RU115672U1 - AUTOMATIC STATIONARY FIRE FIGHTING SYSTEM AND / OR PROTECTION AGAINST FIRE HAZARD OF SUCH OBJECTS AS PREMISES IN BUILDINGS AND CONSTRUCTIONS OF VARIOUS PURPOSE - Google Patents

Abstract

1. Automatic stationary fire extinguishing system and / or protection against fire hazard of such objects as premises in buildings, structures for various purposes, having a control unit and an associated fire hazard monitoring device in the form of a set of fire detection means, for example, functional fire alarm sensors, and also, at least one unit for generating a working electric field, containing a high-voltage voltage converter obtained from the used power source, and two opposite high-voltage electrodes connected to it, installed at a distance relative to each other, and the negatively charged electrode is located in the zone of the lower horizontal plane object, characterized in that in it the positively charged electrode of the unit for generating the working electric field is installed above the negatively charged electrode and placed in the upper horizontal plane of the object or installed on the side of it and the size is located in the lateral vertical plane of the object, while both electrodes are installed relative to each other at such a distance h that provides a working electric field with the ability to affect the entire volume of the flame simultaneously. ! 2. The system according to claim 1, characterized in that the voltage converter of the unit for generating the working electric field is adjustable. ! 3. The system according to claim 1, characterized in that the opposite electrodes of the unit for generating the working electric field are installed relative to each other at a distance h equal to the parameter of the object corresponding to a specific size scheme

Description

The utility model relates to the field of fire extinguishing, more specifically to the technical means of automatic fire extinguishing; it is intended primarily to extinguish fires and / or to prevent the spread of the source of fire inside or outside objects such as rooms in buildings and structures for various purposes.

Automatic fire extinguishing systems are known: single-threshold (RU 2314847 C1, 2008), two-threshold (RU 2283149 C1, 2006) or with a series of redundant fire extinguishing stages (RU 2368409 C1, 2009), which provide for the operation of tracking flame or thermal sensors threshold spraying of powdered or aerosol fire extinguishing agents inside the premises, the use of which worsens the working conditions of firefighting personnel, and the contact of these funds with the property located in the room as a result of such fire extinguishing often causes him significant he said. In addition, with a single-threshold fire extinguishing mode, its effectiveness decreases, and with two- and multi-threshold fire extinguishing times, the fire-fighting time is increased and the process control algorithm is complicated.

Fire-extinguishing devices that implement a non-contact method of extinguishing a fire by exposing a flame to generated high-voltage electric discharges supplied to the zone of the fire source manually or using installations are more effective in response time and ensuring the preservation of property.

The mobile fire installation (RU 69754 U1, 2006) is known, which contains a vehicle with an elastic conductor located on it and interconnected and adjustable in length: an electric power source, a DC-voltage converter, and a device for generating electrical discharges in the form of a positive connected to a high-voltage capacitor an electrode in the form of a "rake" with needles; as well as a retractable device that delivers this electrode to the zone of the electron cloud (plasma) of the flame with negatively charged electrons.

The main disadvantage of such an installation is that when extinguishing a fire, the operator is forced to be in the zone of extreme proximity to the fire, and the principle of using a plasma instead of a negative high-voltage electrode in this analogue not only affects the efficiency of generating the required electric field strength necessary to suppress the combustion reaction, reducing the effectiveness of fire extinguishing in general, but also does not allow the use of such a plant for preventive protection of premises, etc. objects from fire hazard. In addition, in real fire extinguishing conditions, due to the high temperature of the flame, it is technically difficult to realize the introduction of the electrode deep into the flame.

The closest analogue (prototype) of the proposed utility model is an automatic stationary system that provides, in addition to extinguishing the fire, the possibility of protection against fire hazards of such objects as rooms in buildings and structures for various purposes (EP 0436487 A1, 1991, Fig. 7), which contains a control unit and a fire hazard tracking device associated with it in the form of a set of fire detection means, for example, functional fire alarm sensors and at least one generating unit and operating the electric field, consisting of a high-voltage converter, resulting from the used source of power, and connected to it two high voltage of opposite electrodes arranged with an air gap relative to each other, wherein as the negative electrode therein is grounded plate floor space. A positively charged electrode is organized by a series of ring modules laid with a gap on this plate. The work of the prototype system is based on the creation of an intense working electric field in the zone of the base of the flame, acting on it until it disappears.

The disadvantages of the prototype include the reduced efficiency of the device, due to the unilateral in relation to the flame torch, the placement of unlike electrodes with which to generate a working electric field, because as a result of this placement, the effect of the electric field on the flame is limited only by the zone of its base. In addition, the prototype does not realize the possibility of expanding the functional range of the device, since the placement of opposite electrodes on top of each other with a small (air) gap between them — practically in the same plane of the object (in the floor) —and the use of an earthed floor of the room as one of the electrodes limits variability and effectiveness of object protection, including in the presence of complicated structural parameters and room geometry, when the arrangement of electrodes provided in the prototype is not technically feasible.

The problem solved by the utility model is aimed at expanding the arsenal of technical means - automatic stationary systems that implement the method of non-contact fire extinguishing / fire protection by exposing the ignition flame to a high-voltage electric field.

The technical result obtained from the implementation of the proposed technical solution is to increase the efficiency of the system and expand its functional range.

The claimed technical result is achieved by the fact that in an automatic stationary fire extinguishing system and / or protection against fire hazard such objects as premises in buildings, structures for various purposes, having a control unit and associated fire hazard tracking device in the form of a set of fire detection tools, for example functional fire alarm sensors, as well as at least one site for generating a working electric field containing a high voltage voltage converter received from the used power source, and two opposite high voltage electrodes connected to it, installed at a distance relative to each other, and the negatively charged electrode is placed in the zone of the lower horizontal plane of the protected object, in contrast to the known analogues, the positively charged electrode of the working electric field generation unit placed above the negatively charged electrode in the upper horizontal plane of the object or installed on the side of it and placed on the side the vertical plane of the object, while both electrodes are mounted relative to each other at a distance h that provides a working electric field with the possibility of affecting the entire volume of the flame at the same time.

Additional differences of the system are that in it:

- the voltage Converter node generating a working electric field is made adjustable;

- the opposite electrodes of the working electric field generation unit are installed relative to each other at a distance h equal to the object parameter corresponding to a specific arrangement of electrodes in two opposite horizontal planes or in two adjacent planes: vertical and horizontal;

- each of the electrodes is made in the form of a grid with a perimeter corresponding to the perimeter of the plane of the object in which it is placed;

- the electrodes are made in the form of rods or in the form of solid or mesh plates;

- there is an autonomous power supply.

The proposed placement of the electrodes of the node / nodes generating an electric field so that one of them is under the zone or in the zone of the base of the flame, and the opposite one above the top of this flame, provides the formation of a working electric field (or a complex of electric fields, if the system contains a group of these nodes), which has a simultaneous effect on the entire flame volume, which increases the system speed and the level of flame suppression reliability, while both electrodes are located in the prototype One way flame generated by them and the working electric field acts on the torch only in its base area.

A variety of electrode shapes and the possibility of the variation of the placement of the positive electrode relative to the negative allows you to expand the functional range of the proposed system due to the possibility of protecting the premises of buildings, structures from the flame of an external fire, including and by additionally placing nodes for generating working electric fields in window, door, etc. openings.

The invention is illustrated by drawings, where in Fig.1 shows a block diagram of a system (example); figure 2 is an embodiment of a node generating an electric field (circuit diagram); figure 3 is an example of the placement of opposite electrodes in two opposite planes; figure 4 is the same in two adjacent planes; figure 5 - examples of the system for a room in a residential or office space; figure 6 is an example of the placement of the electrodes in the doorway of a residential or office space.

The proposed automatic stationary system is designed to prevent fire and extinguish a fire inside objects such as rooms in buildings, structures for various purposes or outside them. The object served by the proposed system can be a separate room inside a building, structure or a complex of such premises, as well as door, window and other openings, which allows you to cut off the source of fire that arose in one of the rooms, preventing its spread to other neighboring rooms.

The system comprises a control unit 1 (control signal generation unit) and a fire hazard tracking device 2 in the form of a set of fire detection means, for example, functional sensors 3 for fire alarms or visualization tools, and a unit 4 for generating a working electric field. Depending on the volume of the protected object 5 or the complex of objects, the system contains at least one node 4 per protected object 5, or a group of such nodes located around the perimeter of the protected object 5 in the order required for reliability of protection / fire fighting. The node 4 contains a high-voltage adjustable converter 6 of the voltage received by it from the used power source 7, and two unlike high-voltage electrodes connected to the converter 6: negatively charged 8 and positively charged 9.

The negatively charged electrode 8 is placed in the lower horizontal plane of the object 5, for example, in the floor of the room, the lower part of the opening, window, wall, etc., and the placement of the electrode 9 is possible depending on the specific type and purpose of the object 5: it is either opposite to the electrode 8 in the upper horizontal plane of the object, for example in the ceiling of the room, the upper part of the wall, opening, etc., or on the side of the electrode 8 and installed in one of the sides of the room. The electrodes 8 and 9 are installed relative to each other at such a distance h, which provides a working electric field with the possibility of influencing the entire volume of the flame at the same time (Figs. 3 and 4). In special cases of the system execution, the distance h is chosen equal to the object parameter corresponding to a specific arrangement of electrodes in two opposite horizontal planes or in two mutually intersecting planes, or less than it.

As the source 7 of the initial electrical voltage can be used industrial power grid of the object, or the system is equipped with an autonomous power source. Means of recording open flame / smoke or other signs of fire hazard - fire alarm sensors 3, such as smoke, heat, flame sensors, etc., or visualization tools (not shown) are connected to the control unit 1, which receives information on fire / smoke in the protected area of the facility and generating control signals for the executive nodes 4. The layout of the nodes 4 in the fire-protected object 5 is set so as to create an impenetrable high-voltage electromagnet for ignition / fire flame suppression agnitic screen.

Structurally, high-voltage electrodes 8 and 9, depending on the type of a specific object and the specific arrangement of their location, the number and placement of nodes 4 in the object in shape, can be made in the form of: a metal grid (electric current conductor) mounted in / on the floor and ceiling, for example as shown in FIG. 5; metal rods or plates (solid or mesh) installed with step-by-step placement in one or another plane of an object (objects).

The principle of operation of the system is illustrated in the following specific example of its execution in accordance with figure 1.

In the initial state, the device 2 of the system is in a state of fire hazard detection, determined using fire alarm sensors 3, for example, smoke, heat, open flame sensors, installed along the volume and / or perimeter of the protected object / room. Upon receipt of the signal from the sensors 3 to block 1, the latter generates control signals supplied to the corresponding actuating nodes 4 by a predetermined algorithm, which generate a working electric field forming the electromagnetic three-dimensional screen using the high-voltage voltage converter 6 and electrodes 8 and 9, covering the torch of flame throughout its volume (figure 3 and 4). Thus obtained electromagnetic screen not only suppresses fire and extinguishes a fire, but also is an obstacle to the spread of flame.

This system of electrical flame prevention and extinguishing has successfully passed pilot prototype laboratory tests, which confirmed its operability.

The proposed system due to its effectiveness, as it automatically registers the place and volume of ignition at the initial stage of its occurrence, and generates a working electric field for the entire volume of the flame / fire torch as a whole, can be used to prevent fires and non-contact fire extinguishing at important and especially important objects, since it allows faster than known analogues, stop the fire and reduce or completely prevent material damage to the property of these objects.

The manufacture of the system does not require any special materials, technologies, equipment and can be manufactured using well-known and widely used tools and technologies.

Claims (7)

1. An automatic stationary fire extinguishing and / or fire protection system for objects such as rooms in buildings, structures for various purposes, having a control unit and an associated fire hazard tracking device in the form of a set of fire detection tools, for example, functional fire alarm sensors, and also at least one node generating a working electric field containing a high voltage voltage converter, obtained from the used power source ia, and two opposite high voltage electrodes connected to it, installed at a distance relative to each other, and the negatively charged electrode is placed in the zone of the lower horizontal plane of the object, characterized in that it has a positively charged electrode of the working electric field generation unit mounted above the negatively charged electrode and placed in the upper horizontal plane of the object or installed on the side of it and placed in the lateral vertical plane of the object, both electrodes Credited relative to each other at such a distance h, which provides a working electric field to act on the entire volume of the flame simultaneously. 2. The system according to claim 1, characterized in that the voltage Converter node generating a working electric field is made adjustable. 3. The system according to claim 1, characterized in that the opposite electrodes of the working electric field generation unit are installed relative to each other at a distance h equal to the object parameter corresponding to a specific arrangement of electrodes in two opposite horizontal planes or in two adjacent planes: vertical and horizontal. 4. The system according to claim 1, characterized in that each of the electrodes is made in the form of a grid with a perimeter corresponding to the perimeter of the plane of the object in which it is placed. 5. The system according to claim 1, characterized in that the electrodes are made in the form of rods. 6. The system according to claim 1, characterized in that the electrodes are made in the form of mesh or solid plates. 7. The system according to claim 1, characterized in that it is equipped with an autonomous power source.