RU158594U1 - EMERGENCY LIGHTING INSTALLATION - Google Patents

Abstract

An emergency lighting installation containing a base, an inflatable shell mounted on it, an air blower installed in the base, in communication with a cavity of the shell, to which a lampholder of an electric lamp having an incandescent element is connected, wherein the lamp is located in a protective grill that is located inside the shell and is connected to so that a space is formed between the shell and the grating, as well as a light reflector, characterized in that the light reflector is made in the form of a reflective disk and is fixed inside the grating Between the holder of the electric lamp and the incandescent element, a central hole is made in the reflective disk, in which the electric lamp is located so that between the edge of the central hole of the disk and the lamp a ventilation gap is formed, communicating the cavity of the shell with a cavity that is located above the reflective disk, and in top view the reflective disk has the shape of a polygon, to each side of which an additional light reflector is located pivotally attached to one side, which is overlapped in relation to to adjacent additional reflectors of light, while the opposite side of the additional reflector is connected to the shell.

Description

This technical solution relates to the illumination of de-energized places of accidents and disasters at night. It is intended for use in the construction of emergency lighting installations.

Emergency lighting installations are known, each of which contains a base, an inflatable casing, mounted on it in a vertical position, filled with air, an air blower installed at the base, in communication with the cavity of the casing, to which an electric lamp cartridge with an incandescent element is connected via fastening elements, and the lamp located in the protective grill, which is located inside the shell and connected with it so that between the shell and the grill space is formed (RU 2453763 C2, F21V 15/04 F21L 13/00, 06/26/2012. RU 2315904 C1, F 21S 8/08, 01/27/2008).

A close emergency lighting installation, to the installation presented in this description, is an installation containing a support with an air channel therein for supplying pressurized air to the installation, means for attaching the support to the ground or to a supporting ground structure, an inflatable shell connected to the support with an inlet shell a hole in front of which an air valve is installed, which communicates the cavity of the shell with the air source through the air channel, a light source and a means of protection are fixed in the cavity of the shell, the shell is made with medium by changing its shape and curvature, having upper and lower and two lateral elastic elastic or spring-loaded rods opposite from the protective equipment, connected with the shell and protective equipment, the inner surface of the shell part, located behind the horizontal axis of its symmetry away from the support, is made reflective, the transparency coefficient of this (upper) part is less than the transparency coefficient of the opposite (lower) part of the shell, while the shell is detachably connected to the support, which is made hollow and tubular and in The said air channel is in communication with the cavity of the shell.

The second variant of the lighting installation includes a support with an air channel in it for supplying pressurized air to the installation, means for attaching the support to the ground or to a supporting ground structure, an inflatable casing connected to the support with an inlet opening in front of it, in front of which an air valve is installed, communicating the cavity of the casing with a source of air through the air channel, a light source and a means of protection are fixed in the cavity of the shell, the shell is made with a means of changing its shape and curvature, which are opposite from the means protect the upper and lower and two lateral elastic elastic or spring-loaded rods connected with the shell and the protective equipment, the part of the shell located behind the horizontal axis of its symmetry away from the support is made reflective, the transparency coefficient of this (upper) part is less than the transparency coefficient of the opposite (lower ) part of the shell, while the shell is detachably connected to a support, which is made hollow and tubular and in its cavity there is an air channel in communication with the cavity of the shell, while the support with the air in a channel for supplying air to the shell under pressure is located above the shell, between it and the supporting ground structure (ceiling), which is located above the support.

The third version of the lighting installation includes a support with an air channel in it for supplying pressurized air to the installation, means for attaching the support to the ground or to the supporting ground structure, an inflatable casing connected to the support with an inlet opening in front of it, in front of which an air valve is installed, communicating the cavity of the casing with a source of air through the air channel, a light source and a means of protection are fixed in the cavity of the shell, the shell is made with a means of changing its shape and curvature, which are opposite from the means of shields the upper and lower and two lateral elastic elastic or spring-loaded rods connected with the shell and the means of protection, the part of the shell located behind the horizontal axis of its symmetry away from the support is made reflective, the transparency coefficient of this (upper) part is less than the transparency coefficient of the opposite (lower ) part of the shell, while the shell is detachably connected to a support, which is made hollow and tubular and in its cavity there is an air channel in communication with the cavity of the shell, while the support with the air in s duct for supplying air to a pressurized shell is made of an additional inflatable membrane forming an air channel, filled with pressurized gas.

The fourth version of the lighting installation includes a support with an air channel in it for supplying pressurized air to the installation, means for attaching the support to the ground or to a supporting ground structure, an inflatable casing connected to the support with an inlet opening therein, in front of which there is an air valve communicating with the casing cavity a source of air through the air channel, a light source and a means of protection are fixed in the cavity of the shell, the shell is made with a means of changing its shape and curvature, which are opposite from the means and the protection of the upper and lower and two lateral elastic elastic or spring-loaded rods associated with the shell and the means of protection, the inner surface of the shell part, located behind the horizontal axis of its symmetry away from the support, is made reflective, the transparency coefficient of this (upper) part is less than the transparency coefficient opposite (lower) part of the shell, while the shell is detachably connected to a support, which is made of flexible reinforced hose, in the cavity of which is located the air channel.

The fifth embodiment of the lighting installation includes a support with an air channel in it for supplying pressurized air to the installation, means for attaching the support to the ground or to a supporting ground structure, an inflatable casing connected to the support with an inlet opening in front of which is installed an air valve communicating with the casing cavity a source of air through the air channel, a light source and a means of protection are fixed in the cavity of the shell, the shell is made with a means of changing its shape and curvature, having opposite There are upper and lower and two lateral elastic elastic or spring-loaded rods connected with the shell and protective equipment, the entire part of the shell located behind the horizontal axis of its symmetry away from the support is made reflective, the transparency coefficient of this (upper) part is less than the opposite transparency coefficient ( the lower) part of the shell, while the shell is detachably connected to a support, which is made telescopic from at least two hollow sections - the upper and lower, one of which is rotated it is different in the horizontal plane, while the support sections are hollow and an air channel is located in their cavities, the shell is pivotally connected to the support, and the installation comprises means for rotating the shell in a vertical plane relative to the hinge (RU 2336457 C2, F21S 8/08, 20.10. 2008).

Known, the above options for emergency lighting installations have light reflecting surfaces that reflect light in different directions, which leads to light scattering. It should be noted that the known design of emergency installations have a significant drawback - they provide illumination of the emergency area within the power of an electric lamp, the increase of which is associated with the weighting of the upper part of the installation and the complexity of its design.

In order to increase the illumination, in a lighting installation containing a base, an inflatable casing filled with air, mounted vertically on it, an air blower installed in the base, an electric lamp with an incandescent element, which is located in the protective grill inside the casing and connected with it so that a space is formed between the shell and the grill, and a reflective plate with holes in it for air passage is fixed to the protective grill across it (RU 59774 U1, F21L 14/00, 12/27/2006). This setting is adopted closest to the setting presented in this description. It should be noted that the holes in the reflective plate reduce the lighting efficiency of the illuminated emergency area and increase the energy consumption of the installation.

The technical result of an emergency lighting installation is to reduce its energy intensity and increase the illumination of the illuminated area. Due to increased illumination, energy intensity is reduced.

The technical result is obtained by an emergency lighting installation containing a base, an inflatable casing fixed to it, an air blower installed at the base, in communication with the cavity of the casing, to which the lampholder of an electric lamp having an incandescent element is connected, while the lamp is located in a protective grill, which is located inside the casing and is connected with it so that between the shell and the grating a space is formed, as well as a light reflector, and the light reflector is fixed inside the grating between the cartridge In the light reflector, a central hole is made in the light reflector, in which an electric lamp is located so that between the edge of the central hole of the disk and the lamp a ventilation gap is formed that communicates the shell cavity with a cavity that is located above the reflective disk, and the light reflector is shown in plan view has the shape of a polygon and to each side of it an additional reflector is pivotally attached to one side, which is overlapped with respect to adjacent additional light tracers, while the opposite side of the additional reflector is connected to the shell.

In FIG. 1 shows an emergency lighting system in a basic design;

in FIG. 2 installation with additional light reflectors;

in FIG. 3 is a view A in FIG. 2;

in FIG. 4 is a section BB in FIG. 3.

The emergency lighting installation (Fig. 1) contains a base 1, an inflatable casing 2 fixed on it in a vertical position, filled in the working position with compressed air, an air blower 3 installed in the base 1, in communication with the atmosphere and the cavity 4 of the casing. The cartridge 5 of the electric lamp 6 having an incandescent element 7 is connected to the shell through the fastening elements. The lamp is located in the protective grill 8, which is located inside the shell and connected with it so that between the shell 2 and the grill 8 there is a space 9. Inside the grill 8, a light reflector is installed, which, in particular, is made in the form of a reflective disk 10 (hereinafter, disk 10 ) with a central hole 11. A lower surface 12 of the disk 10 is made reflective. A lamp 6 is located in the hole 11 of the disk 10. A ventilation gap 13 is formed between the edge of the central hole 11 of the disk and the lamp, which communicates the cavity 4 of the shell 2 with the cavity 14, Thoraya disk 10 located above light reflector.

The disk 10 is located between the lampholder 5 and the filament element 7 of the lamp along the height of the lighting system so that the filament element 7 of the lamp is located below the disc 10. The disc is mounted on the grill, and its outer edge is located inside the grill or flush with it. The disk 10 has a flat surface, in another design it has a different shape, while the disk 10 is made of a heat-resistant elastic material, and its reflective surface is made of foil glued from below on the disk, or of reflective material sprayed onto the disk. The outer edge of the disk 10 and the outer edge of the lattice in a plan view have a preferred polygon shape (Fig. 3), in another design they are round in a plan view.

The lighting installation includes additional reflectors pivotally connected to the disk 10 (Fig. 2) located around the disk 10. Each additional light reflector has the shape of a segment 15 extending from the disk 10 towards the casing 2. Reflective segments are located in the space 9 formed around the disk 10 between the grill 8 and the casing. One side of each segment 15 (Fig. 3) is connected by hinges 16 to the reflective disk 10, and the other opposite side of each segment is connected by a hinge 17 to the shell 2. The lower surface of each segment 15 is made of reflective foil or from a reflective material sprayed onto the segment. The disk 10 is connected to the grill 8, mounted on the flange 18. There are various options for connecting the segments 15 to the disk 10, provided that the segments 15 have the ability to rotate relative to the disk 10 in the vertical plane from the action of the shell during inflation.

In the inoperative position of the installation, its shell 2 is in the folded state and in this state the shell wall can occupy any broken shape. Corresponding to these non-working positions of the shell, the segments 15 are in non-working positions, freely turning on hinges 16 and occupying intermediate positions, shown by the dotted line in FIG. 2 when turning into transport position. In order to avoid breakage of the segments when folding the shell, they are preferably made of an elastic, flexible, heat-resistant material. The disk 10 and segments 15 may have various shapes, provided that they have reflective surfaces on the lower sides.

The disk 10 and the segments 15 in the working position are located between the cartridge and the lamp filament element 7 along the installation height so that the filament element 7 is located below the disk 10 and below the segments 15. The disk 10 and the segments are located in the same plane. In another embodiment of the lighting installation, the segments 15 are inclined to the lower side and with respect to the disk 10, each segment can be located at an angle to the disk in the range from 100 to 170 ° (this position is not shown in the drawing). Segments 15 are located along the installation height so (Fig. 4) that each previous segment 15 is overlapped on each subsequent segment 15 (fan-shaped) in a plan view. Surfaces of adjacent segments 15

bringing the lighting installation into position.

In another embodiment of the lighting installation, the segment length is chosen such that the hinge 17 connecting the segment to the casing is located below the horizontal plane in which the disk 10 is located. By the location of the hinge 17 along the height of the lighting installation, select the angle of inclination of the segments 15 to the disk 10 and their length, that allows you to select the focus of the light flow coming from the disk and segments and adjust the spot of light reflected by the disk and segments.

The air blower 3 is made in the form of an impeller, which is mechanically connected to the drive (not shown) of the power unit 19 installed inside the base 1. The cartridge 5 of the electric lamp 6 is mounted on the flange 18, which is located inside the shell and is mounted on it. In the domed part of the shell 2, a ventilation hole 20 may be provided, which may be closed with a plug (not shown) if necessary. By electric wires 21, the power unit 19 is connected to the cartridge 5 of the electric lamp 6. In the central part of the flange 18 there are ventilation holes 22 through which cavities 9 and 14 are connected to the atmosphere through the hole 20.

The installation works as follows. In the transport position, the installation shell is in the folded state and all installation components covered by the cover are laid on the base 1 in the non-working position (not shown). To bring the installation into working position, remove the cover, turn on the engine of the power unit 19 (Fig. 1) and its generator, and supply electric current through the electric wires from the generator of the power unit to the electric drive of the air blower 3. When the supercharger 3 rotates, air from the atmosphere is supplied from below upward under pressure into the cavity 4 of the shell 2, while the shell 2 is inflated with air and occupies the operating position shown in FIG. 1. Next, an electric current is supplied from the generator of the power unit to the electric lamp 6 through the electric wires 21 and the electric lamp 6 is turned on. As a result of the glow of the incandescent element 7 of the electric lamp, it emits light, which in the first embodiment of the installation is reflected by the reflective disk 10 and directed downward, and the other part the light flux is directed away from the longitudinal axis of the shell 2. In this case, the emergency area is illuminated by two light spots - the central light spot from the disk 10, which has high illumination, and peripheral with etovym spot from the element 7, having a lower illuminance. The central light spot is the reflected light rays from the reflective disk 10, the peripheral light spot is formed by scattering light from the element 7.

When the installation is in the process of deploying and pumping air into the shell 2, the wall of the shell is leveled and occupies a working position. As the shell becomes hard, the hinges 17 rise upward and the retro-reflective segments 15 rotate around the hinges 16 to a working horizontal position. From the positions shown by dashed lines, the retro-reflective segments 15 rotate upwardly carried away by hinges 17 in the process of inflation of the shell. With this position of the segments 15, the light from the incandescent element 7 is reflected by the light-reflecting disk 10 and the light-reflecting segments 15. In this case, the light is reflected down by the disk 10, from which a central spot of light is formed in the illuminated area, and from the stream of light reflected by the segments 15 is formed in the area around the central spot outer light ring. A peripheral scattered light spot from element 7 is formed behind the outer light ring. Scattered light passes through the translucent sheath 2 and is scattered by it in the illuminated space. Part of the light in a concentrated state illuminates the area around the installation, and the rest of the light is scattered in the space outside the concentrated spot of illumination formed by the reflective disk and segments. All this significantly increases the concentration of light in the illuminated area in predetermined places and increases its illumination near the installation. Due to the concentration of light and increased illumination, it is possible to reduce the power of the electric lamp, its dimensions, the mass of the grating, the mass of the upper part of the installation and the installation as a whole with a significant reduction in energy consumption. Reducing the energy consumed allows you to reduce the power of the air blower and electric bulbs, which ultimately reduces the energy consumption of the installation as a whole. Moreover, due to the available light scattering outside the concentrated lighting spot of the territory, the illumination of the rest of the territory is kept within the calculated limits outside the concentrated lighting spot.

Located between the edge of the Central hole 11 of the disk 10 and the lamp 6, the ventilation gap 13 (Fig. 1), communicating the cavity 4 of the shell 2 with the cavity 14, ensures the outflow of air from the bottom up in the zone of the lamp and its constant cooling. In this case, the air heated by the lamp passes through the holes 22 in the flange 18 and the heated air is ejected out through the hole 20. A stream of cold air is pumped from the atmosphere into the cavity of the shell by the supercharger 3 constantly during the entire cycle of the lighting installation, which eliminates the lamp overheating and its premature failure.

In the embodiment of the apparatus shown in FIG. 2, the outflow of air occurs in the same manner as described, with the difference that the heated air is essentially in the closed cavity 14 and therefore, for the heated air to escape from this cavity out through the opening 20, it is more significant from the point of view of lamp cooling efficiency.

It is possible to adjust the diameter of the concentrated spot of illumination of the emergency area by changing the angle of inclination of the reflective segments 15 relative to the disk 10. If they are located at an angle of 180 ° to the plane of the reflective disk 10, the diameter of the spot of concentrated lighting will be maximum, and the light concentration will be minimal, and if this is reduced angle - the spot diameter of concentrated lighting decreases, the illumination of this spot of lighting increases, and the energy consumption of the installation decreases.

Thus, a significant increase in illumination made it possible to reduce the energy consumption of the installation.

Claims (1)

An emergency lighting installation containing a base, an inflatable shell mounted on it, an air blower installed in the base, in communication with a cavity of the shell, to which a lampholder of an electric lamp having an incandescent element is connected, wherein the lamp is located in a protective grill that is located inside the shell and is connected to so that a space is formed between the shell and the grating, as well as a light reflector, characterized in that the light reflector is made in the form of a reflective disk and is fixed inside the grating Between the holder of the electric lamp and the incandescent element, a central hole is made in the reflective disk, in which the electric lamp is located so that between the edge of the central hole of the disk and the lamp a ventilation gap is formed, communicating the cavity of the shell with a cavity that is located above the reflective disk, and in top view the reflective disk has the shape of a polygon, to each side of which an additional light reflector is located pivotally attached to one side, which is overlapped in relation to to adjacent additional reflectors of light, while the opposite side of the additional reflector is connected to the shell.

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