the conductors of the cable 1.

The intermediate resistor 8 is made with a resistance of 0.02-0.2 resistance of the terminal resistor 5.

The detector may contain several series-connected sections of the connecting cable 1 sections of the thermal cable with conductors 4 (not shown). This allows you to save money and locate sections of the thermal cable in the necessary sections of the route. Each of the control sections of the thermal cable is made of two insulated conductors 4 connected to the electrical connector, the insulation of which is made of fusible material, with the possibility of shorting the conductors 4 when melting the insulation. At the same time, the remote ends of the most remote from the device 2 sections of the conductors 4 of the thermal cable are closed in a circuit by a terminal resistor 5 mounted on a printed circuit board 6, connected to the conductors 4 by soldering and equipped with an electrically insulating hermetic casing 7 completely filled inside with a sealing mass. The presence of several additional sequential intermediate resistors 8 (which may have unequal electrical resistance) in the intermediate control sections of the thermal cable makes it possible to more accurately determine the place of operation. Each intermediate resistor 8 is mounted on an intermediate printed circuit board 9, connected to the conductors 4 by soldering and equipped with an electrically insulating sealed enclosure 10 completely filled inside with a sealing mass.

The sealing materials for filling the housings 7 and 10 must be strong and flexible, have resistance to aggressive environments and temperature extremes, and also have electrical insulation properties, for example, fireproof silicone sealant TU 2257-001-33680530-2001.

The thermal cable is enclosed in a fire and moisture resistant flexible external protective braid (tube, sheath) made of material from the group: PVC, nylon, polypropylene - a coating corresponding to the environment where it will be used.

Thermal line detector is operated as follows.

The control panel 2 monitors the condition of the thermal cable by constantly measuring its electrical resistance. In standby mode, the nominal control current flows through the conductors 4 of the thermal cable, the value of which is determined by the total value of the resistors 5 and 8. An external protective braid made of material from the group: PVC, nylon, polypropylene, eliminates the ingress of moisture, fuel, oils and provides reliable electrical insulation the thermal cable along the entire length from the structures of the structure or vehicle on which it is installed (and prevents the conductors from touching 4 elements of the conductive structures of the installation compartment la), thereby stabilizing the value of the control current.

Printed circuit boards 6, 9 are used to ensure minimum electrical resistance and mechanical strength of the installation of resistors 5, 8, they are varnished. Soldering is preferable for a reliable electrical connection, therefore on the printed circuit board 6 and 9 it is more convenient and reliable to connect the conductors 4 by soldering. Sealed enclosures 7, 10, filled inside with a sealing mass, do not allow moisture, fuel, oils, etc. to get on boards 6, 9 because this could cause corrosion and a change in resistance, which prevents contact of the elements of the conductive structures of the detector installation compartment. The connecting cable 1 is necessary to ensure high-quality connection of the thermal cable with the connecting connector of the device 2, since the thermal cable with the conductors 4 is rigid in itself, during deformations, especially on the vehicle, it can create significant mechanical stress and deform or destroy the connecting connector of the device 2.

If the cable 4 of the thermal cable is broken in any part of it, the control current disappears and device 2 generates a “Damage” signal.

When the critical temperature is reached, the insulation melts and breaks down, i.e. insulating coating of heat-sensitive polymer conductors 4. Under the action of the pressure of the expanding conductors 4, the latter are in contact with each other, which leads to the closure of the conductors 4 to each other. In the event of a fire emergency and a sharp increase in temperature in any controlled zone, the elastic conductors 4 of the thermal cable are closed and shunt the common route of the thermal cable from the controlled zone. The address of this zone is determined by the total value of the electrical resistance of the resistor (s) 8, streamlined by the control current. In this case, the device 2 generates a “Fire” signal, and on the digital indicator of the device 2 the address of the zone in which the fire occurred is displayed.

The installation of resistors 5, 8 on boards 6, 9 in electrically insulating sealed enclosures 10, 7, filled inside with a sealing mass, allows you to configure the sensitivity of device 2 in such a way as to exclude false triggering of device 2 in cases of changes in the control current during non-destructive effects of aggressive environments and climatic , technical (non-emergency) changes in ambient temperature, as well as under the influence of stray currents and other environmental parameters, prevents the occurrence of a short circuit, not associated with accidentally elevated temperatures. Since the intermediate resistor 8 is made with a resistance of 0.02-0.2 (from 2% to 20%) of the resistance of the terminal resistor 5, the operation is excluded with an insignificant or uncertain spread of current values, thereby making it possible to confidently, most likely to distinguish normal and non-emergency current fluctuations from operation in emergency situations “Fire”, “Damage”.

The inventive detector has the following properties.

- The set operating temperature throughout;

- High resistance to humidity, dust, low temperatures and chemicals;

- Indispensable in hazardous areas;

- Easy to install and commission;

- Economical, no operating costs;

- If necessary, the extension is simply added to the system;

- Does not require maintenance;

- Expected service life over 25 years

Thus, an efficient and reliable thermal linear detector was created and the arsenal of automatic fire alarm systems was expanded. At the same time, with the entire set of features of the utility model, an increase in the probability of failure-free operation of the control of fire extinguishing means is achieved with an inextricably linked increase in the accuracy of determining the ignition site along the length of the thermal cable due to measurements at absolute resistance values that are optimal for converting the response currents of the control panel.

Claims (5)

1. A thermal linear detector comprising at least one control section of a thermal cable connected to an acceptance monitoring device, consisting of two insulated conductors connected to an electrical connector with insulation made of fusible polymer material, with the possibility of shorting the conductors when melting the insulation, and the remote ends of the conductors are closed in the circuit with a terminal resistor mounted on a printed circuit board connected to the conductors by soldering and equipped with an electrically insulating sealed enclosure, filled in nutri sealing mass. 2. The detector according to claim 1, characterized in that it is equipped with an intermediate resistor connected between the acceptance control device and one of the conductors of the thermal cable, mounted on a printed circuit board, connected to the conductors by soldering and provided with an electrically insulating hermetic enclosure filled with a sealing mass inside. 3. The detector according to claim 2, characterized in that the intermediate resistor is made with a resistance of 0.02-0.2 of the resistance of the terminal resistor. 4. The detector according to any one of claims 1 to 3, characterized in that the thermal cable is enclosed in a fire and moisture resistant flexible external protective braid made of material from the group: PVC, nylon, polypropylene. 5. The detector according to claim 1, characterized in that it contains several series-connected control sections of the thermal cable, each of which is made of two insulated conductors connected to the electrical connector, while the insulation of the conductors is made of fusible material, with the possibility of shorting the conductors when melting the insulation .

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