EA028004B1 - Lighting installation - Google Patents

Abstract

The invention relates to outdoor illumination devices, used primarily in emergency situations. It is designed to be used in cases of power supply interruption during accidents and catastrophes, and in cases of conducting construction or repair or rescue operations in the night time. The technical result is higher reliability and better service qualities of the lighting installation. The lighting installation comprises a base, an inflatable shell fastened to the base, an air blower in communication with the shell cavity, and at least one light source accommodated in the shell. The lighting installation is equipped with a hollow module secured inside the shell and carrying the light source, the module cavity being in communication with the light source cooling system. The light source is of LED type, and the cooling system uses liquid as the cooling medium and includes a pump connected to the module cavity by means of flexible pipes.

Description

This technical solution relates to lighting facilities mainly in emergency conditions. It is intended for use in cases of power outages in accidents and disasters, as well as in cases of construction or repair or search and rescue work at night.

Inflatable lighting installations are known from patent publications (I8 6322230B1, publ. 11/27/2001; KI 2192581C1, publ. 02.26.2001; KI 2286510 C9, publ. 10.04.2006; “About 02/063207 A1, publ. 08/15/2002), each of which has an inflatable flexible casing, which is a support for a light source fixed inside the casing, in its upper part, the support having a base through which it is connected to the ground or to any known structural component (floor, building, frame) )

A disadvantage of the known lighting systems is that their design does not imply the possibility of using LED light sources for lighting, providing illumination comparable to gas-discharge lamps, in particular sodium lamps, traditionally used in such installations.

A well-known emergency lighting installation, including a base, a support connected to it, made of a flexible airtight and transparent shell forming a closed internal cavity of the support, with a detachable lightning and an insert that controls its height, means for connecting the support shell with the base and the upper end part of the support, according to at least one lantern in the casing with the base of its fastening to the upper end part of the support, stretch marks associated with the upper part of the support and the ground. The emergency lighting installation contains at least one LED flash overhead strobe lamp mounted with screws on top of the end part of the emergency lighting installation above the base of the lamp housing, the extensions are made entirely of retroreflective material or with elements of retroreflective material. The LED lamp is mounted on top of the base, and such lamps can be installed on the side surface of the shell (outside) in the required quantity and at the required height using polycarbonate spacers placed on the shell under the bases of the LED lamps. Equipping the installation with an LED lamp increases the efficiency of the signaling functions of the installation and expands its operational capabilities (KI 139894 I1, publ. 04/27/2014).

This installation also does not solve the problem of lighting the territory with LED light sources due to the fact that in emergency installations of this type there are no devices for reliable cooling of powerful LED light sources. The LED strobe lamp performs only a signaling function and cannot be used for lighting.

Meanwhile, LED light sources have a number of significant advantages over other well-known light sources, namely, they exceed their service life, have lower power consumption, instantly ignite when a voltage is applied, and show stable performance in a wide temperature range, provide high contrast, which provides better contrast clarity of illuminated objects.

However, to ensure sufficient reliability of the LEDs, a heat sink must be present. It is known, in particular, a lighting device containing a housing, a removable cover with a diffuser, LEDs on the board, a power device, characterized in that it is additionally equipped with a radiator, rigidly fixed to the housing of the lighting device, while on the base surface of the radiator is installed and rigidly fixed board with LEDs connected to the power supply. The known device is intended for lighting industrial, warehouse and other premises for various purposes, as well as in transport for auxiliary rooms and vestibules of railway cars, where a high degree of illumination is not required (KI 77024 I1, publ. 10.10.2008).

The use of such devices as part of inflatable lighting installations will not meet the necessary lighting requirements, since such installations are usually used to illuminate large areas during various types of work associated with increased danger (liquidation of accidents, consequences of disasters, etc.) which require a much higher level of illumination.

An increase in the quantity and power of LED light sources will inevitably lead to the need to increase the heat sink surface of the radiator and, as a result, to increase its size and mass. A high-power LED floodlight is known, characterized in that it is open-frame and contains a rectangular, round or ellipsoidal frame, in the opening of which a light-emitting matrix with a cooling radiator is installed, and the light-emitting matrix contains white-emitting light elements covered with aspherical lenses. The results of electrical tests of a prototype of this searchlight showed that its luminous flux is 15,000 lm, and the weight of the searchlight is 17 kg, even though it is made unpacked (KI 144224 I1, publ. 08/10/2014).

The use of a volumetric and massive radiator as a part of inflatable lighting installations will negatively affect their operational characteristics, since the rise of the light source

- 1 028004 together with such a radiator by means of a stream of air pumped into an inflatable shell, it can be difficult, and in some cases impossible, due to the high mass of the radiator and the need to maintain a higher air pressure inside the shell. In addition, when the shell is deflated, a sharp drop in the radiator combined with the light source is possible, which can lead to personal injury and damage to the installation.

The problem to which the claimed invention is directed is to create a design of an inflatable lighting installation equipped with an LED light source that provides a high level of illumination and does not lead to a significant increase in the mass of the upper part of the installation in its working position.

The technical result of the lighting installation presented in this description is to increase its reliability and operational characteristics.

The technical result is achieved by a lighting installation containing a base, an inflatable shell fixed thereon, an air blower communicated with the shell cavity and at least one electric light source located in the shell, characterized in that it is equipped with a hollow module mounted inside the shell on which it is mounted the light source, the cavity of the module is in communication with the cooling system of the light source, while the light source is LED, and the cooling system is liquid and includes pump connected to the module cavity with flexible tubes.

In some versions of the lighting installation, its cooling system can be equipped with a radiator and an expansion tank; the tubes can be made spiral and fixed on the shell; the radiator may be located on the longitudinal axis of the air blower. The cooling system may be located inside or outside the lighting system.

The drawing shows one example of the implementation of a lighting installation made in accordance with the claimed technical solution.

The lighting installation comprises a base 1, an inflatable shell 2 fixed thereon, filled with air, an air blower 3 installed in the base, in communication with the atmosphere and the cavity 4 of the shell. Inside the shell 2, at least one electric light source 5 is installed (four light sources are shown in the drawing) connected to a power source by an electric wire (not shown). The light source 5 is connected through a flange 6 and fastening elements 7 with an inflatable shell

2. The installation used a powerful LED light source 5, which emits a significant amount of heat. To remove heat and prevent overheating of the source 5, the installation is equipped with a radiator 8 installed in its base 1, located on the axis of the air flow from the air blower 3. Radiator 8 is filled with coolant. A hydraulic pump 9 and an expansion tank 10 are connected in series with a radiator 8, which is in communication with a drain pipe 11. In one embodiment of the installation, a radiator 8, a hydraulic pump 9 and an expansion tank 10 are installed inside the base (see drawing), and in another design they can be located behind outside the base.

The radiator 8 is in communication with the hollow module 12, intended for mounting on it a light source 5, as well as for cooling the latter. For this purpose, the sealed cavity 13 of the module 12 is filled with coolant and this cavity is in communication with the radiator 8 by the pressure pipe 14. In the case of one electric light source 5, it is mounted on the underside of the module 12, and in the case of several light sources 5, they are installed on different sides of the module 12. The lighting installation may contain several modules 12 located at the same height or under each other or in other combinations. Tubes 11 and 14 are made flexible and resilient. A possible embodiment of the tubes 11 and 14 spiral to increase the area of heat transfer and prevent them from twisting.

These hydraulic components are a liquid cooling system of the LED light source 5, and the radiator 8, which is one of the main components of the cooling system, has heat exchanger fins 15 on its outer surface, mounted longitudinally to the air flow coming from the air blower 3 from the bottom up. This air flow passes through the channels 16 between the ribs 15.

Due to the high heat capacity of the coolant under certain conditions (climatic, low power of the light source, low velocity of the fluid along the cooling circuit), it is possible to use the cooling system without a radiator 8. In this case, heat will be removed directly through the walls of the tubes 11 and 14.

Module 12 is made with inlet and outlet openings and fittings in them, connected with tubes 11 and 14. If there are several modules 12, they can be combined in one circuit of the cooling system in series or in parallel, or each of the modules 12 can have an autonomous cooling system.

The installation is also equipped with a power unit 17. In various embodiments, the power unit 17 may include an electric generator and an internal combustion engine or an electric accumulator (not shown). The installation is equipped with starting and adjustment equipment and controls (not shown).

The installation works as follows.

- 2 028004

An electric current is supplied from the power unit 17 to the air blower 3. When the supercharger 3 rotates, pressure air enters the cavity 4 of the casing 2 from the atmosphere, the casing is inflated, rises together with the associated module 12, the light source 5 and tubes 11 and 14. An electric current is supplied from the power unit 17 to the LED light source 5, during operation, the module 12 is heated. Along with this, electric current is supplied to the hydraulic pump 9, which pumps the coolant through the cooling system: hydraulic pump 9 - radiator 8 - tube 14 - cavity 13 of the module 12 tube 11 - expansion tank 10 - hydraulic pump 9. When the fluid moves along the specified circuit, heat is transferred to it from the module 12, which is heated from the light source 5, and the liquid is cooled by the radiator 8. In this case, the light source 5 is cooled by the cooled liquid through the wall of the module 12.

The heated coolant coming from the hydraulic pump 9 to the radiator 8 is cooled in the radiator 8 in such a way that heat is removed from the liquid by the radiator to the outside through heat exchange fins 15, which are blown by the working air blower 3. The liquid cooled in the radiator 8 enters through the tube 14 into the cavity 13 of the support 12, and the described operation cycle of the installation is repeated.

The design of this lighting installation allows to increase its power and luminous flux of light sources in relatively large limits due to the fact that the installation uses an effective liquid cooling system, the radiator of which is blown by a constantly working air blower of the installation. As a result of the use of LED light sources, the territory is illuminated most effectively in comparison with analogues known from practice. The reliability of the installation is also significantly increased, since its heat resistance and resistance of the light source to shock loads are increased. It should be noted that since the components of the cooling system can be located at the base of the installation or outside it, this can significantly reduce the mass of the upper part of the installation, its energy intensity and dimensions in the working position.

Claims (8)

CLAIM 1. A lighting installation comprising a base, an inflatable shell fixed thereon, an air blower communicating with the shell cavity and at least one electric light source located in the shell, characterized in that it is equipped with at least one hollow module fixed inside the shell, on which the light source is installed, the cavity of the module is in communication with the cooling system of the light source, while the light source is LED, and the cooling system is liquid and includes a pump with a module cavity by flexible tubes. 2. The lighting installation according to claim 1, characterized in that the cooling system is equipped with a radiator. 3. The lighting installation according to claim 1, characterized in that the cooling system is equipped with an expansion tank. 4. The lighting installation according to claim 1, characterized in that the tubes are made spiral. 5. The lighting installation according to claim 1, characterized in that the tubes are fixed on the shell. 6. The lighting installation according to claim 2, characterized in that the radiator is located on the longitudinal axis of the air blower. 7. Lighting installation according to claims 1 to 3, characterized in that the cooling system is located inside the lighting installation. 8. The lighting installation according to claims 1 to 3, characterized in that the cooling system is located outside the lighting installation.