RU2336457C2 - Lighting plant (versions) and lighting element thereof - Google Patents

Abstract

FIELD: lighting.

SUBSTANCE: invention concerns of time, temporary, essentially emergency lighting facilities and can be applied at night construction and roadway maintenance works in case of power outage, at emergency recovery operations. Plant contains support with in-built air-supply passage under pressure, support fastener to ground or bearing surface structure. Air flexible bag with inlet opening is attached to support. In front of inlet opening there is air valve connecting bag cavity to air source through air-supply passage. Light source is mounted inside of bag. Bag is provided with curvature and shaper modifier. Internal surface of bag section behind horizontal symmetry axis towards support is light-reflecting. Transmission ratio of bag reflecting sector is lower than transmission ratio of bag sector that is opposite to bag reflecting sector. Bag is separable connected to hollow-core and tubular support. Said air-supply passage is mounted within its cavity.

EFFECT: enhanced performance of lighting plant with provided displacement of light spot within illuminated surface and modified geometry of light spot.

10 cl, 32 dwg

Description

This technical solution relates mainly to temporary, mainly emergency, lighting equipment and can be used in construction and road works at night in cases of power outage, as well as during rescue operations in emergency conditions when it is necessary to quickly install and put into operation light source. This lighting installation can be used in any other technical field to illuminate territories and surfaces on which rescue or other work is carried out.

Lighting installations are known, each of which has an inflatable casing, a light source located in the casing, means for supplying gas to the casing, means for attaching a light source in the casing, a support on which the casing is installed or by which the casing is connected to the ground, and also means for fixing the installation [1-12], while in lighting installations [1, 6 and 7] the shell has a reflective surface; in lighting installations [2, 3, 5, 10, 12] inside the shell there are elements, rods, extensions, rods by which the shell is connected to a light source, and in the lighting installation [10] rods or elements through which the upper part of the shell is connected with protective grille of the light source, made by tension.

In the lighting installation [2], the rod on which the light source is mounted is connected with its upper end to the upper part of the shell, the lower end of which is connected to the upper end of the tension spring, the latter connected to the lower part of the shell in such a way that the rod essentially acts as an elastic an element providing the ability to change the shape and curvature of the shell surface with a change in gas pressure in the shell.

A close technical solution to this invention is a lighting installation containing a support, a means of attaching the support to the ground, an inflatable flexible shell connected to the support, forming a load-bearing structure in the working position, the cavity of the shell is filled with gas, and a light source located in the protective cavity is located in this cavity the lattice attached to the upper part of the shell, while the inner part of the top of the supporting structure of the shell is made of reflective material and has the ability to change the geometry and by lowering the Central part of the top of the structure, while the installation is performed with a means of changing the surface [12].

This installation does not provide the ability to control the light spot obtained from the reflective surface of the inner part of the top of the shell, which limits the functionality of the lighting installation.

The technical result of the invention is to expand the functionality of the lighting installation by providing the ability to move the light spot received from the reflective surface of the installation on the illuminated surface.

The technical problem is solved in that the lighting installation (first option) contains a support with an air channel therein for supplying pressurized air to the installation, means for attaching the support to the ground or to the supporting ground structure, an inflatable flexible shell connected to the support with an inlet opening in it, in front of which there is an air valve that communicates the cavity of the shell with an air source through the air channel, and on the shell, in its cavity, a light source is fixed, surrounded by a means of protecting it from contact with the shell, the shell is made with a means of changing its shape and curvature, the inner surface of the shell part, which is located behind the horizontal axis of symmetry to the side of the support, is made reflective, the transparency coefficient of the reflective part of the shell is less than the transparency coefficient of the part of the shell, which is opposite the reflective part of the shell, the shell detachably connected to a support, which is rigid and tubular, and said air channel is located in its cavity.

The lighting installation (second option) contains 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 flexible shell connected to the support with an inlet opening in front of which there is an air valve communicating the cavity of the shell with the air source through the air channel, and on the shell, in its cavity, a light source is fixed, surrounded by a means of protecting it from contact with the shell, while the shell is made with medium by changing its shape and curvature, the inner surface of the shell part, which is located behind the horizontal axis of symmetry away from the support, is made reflective, the transparency coefficient of the reflective part of the shell is less than the transparency coefficient of the part of the shell, which is opposite the reflective part of the shell, while the shell is detachably connected with a support, the support is located above the shell, between it and the supporting ground structure, which is located above the support.

A lighting installation (third option) comprises 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 flexible shell connected to the support with an inlet opening in front of which there is an air valve, the cavity cavity communicating with the air source through the air channel, and on the shell, in its cavity, a light source is fixed, surrounded by a means of protecting it from contact with the shell, while the shell is made with medium changes in its shape and curvature, the inner surface of the shell part, which is located behind the horizontal axis of symmetry away from the support, is made reflective, the transparency coefficient of the reflective part of the shell is less than the transparency coefficient of the part of the shell that is opposite the reflective part of the shell, while the shell is detachably connected with a support, the support is made of an additional inflatable shell filled with gas under pressure, in the cavity of the additional inflatable shell is mentioned mentioned air channel or cavity itself more air bag is an air channel.

The lighting installation (fourth option) contains 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 flexible shell connected to the support with an inlet opening in front of which there is an air valve communicating the cavity of the shell with an air source through the air channel, and on the shell, in its cavity, a light source is fixed, surrounded by a means of protecting it from contact with the shell, while the shell is made with Due to changes in its shape and curvature, the inner surface of the shell part, which is located behind the horizontal axis of symmetry away from the support, is made reflective, the transparency coefficient of the shell part, which is located in front of the reflective part of the shell, is less than the transparency coefficient of the reflective part of the shell, while the shell detachably connected to the support, the support is made of a flexible reinforced hose, in the cavity of which the aforementioned air channel is located.

A lighting installation (fifth embodiment) comprises a support with an air channel therein for supplying pressurized air to the installation, means for attaching the support to the ground or to the supporting ground structure, an inflatable flexible shell connected to the support with an inlet opening in front of which there is an air valve, the cavity cavity communicates with the air source through the air channel, and on the shell, in its cavity, a light source is fixed, surrounded by a means of protecting it from contact with the shell, while the shell is made with by changing its shape and curvature, the inner surface of the shell part, which is located behind the horizontal axis of symmetry away from the support, is made reflective, the transparency coefficient of the reflective part of the shell is less than the transparency coefficient of the part of the shell, which is opposite the reflective part of the shell, while the shell is detachably connected with support, the support is made telescopic from at least two hollow sections - the upper and lower, one of which is made rotatable relative to the other in horizontal plane, while the support sections are hollow and the said air channel is located in their cavities, the shell is pivotally connected to the support, and the installation comprises means for turning the shell in a vertical plane relative to the hinge.

The options provide that the air channel is formed by a pipe cavity or made of a flexible air hose located in the pipe cavity.

The tool for turning the shell in the vertical plane of the fifth installation variant is made of at least one rod, one end of which is fixed on the outer part of the shell above the hinged connection of the shell with the support, the middle part of the rod is located in the guide made on the outside of the support with respect to the vertical axis of the shell .

The lighting part of the installation contains an inflatable flexible casing with an inlet for supplying air or gas under pressure to the casing and with a means for attaching the casing to the installation support, surrounded by a means of protection against contact with the casing, a light source that is fixed to the casing in its cavity, a means of changing the shape and curvature of the shell, having upper and lower, opposite from the protective means, and two lateral elastic elastic or spring-loaded rods connected with the shell and protective means, the elastic modulus The upper and lower rods are larger than the elastic modulus of the lateral rods, the inner surface of one part of the shell, located behind the longitudinal axis of its symmetry away from the support, is made reflective, the transparency coefficient of the part of the shell located in front of the reflective part of the shell is less than the transparency coefficient of the reflective part of the shell, the input the hole of the shell is aligned with the axis of the means of fastening the shell to the installation support or is located anywhere else on the shell away from the means of fastening the shells to the support, wherein the shell formed on at least one means for its fastening to a support and at least one hole for supplying air into the shell.

In the lighting part of the installation, in the shell opposite the inlet, an additional inlet is made with an additional flange closed by a plug, the additional flange is identical in shape to the main flange.

In the lighting part of the installation, the shell has at least several flanges located around it.

In the lighting part of the installation, the hole for supplying air to the shell is made in the form of a sleeve of the shell with an element in it for attachment to the air hose.

The method of controlling the operation of the lighting installation includes injecting air or gas lighter than air into the inflatable shell, the inclusion of a light source inside the shell, characterized in that during installation the shape and size of the light spot on the illuminated surface are changed, as well as the brightness of the light, changing the geometry of the reflecting the surface of the inflatable shell, and the geometry of the reflecting surface is artificially changed due to the difference between the pressure on the shell from the action of air in it and the pressure on the shell about t stretched flexible elastic rods, while the specified pressure difference is obtained by bleeding air from the shell or forcing air into the shell.

The method involves setting the pressure generated by the upper individual elastic traction, more pressure created by the lateral individual elastic traction.

In the method, the pressure on the shell created by the upper elastic rods is chosen to be greater than the pressure that the lateral elastic rods exert on the shell.

In the method, the area of the light spot and the brightness of the light are controlled by bleeding the gas from the shell and reducing its pressure in the shell or by supplying air under pressure to the shell and increasing the pressure in it.

In the method, the area of the light spot is reduced and the brightness of the light is increased by forcing air into the shell.

In the method, the area of the light spot is increased and the brightness of the light is reduced by forcing air into the envelope.

Figure 1 shows a lighting installation in a working position with a minimum gas pressure in an inflatable flexible shell.

Figure 2 - lighting installation in working position at a nominal gas pressure in the shell.

Figure 3 - lighting installation with a maximum gas pressure in the shell.

Figure 4 - lighting installation with a support made of an inflatable flexible shell support.

Figure 5 - installation with a support made of a reinforced hose having an air channel.

Figure 6 - lighting installation in suspension with an upright support made of a reinforced hose having an air channel.

In Fig.7 - view A in Fig.6 (a diagram of one embodiment of the rods in the shell at a nominal gas pressure).

On Fig - view a in Fig.6 (diagram of another arrangement of rods in the shell at a nominal gas pressure).

In Fig.9 is a layout of another variant of the location of the rods in the shell at the maximum gas pressure in it.

Figure 10 - lighting installation with a displaced vertical axis of symmetry of the shell relative to the axis of the inflatable support at the maximum gas pressure in the shell.

Figure 11 - lighting part of the lighting installation and the arrangement of rods in the shell with different elasticity of the lateral rods and at maximum gas pressure.

On Fig - one of the options for attaching the shell to a telescopic support made of movably located one in the other sections.

On Fig - one of the options for the layout of the lighting installation, including the upper lighting part of the installation, in particular an inflatable shell with a light source in it, and a support made of another inflatable flexible shell, in the cavity of which there is a means of feeding into the shell of the upper lighting installation gas under pressure.

On Fig - one of the options for the support made of a hollow flexible rod, for example, of a reinforced hose that provides a reliable flexible suspension of the lighting part and the gas supply through the air channel of the hose.

On Fig - the upper part of the inflatable flexible shell in longitudinal section with a flange and a plug in the hole of the flange.

On Fig - one of the possible embodiments of the shell with rods, with limiters stretching vertically arranged rods (in each vertically located rod there is an anti-stretching rope).

On Fig - arrangement of light fluxes at a nominal gas pressure in the shell of the installation.

On Fig - arrangement of light fluxes with increased gas pressure in the shell of the installation.

On Fig - arrangement of light fluxes with a maximum gas pressure in the shell of the installation.

On Fig - arrangement of light fluxes at a nominal gas pressure in the shell of the installation.

On Fig - arrangement of the light flux from the reflective surface of the shell at the maximum gas pressure in the shell of the installation, which is made with a displaced transverse vertical axis of symmetry of the shell, inclined relative to the longitudinal axis of the installation at a given angle.

On Fig shows one of the possible options for performing elastic traction with a limiter.

On Fig shows a second embodiment of elastic traction with a limiter.

On Fig - light spot on the illuminated surface, obtained from the shell of the installation, having a spherical shape at a nominal gas pressure in the shell of the installation.

On Fig - light spot on the illuminated surface, obtained from the shell of the installation having a bent downward upper part of the shell of the installation with a minimum gas pressure in the shell of the installation.

On Fig - light spot on the illuminated surface, obtained from the shell of the installation, having an elongated oval shape with a maximum gas pressure in the shell of the installation.

On Fig - the fourth version of the lighting installation, the shell of the upper lighting part of which is filled with light gas and connected to the ground through a reinforced hose.

On Fig - the fifth version of the lighting installation, the lighting part of which is connected to the ground by means of a telescopic rod and is connected with the means of its rotation relative to the rod in a vertical plane.

On Fig shows the installation with an embodiment of the shell of the lighting part having several flanges for mounting the shell to the support, providing the ability to change the direction of the light flow depending on the choice of flange for mounting the shell to the support, in particular, shows the installation with the lighting part turned down (light flow down).

On Fig - installation with the lighting part turned up (the luminous flux is directed upwards).

On Fig - installation with the lighting part turned to the right (the luminous flux is directed to the right side).

On Fig - installation with the lighting part turned to the left (the luminous flux is directed to the left side).

Lighting installation, its five options are presented in figures 1, 4, 5, 6 and 28. The lighting part of the installation is presented in figures 9 and 29-32.

The first version of the lighting installation (figure 1) contains two main nodes that are quickly connected in their various combinations. The first unit of the installation is a support 1 and means 2 for fixing the support to the ground or to the supporting ground structure. The first installation unit performs the function of a load bearing structure.

The second node of the lighting installation is the lighting part of the installation, which performs the lighting function. The second unit of the installation includes an inflatable flexible shell 3 connected to the support 1, which can be made of sailing fabric slightly passing air, or from an elastic elastic material, or from a combined elastic-woven material that does not allow air and is capable of limited stretching.

The shell 3 is made of a translucent light-transmitting fabric or can be made of a transparent or translucent elastic material with the ability to stretch when it increases the pressure of gas or air and restore shape after pressure reduction. The shell at a nominal gas pressure has a spherical shape.

A sealed closed cavity 4 of the shell 3 which is filled with air or gas, which is lighter than air. The shell 3 in the working position is under air pressure from its source. In the shell 3 by means of rods 5 a light source is fixed. The rods 5 are located in the shell 3 radially and form at least one lower rod 5, one upper rod 5, and two side ones - the left and right rods 5. The rods 5 are conventionally called upper, lower and lateral rods for better understanding. It should be noted that when installing the installation, traction 5 can change places.

The upper and side rods 5 are spring-loaded or elastic. The lower link 5 can be spring-loaded or elastic and have greater elasticity in comparison with the other above-mentioned links 5. The lower link 5 can also have a limiter that limits its stretching. The lower rod 5 can also be made rigid.

One end 6 of each rod 5 is connected to a lamp protector or to a protective grill 7, to which a light source, in particular an electric lamp 9, is rigidly connected to the connection means (cartridge) 8. The other end of each rod 5 is connected to an inflatable flexible shell 3. Support 1 in the first version of the installation is made rigid, in the form of a hollow rack.

The shell 3 (due to the selection of resistance to tensile rods 5) is made with a means of changing its shape and curvature during operation of the installation. Such means are rods 5 (Fig. 9) located in the cavity 4 of the shell 3. The rods 5 can be arranged so that they form the upper group 10 of rods 5, the lower group 11 of rods 5 and two side (left and right from the axis of symmetry of the shell 3) groups 12 of rods 5. Each rod 5 of the side groups 12 in one of the structural solutions of the installation includes at least two interconnected elements 13 and 14, which are also made flexible and elastic, capable of stretching, compressing, increasing and shortening lengths. The ends of the elements 13 are connected to the shell 3 of the installation, the ends of the rods 14 are connected to the protective grill 7 in which the electric lamp 9 is located. The elasticity of the elements 13 is greater than the elasticity of the elements 14. The elasticity of the elements 13 of the rods 5 of the side groups 12 and the tensile forces of these elements are less than the elasticity and tensile forces rods 5 of the upper and lower groups 10 and 11. Shell 3 in Fig. 9 has a (conditionally) upper part 15, which is located on the upper side of the longitudinal horizontal axis of symmetry of the shell 3, and lower part 16, which is located on the lower side of the longitudinal th horizontal axis of symmetry of the shell 3.

The transparency of the upper part 15 of the inflatable flexible shell 3 may be less than the transparency of the lower part 16 of the shell of the upper part 15 of the inflatable flexible shell 3. This does not exclude such a performance when the transparency of the upper part 15 of the inflatable flexible shell 3 changes during operation of the installation due to stretching of the shell 3, and at a nominal gas pressure in the shell, the transparency of its upper part 15 is close to zero. This is due to the fact that the inner surface 17 (Fig. 15) of the upper part 15 of the inflatable flexible shell 3 is made reflective - a reflective coating 18 is applied to the indicated surface 17 of the upper part of the shell 3.

The first embodiment of the installation provides (in addition to the described construction of the support 1) the implementation of the support telescopic (Fig), from located at least two tubular hollow elements located in one another.

In the first embodiment of the installation (Fig. 1), the support 1 is connected with the outer side 19 of the lower part 16 of the inflatable flexible shell 3 by means of the pair of flanges described below, between which the shell is clamped, while the support 1 is made with an air channel 20 in communication with the air cavity 4 of the inflatable shell 3 through the inlet 21, which is made in the shell 3 and formed by the flanges for fastening the shell 3 to the support 1 described below. An air valve 22 is installed in the hole 21 or in front of it. In this case, by means of the support 1 and means 2 of fixing the support, Lena connection shell 3 with the earth. The air channel 20 is located in the cavity of the support 1 and is formed by the walls of the air hose described below or by the walls of the support 1.

It should be noted that the opening 21 of the shell 3 can be formed by a sleeve of this shell (not shown), in which a connecting element (not shown) is fixed for its connection with the support 1 of the installation or for connecting the sleeve of the shell with the air hose described below. The sleeve of the sheath is a cylindrical element made, for example, of sailing fabric and sewn to the sheath 3. At the end of such a sleeve, a connecting element is fixed for quick connection of the air hose to the sheath, for example, a ring having a means of connection.

In this case, the flange connection of the support 1 to the shell and the alignment of the hole 21 with the flange of the mounting of the shell to the support does not exclude the connection of the support with the shell in one place, and the supply of air into the cavity of the shell in another place of the shell, for example, via the shell sleeve.

The second variant of the lighting installation (Fig. 6) is made similarly to the first variant with the difference that the lighting part of the installation, in particular the casing 3, is installed under the supporting structure 23, which is located under the illuminated surface 24, for example, under the ceiling of a building whose floor is littered with debris filled with water or aggressive liquid. This mounting option is performed for the purpose of saving, providing the ability to change the direction of the light stream on the illuminated surface.

It should be noted that the illuminated surface refers to the surface of the earth, floor, wall or ceiling of a building or structure, or any other surface requiring lighting in order to eliminate the accident or rescue. In this embodiment of the lighting system, a hollow rope or the aforementioned reinforced air hose, which is described below, is used as a support 1. One end of such a hose is connected with the sheath 3, and the other end of the hose is connected with means 2 for attaching the unit to the supporting structure 23 of the structure. In this embodiment, the hole 21 is made in the shell 3 on the opposite side of the reflective coating 18 and in this hole 21 or in front of it is an air valve 22. The support 1 is located in the opening 25 of the structure 23.

Unlike the first installation option (Fig. 1), the support 1 of which is connected to the ground 26, in the second installation option, the support 1 (Fig. 6) made of a reinforced hose is connected to the earth 26 through the supporting structure 23 of the building.

It should be noted that in all installations, the inflatable flexible shell 3 (Figs. 1, 4, 5, 6 and 28) has a horizontal axis of symmetry 27 and a vertical axis of symmetry 28.

The air channel 20 (FIG. 6) in the second installation variant is located similarly to its location in the first installation variant — in the cavity 29 of the support 1, with the difference that the air channel 20 in the second installation variant is formed by the cavity 29 of the reinforced load-bearing hose 30 (FIG. 6 , 14) for supplying air from its source (not shown) into the closed cavity 4 of the shell 3 through the air valve 22.

It should be noted that the hose can be made with a thin, strong and light rope located in it (Fig. 14), rigidly connected to the sheath 3 and the fastening means 2 of the unit to the ground 26.

The third version of the lighting installation (Fig. 10, 11) provides for the implementation of the support 1 of the installation semi-rigid, for example, from another inflatable flexible shell (hereinafter the support shell) having a predetermined hardness after injection of air under pressure therein.

The axis 31 (figure 10) of such a semi-rigid support 1 in one installation design is structurally offset by a distance F relative to the vertical axis 28 of the shell 3. With increasing air pressure in the shell due to the difference in tensile strength of the side rods 5, upper and lower rods (Fig.11 ) axis 28 is further offset from axis 31 by a distance of F1. In this case, a second axis of symmetry 32 of the shell 3 is formed, and the grating 7 and the electric lamp 9 are moved to a distance F1 from the initial position shown in FIG. 10. In this case, the grating and the electric lamp when changing the shape of the shell 3 are located on the axis 32. In the third embodiment of the lighting installation (Fig. 10), the support 1 is made of an inflatable flexible shell 33, which has greater rigidity compared to the rigidity of the shell 3. The shell 33 of the support is connected with means 2 for fixing the support 1 to the ground 26. In the shell 33 there is a sealed closed cavity 34, which is in communication with the air cavity 4 of the shell 3 through the inlet 21 of the shell 3 or through the air valve 22 located in this hole or in front of it.

The fourth installation option (Fig. 5) has a lighting part identical to the previous versions, which is flexibly connected to the ground 26 through a support 1 made of a hollow rope or from a reinforced hose 30 (Fig. 14) with an air channel 20 in it, and such a hose has ability to bear tensile load. This installation option involves filling the shell 3 with gas, which is lighter than air. Due to the unified flanges of fastening the sheath 3 to the hose 30, the reflective surface 18 can be directed upward if the sheath 3 is rotated 180 degrees in the frontal plane and attached to the hose 30 by other flanges described below. This is done in order to provide the possibility of changing the position of the light stream on the illuminated surface. It should be noted that under the illuminated surface (Fig.17-20) refers to that part of the illuminated surface 35, which is affected by the scattered light stream 36 from the entire installation casing 3 and the directed light stream 37 reflected from the reflective coating 18 of the shell. The light fluxes 37 shown in FIGS. 17-20 are obtained in accordance with the shapes of the sheath 3 shown respectively in these figures. From each shape of the casing 3, a common light spot 38 (FIGS. 24-26) is formed on the illuminated surface 35. The illumination of a part of the light spot 38, which is obtained from the diffused light stream 36, is less than the illumination of the light spot 39, which is obtained from the directed light stream 37, wherein a light spot 39 having high illumination is located inside the light spot 38. It should be noted that the light spot 39 is formed when the illuminated surface 35 is illuminated by an electric lamp 9 through a reflective coating 18 of the upper part 15 of the installation shell 3 and a light spot 38 is formed when the illuminated surface is illuminated through the translucent lower part 16 of the shell, which operates as a light diffuser in different directions from the center of the electric lamp 9.

Light spots 38 and 39 (Fig. 24) correspond to the shape of the casing 3 of the apparatus shown in Fig. 17. Due to the different curvatures of the reflective surface 18 of the shell 3 (FIG. 20), the light spot 39 (FIG. 25) has a central zone 40, a middle zone 41 and a peripheral zone 42. These zones have different degrees of illumination and all of them are part of the light spot 39, received from the directional stream of light 37 (Fig.20). The light spots 38 and 39 shown in FIG. 26 correspond to the shape of the shell 3 of the apparatus, which is shown in FIGS. 19, 21.

In all four variants of the lighting installation, the installation casing 3 with the grill 7 fixed in it, rods 5 and an electric lamp 9 is a removable separate unit of the installation. In order to increase the universality of the installation, the upper part 15 (Fig. 1) and the lower part 16, as well as the side parts of the casing 3, can have several aforementioned standardized flanges 43 (Figs. 29-32), by means of which the support 1 can optionally be attached to the upper part 15 of the shell (Fig) or to the lower part 16 of the shell 3 (Fig), or to the side parts of the shell (Fig and 32). In each specified flange 43, the aforementioned hole 21 is made. If the shell 3 has several flanges 43 (Fig. 29), then it is fixed to the support 1 by only one flange 43, while the holes 21 of the other flanges 43 are closed by plugs 44. Flanges 43, plugs 44, the grill 7 is made of ultralight durable material and have minimal material consumption and weight.

In all four versions of the lighting installation, its working elements providing for changing the curvature and shape of the shell 3 are flexible elastic or flexible spring-loaded rods 5, which are the main elements of the means for changing the shape of the shell 3. On Fig presents one example of a rod 5, which is made with the limiter 45 located in the cavity of the spring 46, the ends of which are connected with the elements 13 and 14 of the rod 5. The limiter 45 is made of inextensible material and shown in Fig.22 in its working tensioned position, limiting further spring tension. On Fig shows a variant of the elastic rod 5, made of two movably interconnected elastic elastic elements 13 and 14, and the elastic element 14 is hollow and the element 13 is located in the cavity of this element. Some ends of the elements 13 and 14 are interconnected, others the ends of these elements are connected to the shell 3 and the lattice 7.

In all four versions of the lighting installation, guy wires 47 are provided. In the first and third variants of the installation (Figs. 1, 4), guy wires 47 serve to ensure the stability of the lighting system under high wind loads acting on the lighting installation. In the second and fourth versions (FIGS. 6 and 27), the guy wires 47 also serve to move the installation casing 3 in different directions during its operation in order to move light spots of light on the illuminated surface.

The fifth embodiment of the installation (Fig. 28) includes a telescopic support 1 made of at least two telescopically located in the other upper section 48 and lower section 49. Both sections are hollow. The upper section is mounted on the lower section with the possibility of its fixation on the lower section and rotation according to the arrows indicated in Fig. 28 in a horizontal plane relative to the lower section. To the upper section 48 of the flanges 43 attached shell 3 of the lighting of the installation. The upper section 48 is connected by a hinge 50 to the flanges 43 of the shell 3. The air channel 20 of the installation is connected with a source of air pressure (not shown) from the air cavity 4 of the shell 3 through an opening in the shell 3, which is identical to the openings 21 in the above installation variants. In the fifth embodiment of the installation for supplying air to the shell 3, the above-described hose 30 is used located in the cavities of the support sections. The cavities of sections 48 and 49 also serve as the air channel 20, which communicates the source of air pressure with the shell in another modification of the installation.

The upper section 48 of the support 1 in the fifth installation option is made L-shaped. The hinge 50 is located at the end of the L-shaped section 48. The shell 3 is fixed at the end of the section 48 with the possibility of its location in the recess of the L-shaped contour of the upper section 48 at the lower position of the shell 3. The shell 3 has a means of rotation in a vertical plane relative to the hinge 50. To rotate the shell 3 and the entire lighting part of the installation in a vertical plane in this installation version, a flexible pull rod 47 is used, which at one point is fixed to the outer side of the shell 3 at point 51. The middle part of the guy 47 is prop schena through the opening guide 52 attached to the rear side of T-shaped top section 48. The other end of the backstay 47 is fixed to fastening means 2 for setting the ground, e.g., through driving element 53, designed as a rope drum on which brace 47 is wound.

The lighting part of the installation is described in the five options described above.

The operation of the first embodiment of the lighting installation (FIGS. 1, 2, 3, 12) includes the operation of pumping air from its source under pressure into the cavity 4 of the inflatable shell 3 of the installation through the air channel 20 and through the air valve 22. The air is supplied to the air cavity 4 until the establishment of the working minimum gas pressure in the air cavity 4, which corresponds to the working minimum installation position shown in figure 1.

When air is supplied under pressure, in the case of a decrease in its supply and a drop in air pressure in the air channel 20 and in the cavity 4 of the shell 3, the air valve 22 closes. In this case, the inflatable flexible shell 3 takes a working minimum shape, which corresponds to the spherical shape of the shell 3 with sagging curved downward from the weight of the grill 7 and the electric lamp 9, the upper part 15 of the shell 3 (figure 1). After that, the light bulb 9 is turned on.

When the installation is operating in the minimum mode (Fig. 20), the casing 3 is a luminous spatial structure with a directional light stream 37 emanating from it downward and a diffused light stream 36. These streams of light form light spots 38 and 39 (Fig. 25) on the illuminated surface 35. The light spot 39 will have different zones that differ in degree of illumination from each other due to different curvatures of the upper part 15 of the casing 3. These zones of illumination include the central zone 40, middle zone 41 and peripheral zone 42.

If it is necessary to change the shape of the light spots 38 and 39, for example, to increase the diameter of the light spot 38, to concentrate the light flux of the light spot 39 on the illuminated surface 35 due to the concentration of the reflected light stream 37, then pressure is additionally supplied to the cavity 4 of the shell 3. At the same time, the air pressure in the cavity 4 increases, the shell 3 swells or deforms within the acceptable elasticity range of the rods 5 and takes the form of a ball (Fig.2, 17). In this case, a light spot 38 and a light spot 39 are formed on the illuminated surface 35 (Fig. 24), while the illumination in the region of the light spot 39 increases due to the concentration of reflected light rays from the reflective spherical shape of the surface 18.

With a further increase in gas pressure in the shell 3 of the installation, the shell due to the operation of the lateral elastic elements 13 and 14 of the rods 5 lengthens (Figs. 3, 9-11 and 19) along the longitudinal axis of its symmetry 27. Moreover, in accordance with the elasticity of the elements 13 and 14 the shell 3 is extended in opposite sides from the center of the shell at the same time, or in opposite directions sequentially, or it is extended in one side. In this case, the casing 3 takes an oval shape, and the light spots 38 and 39 (Fig. 26) on the illuminated surface 35 take an oval shape corresponding to the shape of the casing 3 of the apparatus elongated along the longitudinal axis 28 (Fig. 3).

If it is necessary to increase the installation height, provided that the telescopic support is implemented (Fig. 12), the height of the support 1 is increased, for which the inner pipe of the support is extended from the outer pipe of the support, and then they are fixed in a predetermined working position. This operation is performed in the horizontal position of the installation, which does not exclude the possibility of the extension of the inner pipe of the support from the outer pipe using telescoping means (not shown) with the vertical position of the support 1.

When the installation is working, it is possible to displace the axis of symmetry 28 of the sheath 3. This displacement is carried out by selecting the elasticity and tensile ability of the elastic elements 13 and 14 (Fig. 9) of the flexible rods 5 of the side groups 12. The choice of the elasticity of the elements 13 and 14 rods 5 of these groups 12 provides the possibility of lengthening the shell 3 to the right or left side with increasing air pressure in the shell 3, or the possibility of lengthening the shell to the right and left sides at the same time. If the casing 3 is moved to one of its sides to this side, the electric lamp 9 moves to the indicated distance. It should be noted that the location of the grating 7 and the electric lamp 9 remains unchanged provided that the sides of the casing 3 are moved from the symmetry axis 28 of the casing 3 by the same distance.

If it is intended to move the shell to the left side, then the elasticity of the elements 13 located on the left side of the shell 3 should be less than the elasticity of the elements 13, which are located on the right side of the shell 3 from the axis of symmetry 28. If it is intended to move the shell 3 to the right side, then the elasticity of the elements 13 on the right side of the shell 3 from the axis of symmetry 28 should be less than the elasticity of the elements 13 located on the left side of the shell 3. If simultaneous movement of the shell 3 to the left and right sides is provided, then the elasticity elements 13 located to the right and left of the axis of symmetry 28 should be the same. The elasticity and the ability to stretch the elements 14 in the right and left parts of the shell 3 from its axis 28 is chosen to be less than or equal to the elasticity and tensile ability of the upper and lower rods 5.

The elasticity of the left and right elements 13 corresponds to the distance of movement of the left or right parts of the shell 3 away from the axis of symmetry 28 of the shell with increasing air pressure in it. Figure 11 shows an example when the elasticity of the element 13 or the right elements 13, which is right of the axis 28, is greater than the elasticity of the left element 13 or left elements 13.

The work of the second variant of the lighting installation (Fig.6) is as follows. Since the shell 3 of the installation and the elements located in it represent the upper lighting removable part of the installation, if necessary, for example, during rescue operations in closed emergency buildings (rooms), the floor of which is flooded with water or aggressive liquid, or during rescue operations in cases blockages of the floor with shapeless masses of damaged structures, the shell 3 (in which there is no air) is removed from the support 1, the plug 44 is removed (FIG. 15) from the holes of the upper flanges 43 of the shell 3 (FIG. 1), the shell is turned over 180 ° and swap the upper and lower parts 15 and 16 of the shell. A flexible support 1 made of a reinforced hose 30 (Fig. 6) is connected and the air valve 22 is connected to the sheath 3. The hose 30 is connected to the sheath 3 so that the reflective surface 18 is opposite the hose 30. Enter the opening 25 of the structure 23 of the emergency building the sheath 3 which is in a deflated state and fasten it with the fastening means 2 on the structure 23. The air 3 is pumped into the sheath 3 through a reinforced hose 30, aperture 21 and an air valve 22. The light bulb 9 is turned on. The light stream reflected by the reflecting surface 18 illuminates the surface 24 of the supporting structure 23 or the ceiling of the building, from which light spreads to the floor of the building. If necessary, the installation shell 3 suspended in air can move in different directions relative to the mounting means 2 by guy wires 47, one ends of which are fixed to the installation shell 3, and their other ends are brought out above the upper surface of the supporting structure 23, on which the servicing lighting staff.

The work of the third version of the lighting installation (Fig. 4, 10, 11, 13) is carried out in the same way as in the first embodiment of the installation design, with the difference that before bringing the lighting part of the installation and the casing 3 into working position, pressure air is first supplied to the fixed on the ground 26 by means of fastening 2 deflated shell 33, in particular in its air cavity 34, and after reaching a certain air pressure in this cavity and the shell 33 acquires support 1 of hardness, this support 1 is installed in a known manner in a vertical position. After that, the air valve 22 is installed, installed between the shell 33 of the support and the shell 3 of the installation and air under pressure enters the air cavity 4 of the shell 3 through the hole 21 of the shell and the air valve 22. During the injection of air into the cavity 4 of the shell 3, the valve controls the pressure drop in established limits, which ensures the stability of the shell 33 of the support 1 during air pressure drops.

The work of the fourth installation option (Fig. 5) is similar to the work of the first installation option, with the difference that the reflective surface 18 is placed towards the ground 26, on which the mounting means 2 fasten the support 1 made of a flexible reinforced hose 30. Then, through the air channel of the hose 30 and the air valve 22 feed gas into the air cavity 4 of the shell 3 under pressure that is lighter than air, and as the amount and pressure of gas in the air cavity 4 of the shell 3 increases, the latter rises into the air. Then turn on the light bulb 9, regulate the gas pressure in the cavity 4 of the shell 3 and change the shape of the shell and the shape of the light spots on the illuminated surface as described above. In this case, the installation shell 3 suspended in air in the air can move in different directions relative to the fastening means 2 by guy wires 47, one ends of which are fixed to the installation shell 3 and the other ends hang freely above the ground 26 or are fixed on it. To move the shell 3 above the ground 26, some guy wires 47 are pulled, and other guy wires 47 are loosened. When pulling the right guy 47 and loosening the left guy, the shell 3 is moved to the right side and vice versa.

The operation of the fifth embodiment of the lighting installation (Fig. 28) is carried out similarly to the operation of the first installation option, with the difference that, if necessary, the upper rotary section 48 is rotated around the stationary support section 49 in the horizontal plane and the light stream 37 is moved from the reflective surface 18 of the shell 3 in the horizontal plane, and in case it is necessary to adjust the angle of inclination of the light stream 37 in the vertical plane, then the shell 3 is rotated relative to the hinge 50 in the vertical plane. To do this, the guy 47 is pulled or loosened by a drive element 53 onto which the guy 47 is wound or twisted. When the guy 47 is pulled, the sheath 3 is turned upward from the hinge 50, while the guy 47 is loosened, sheath 3 is turned down under its own weight. If necessary, in the manner described above, the shape of the stream of light 37 and the light spot on the illuminated surface is changed.

The operation of the lighting part of the lighting installation (Fig.9, 11). When air is supplied under pressure into the cavity 4 of the installation casing 3, the tensile force from the air pressure acting on the elements 13 (Fig. 9) of the rods 5 of the side groups 12 increases, the elements 13 stretch and the sides of the casing 3 are removed from the vertical axis of symmetry 28 of the casing (Fig. .eleven). When the gas supply to the cavity 4 of the shell 3 is stopped, the air valve 22 closes. In this case, the shell 3 in the side and top views takes the form of an oval, since the upper and lower parts 15 and 16 of the shell sag or stretch due to the elasticity properties of the rods 5, as well as due to the transformation of a spherical shape (at a nominal pressure of air or gas in the shell) into an oval shape by changing the shape of the shell 3 and removing its sides from the center of the shell along the horizontal axis 27. At the same time, the shape of the inner surface 17 and, accordingly, the surface of the reflective coating 18 of the upper part 15 of the shell 3 trans is formed and changes, or partially increases in different directions, and the sides of the shell are elongated in the direction of the horizontal axis 27 in opposite directions from the vertical axis 28. In this case, the light flux 37 and the light spot on the illuminated surface 35 changes as described above, increases in diameter or lengthens along the horizontal axis of the shell.

To reduce the size of the light flux 37 and the light spot on the illuminated surface 35 and change the lighting parameters in the opposite direction, the air pressure in the cavity 4 of the shell 3 is reduced. To do this, through the air valve 22, air or gas from the cavity 4 is released into the atmosphere until the luminous flux 37 of the required size is formed on the illuminated surface 35 with the necessary lighting parameters. Air bleeding from the casing 3 is carried out by the operation of the air valve 22 by adjusting the position of the valve locking element, which closes or opens the inlet 21 of the casing 3.

The operation of the air valve 22 is not disclosed in this description. As an example of the operability of the air valve 22, there can be such a performance when the valve operating element opening and closing the inlet 21 of the installation shell 3 has an electromagnetic drive electrically connected to the power supply circuit of the electric lamp 9.

If the lighting part of the installation (Fig. 29), in particular its casing 3, has several, for example four, flanges 43 for attaching it to the support 1, then, by choosing one flange from four flanges, the casing 3 of the lighting part of the installation is attached to the installation before starting work support 1 in such a way as to set the desired direction of the light flux 37 in the upper, lower, right or left sides, as shown in Fig.30-32.

Description of the operation of the lighting system. By adjusting the pressure of air or gas in the cavity 4 of the shell 3 by decreasing or increasing it relative to the nominal air pressure in the cavity 4 of the shell 3, the shape of the light spot on the illuminated surface is changed and thus the illumination of the illuminated surface is changed in a given direction (Figs. 17-26).

Moreover, in the case of a nominal air pressure in the shell 3, it has a spherical shape. As follows from the description of the operation of the design options of the lighting installation, the installation control method consists in reducing or increasing the shape and curvature of the reflective surface of the installation envelope by increasing or decreasing the gas pressure in the envelope with respect to its nominal pressure, and resizing the flow of light from the reflective surface of the shell and the shape of the light spots on the illuminated surface and change the illumination of this surface.

Information sources

1. US 5947581, 09/09/1999.

2. RU 2123874 C1, 12/27/1998.

3. WO 02/44613, 06/06/2002.

4. EP 1394466, 03.03.2004.

5. RU 36486 U1, 03/10/2004.

6. WO 02/063207 A1, 08/15/2002.

7. WO 04/025172, 03/25/2004.

8. US 5102364, 04/07/1992.

9.JP 9306210, 11.28.1997.

10. JP 2004228053, 12/08/2004.

11.JP 2003157712, 05.30.2003.

12. WO 99/47853, 09/23/1999.

Claims (10)

1. A lighting installation comprising 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 casing connected to the support with an inlet opening therein, in front of which there is an air valve communicating the casing cavity 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 having the top opposite to the means of protection nu and lower and two lateral elastic elastic or spring-loaded rods associated with the shell and the 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 opposite transparency coefficient ( the lower part of the shell, while the shell is detachably connected to a support, which is hollow and tubular and in its cavity is located the aforementioned air channel in communication with the cavity of the shell. 2. A lighting installation comprising 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 opening in front of which is installed an air valve communicating the shell cavity 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, having the top opposite to the means of protection nude and lower and two lateral elastic elastic or spring-loaded rods associated 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 channel in it m 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. 3. A lighting installation comprising 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 casing connected to the support with an inlet opening therein, in front of which there is an air valve communicating the casing cavity 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, having the upper south and lower and two lateral elastic elastic or spring-loaded rods associated with the shell and 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 hollow and tubular and in its cavity there is an air channel in communication with the cavity of the shell, while the support with an air channel in it for supplying air to the shell under pressure, it is made of an additional inflatable shell forming an air channel filled with gas under pressure. 4. A lighting installation comprising 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 casing connected to the support with an inlet opening in front of which there is an air valve communicating with the casing cavity 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, having the upper south and lower and two lateral elastic elastic or spring-loaded rods associated 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 opposite transparency coefficient ( the 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 an air channel is located. 5. A lighting installation comprising 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 casing connected to the support with an inlet opening in front of which there is an air valve communicating the casing cavity 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, having the upper south and lower and two lateral elastic elastic or spring-loaded rods associated with the shell and the means of protection, 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 transparency coefficient of the opposite (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 made rotationally relative to the other d 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. 6. The lighting installation according to claim 5, characterized in that the means for turning the shell in a vertical plane is made of at least one rod, one end of which is fixed to the outer part of the shell above the hinged connection of the shell with a support, the middle part of the rod is located in a guide made on the outside of the support with respect to the vertical axis of the shell. 7. The lighting part of the installation, containing an inflatable flexible shell with an inlet therein for supplying air or gas under pressure to the shell and with a means of attaching the shell to the installation support, surrounded by a means of protection against contact with the shell, a light source that is mounted on the shell in its cavity , means for changing the shape and curvature of the shell, having upper and lower and two lateral elastic elastic or spring-loaded rods opposite the protective equipment, connected with the shell and protective means, the elastic modulus the upper and lower rods are larger than the elastic modulus of the lateral rods, the inner surface of one part of the shell located behind the longitudinal axis of its symmetry away from the support is made reflective, the transparency coefficient of the part of the shell located in front of the reflective part of the shell is less than the transparency coefficient of the reflective part of the shell, the shell inlet is aligned with the axis of the shell mounting means to the installation support or is located anywhere else in the shell away from the shell mounting means glasses to the support, while at least one means of attaching it to the support, for example a flange, and at least one hole for supplying air to the shell are made on the shell. 8. The lighting part of the installation according to claim 9, characterized in that in the shell opposite the inlet there is an additional inlet with an additional flange closed by a plug, the additional flange is identical in shape to the main flange. 9. The lighting part of the installation according to claim 9, characterized in that its shell has at least several flanges located around it. 10. The lighting part of the installation according to claim 9, characterized in that the hole for supplying air to the shell is made in the form of a sleeve of the shell with an element in it for attachment to the air hose.

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