RU2412501C1 - Fuse for fire automation systems - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: fuse for fire automation systems includes housing (1) consisting of dielectric, for example glass bottle (2) and two bottle holders (3) and (4), and the first fuse element (5) destructed when the specified threshold current value through it is exceeded, and placed inside bottle (2) and connected to two holders (3) and (4). Besides, fuse includes the second fuse element (6) which shunts the first fuse element (5) and is made from alloy the fusion point of which is 70 to 150°C.

EFFECT: excluding the possible failure of fire warning system in the situation when there is short circuit of signal line wires due to fire impact on elements of fire warning and evacuation control system.

2 dwg

Description

The invention relates to the field of fuses.

Traditional fuses are usually a glass or porcelain shell, on the bases of which contacts are located, and inside is a thin conductor made of low-melting metal. A certain strength of the tripping current corresponds to a certain cross-section of the conductor and, accordingly, the value of its resistance. If the current strength in the circuit exceeds a predetermined value, the fusible conductor melts, opens the circuit, protecting it from failure.

Known, for example, is a fuse containing a housing, two contacts connected by a conductive element in the form of a fused jumper, which is equipped with an LED indicator in the form of an electrical insulating base with an electronic circuit located on it, having two conductors connected each to its contact [see Patent 2007136512, H01H 85/00].

Closest to the proposed prototype is a fuse, comprising a housing consisting of a glass bulb and two glass bulb holders, which are simultaneously the fuse terminals, and a fuse, with one or more transverse walls with holes inside the glass bulb through which missed the fusible element connected to the holders of the glass flask using connecting conductors [see Patent 2036527, H01H 85/04, H01H 85/048].

The fuses described above can break the circuit if the current exceeds the maximum permissible value. However, such fuses, as a rule, are not used to protect circuits in fire safety systems (including fire warning systems and evacuation control systems) due to the fact that when the current fuse is activated, the warning control device does not receive any information signal , which makes it difficult to identify a device that has failed. To restore its performance is only possible in the process of conducting scheduled maintenance.

For this reason, under the normal functioning of the system, a short circuit occurring in the signal line is displayed by the control device and is quickly eliminated during the repair and restoration work.

All the fuses described above solve one problem - the prevention of emergency conditions that can lead to failure of the protected devices.

However, in a fire, the failure of a people warning system about a fire is caused, first of all, by the failure of signal lines, which include, for example, fire alarms. In this case, a short circuit in the signal line leads to the protection from the side of the warning control device, thus stopping the broadcast of alarm signals by all fire alarms connected to this device, i.e. failure of the warning system elements in the same room where the fire occurs, will lead to the failure of the entire warning system as a whole or a large part thereof, excluding the possibility of informing people in nearby premises about the presence of fire and the need for evacuation tion in a safe area.

This mode of operation is unacceptable, therefore, in a fire, turning off individual sirens when a short circuit occurs in them is completely justified.

An object of the present invention is to eliminate the possibility of a fire warning system in a situation where there is a short circuit in the signal line wires due to fire exposure to elements of a fire warning system and evacuation control.

This problem is solved in that the fuse contains a housing consisting of a dielectric, for example glass, bulb and two holders, and the first fuse element, which breaks when the set threshold value of the current through it is exceeded, placed inside the said bulb and connected to two holders, contains a second fusible element, which shunts the first fusible element and is made of an alloy, the melting temperature of which is from 70 to 150 ° C.

Figure 1 presents the structural diagram of the fuse.

The fuse for fire automatics systems comprises a housing 1, consisting of a dielectric, for example glass, bulb 2 and two bulb holders 3 and 4, and a first fuse 5, which breaks when the set threshold value of the current through it is exceeded, placed inside the bulb 2 and connected to two holders 3 and 4. In addition, the fuse further comprises a second fusible element 6, which shunts the first fusible element 5 and is made of an alloy, the melting temperature of which is from 70 to 150 ° C.

The second fusible element can be placed inside the dielectric bulb, as shown in figure 1, but can be performed outside it (to provide better contact with the environment).

In normal operation, in the absence of fire impact on the signal line, which includes fire alarms, current flows through the second fuse element 6, the resistance of which is less than the resistance of the first fusible element 5. In this case, the signal line short circuit that occurred when some or siren, detected by the notification control device. When the temperature rises to the melting temperature, the second fusible element 6 is destroyed, and the current does not flow through it. In this case, the signal line current begins to pass through the first fuse element 5, which, in the event of a short circuit in the circuit, is destroyed and thus eliminates the possibility of failure of the entire chain of fire-fighting devices included in the signal line. At the same time, these devices continue to fulfill their functions, providing a process for warning people about a fire and their organized evacuation.

Figure 2 presents the structural diagram of a system for warning people about a fire and evacuation control using the inventive fuses for fire automatics systems.

The system includes a warning control device 7, to which a signal line 8 is connected, made by a fire-resistant cable, in which fire alarm devices 9.1-9.3 (sound or light) are placed in parallel, located in the premises of the protected object. In one of the wires of each branch of the two-wire signal line 8, which are connected to each siren 9.1-9.3, the claimed fuses are included for fire automatics systems 10.1-10.3, respectively. These fuses must be located either as close to the sirens as possible, or, if possible, placed inside their enclosures.

If in one of the premises of the object, for example, in room 2, a fire occurs, the temperature in the zone of placement of the fuse 10.2 rises, and when the melting temperature of the second fuse element of the fuse 10.2 is reached, it will be destroyed. In the event that a short circuit occurs in the siren, the first fusible element will also be destroyed. The time interval from the destruction of the second fusible element to the destruction of the first fusible element will be determined by the resistance of the fire alarm to the effects of elevated temperature and / or open flame. When the first fuse element is destroyed, the siren 9.2 is disconnected from the communication line 8, thereby preventing the possibility of a short circuit of the signal line 8. At the same time, the sirens 9.1 and 9.3 continue to work, notifying people 1 and 3 who are present about the need for evacuation.

Thus, if the proposed fuse is used in fire warning systems and evacuation control systems, the possibility of system failure during a short circuit of the signal line wires due to fire exposure to elements of fire warning systems and evacuation control systems is excluded.

Claims (1)

A fuse, comprising a housing consisting of a dielectric, for example glass, bulb and two holders, and a first fuse element that breaks when the set threshold value of the current through it is exceeded, placed inside the bulb and connected to two holders, characterized in that it further comprises a second fusible element, which shunts the first fusible element and is made of an alloy, the melting temperature of which is from 70 to 150 ° C.

Images