RU2192581C1 - Emergency lighting plant - Google Patents

Abstract

FIELD: lighting engineering. SUBSTANCE: emergency lighting plant has base on which inflatable support made from flexible transparent airtight envelope is secured. Secured on outer surface of support are flexible stabilizers located vertically at different levels. Stabilizers are secured on support by means of retainers which are connected with tie rods whose lower ends are connected with ground. Diaphragm found inside support is provided with inlet and outlet valves. Lower end of envelope is secured on base by means of flange and flexible lower ring received by circular groove of flange. Gap formed between lower surface of flange butt and upper surface of base is used for free position of envelope. EFFECT: enhanced reliability. 7 cl, 13 dwg

Description

 The invention relates to means for lighting streets, territories, terrain, squares, water spaces, mainly in cases of urgent need for lighting during accidents of lighting networks in emergency situations associated with earthquakes, floods, destruction of residential and industrial arrays in cases of bombing, volcanic eruptions, descent mudflows and landslides damaging energy communications, as well as in cases of other catastrophic events, when there is a need for quick coverage of territes ry in order to find victims or missing persons or to eliminate the consequences of the above situation. The invention can also be used in the gas and oil industry in cases of damage to highways, as well as in transport in cases of significant damage to the power supply network, destruction of the rail track or highways. In addition, the installation can be used when conducting search, investigative measures by security agencies at night. At the same time, this technical solution does not exclude its use in unlit crowded places at night and can be used to illuminate parks, gardens, lawns, stadiums and other unlit places that require increased safety with poor visibility.

 A known installation for lighting the terrain, containing a hollow support with a module mounted on it, in the housing of which an air blower is installed, communicates with the cavity of the flexible shell, while a folding light diffuser is located on the housing [1].

 This installation, in addition to the mentioned module, requires the use of a support, which, however, is not intended for quick installation in emergency conditions, which is one of the disadvantages of this technical solution.

 Another well-known technical solution intended for illuminating a space includes a flexible transparent shell inflated by an air blower installed in a hollow support, while the air is used to cool the lamp and maintain the flexible shell in working position, with holes made in the upper part of the support, air blower located under the lamp between the transverse bridge of the support to which the lighting lamp is attached and the air intake grille, the lamp is installed inside the support by means of a flange attached Nogo to a support, and an air blower connected to said flange [2].

 This technical solution relates to decorative lighting, it simultaneously solves the problem of cooling the incandescent lamp and opening the lampshade shell by the pressure of the air flow from the blower fan.

 The use of air flow to bring the support into working position is also known from another technical solution, in which a hollow rod vertically mounted inside the telescopic sections is used to extend the sections of the telescopic support, with a cavity connected to a corrugated pipe for supplying a stream of compressed air to the working cavities of the telescopic sections of the support [ 3].

 The support of this technical solution is made of rigid sections, has many joints and spring-loaded seals located in sections with the possibility of their sliding on the working surfaces of the sections, which greatly complicates the design of the support.

 A device is also known for lighting areas of rescue operations, production sites, sports areas, including carrying cylinders filled with gas lighter than air and equipped with connecting cords that hold the cylinders together, as well as extensions associated with the cylinders and the ground, lamp lamps and live wires, this luminaire is rigidly connected to the lower surfaces of the bearing cylinders using fasteners, and fasteners are located on the surface of the reflectors of the luminaires and lower bearing surfaces of cylinders [4].

 This device has a relatively complex design.

 In another technical solution, the lighting lamp includes a cone-shaped hollow support made in the form of an elastic spiral profile made of a metal tape, which is compactly laid in the initial state in a roll in the inner cavity of the connecting sleeve covering the wide end of the tube, on the other end of which there is a lamp or reflector and a cartridge with incandescent lamp. The design of the lamp allows you to power from an external source and from batteries located inside the lamp housing [5].

 This design of the lighting device is also complex, metal-intensive and heavy, which negatively affects the operational capabilities of this technical solution.

 Known pneumatic installation for lighting the terrain, including a pneumatic telescopic support, a light source installed in the upper section of the telescopic support, a flange mounted on the lower section under the protrusion of the upper section, an air blower in the working cavity of the telescopic support [6].

 The disadvantage of this installation is the limited height, since rigid sections of the support require a significant number of seals with an increase in the number of sections and the height of the support, which does not ensure the effectiveness of the design.

 The closest technical solution in essence and the achieved effect to the invention is an 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, in which there is a flashlight with a flange for attaching it to the upper end part supports located in the upper and lower parts of the support means for connecting the shell of the support with the base and the lamp, as well as stretch marks associated with the upper part of the support and the ground [7].

 In this technical solution, the means of connecting the shell of the support with the lamp and the base are not effective enough in operation, since during the injection of the air flow into the shell, the places of its connection with the lamp and the base experience significant dynamic loads that cause rupture of the fabric of the shell.

 At the same time, at the initial stage of injection into the shell of the air support, when the flexibility of the support shell is maximum, the support shell is in contact with the ground, contaminated and the light emission efficiency of the installation is reduced.

 When folding the installation into transport position, bleeding air from the cavity of the shell, drastically reducing the pressure in the support and increasing the flexibility of the shell, the risk of falling of the upper part of the installation with the lamp from a high height and damage to the lamp and the upper part of the installation increases.

 The solved and achieved goal of the invention is to increase the reliability and performance of the installation.

 This goal is achieved by the fact that the 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, in which there is a lamp with a flange of its fastening to the upper end of the support, located in the upper and the lower parts of the support means for connecting the shell of the support with the base and the lamp, as well as the stretch marks associated with the upper part of the support and the ground, is equipped with air pressure stabilizers in the shell attached to the outer surface of the support shell in height of the latter at different levels, each stabilizer is made of elastic elastic material, the tensile strength of each lower stabilizer is chosen less than the tensile strength of each upper stabilizer located above the lower stabilizer, the means for connecting the support shell to the base is made in the form of an elastic ring and the lower flange with an annular groove in which an elastic ring is located, connected along the perimeter with the end of the shell of the support, and the elastic ring o is located between the fastened flange and the base with the possibility of forming a gap between them, in which the shell of the support is freely located, while the lower stabilizer is located in the middle of the support, and below the lower stabilizer in the inner cavity of the support there is a diaphragm that separates the inner cavity into the lower and upper sections moreover, the diaphragm is made with inlet and outlet valves and the inlet of the inlet valve is smaller than the inlet of the outlet valve.

 This goal is also achieved by the fact that the lower flange is made with an annular stop, internal flanging, forming a central hole - a bell for air passage, the end of the inner flanging and the end of the ring stop of the lower flange are located in the same plane with the possibility of tight contact with the adjacent surface of the base, and the lower surface of the outer end of the flange is located above the plane.

 Each end of the support shell is connected to the elastic ring by means of a loop made at the end of the shell covering the ring along the perimeter of its cross section.

 Each end of the support shell in another installation variant is connected to the elastic ring by means of a spiral formed by the end part of the shell located in the annular groove of the lower flange with the possibility of pinching the spiral of the shell in the annular groove when the elastic ring is compressed.

 Each stabilizer is fixed to the outer surface of the shell of the support by means of latches located around the perimeter of the support and fixedly connected with the said surface.

 Each stretch is associated with a stabilizer latch.

 In the flange of the lantern mounting to the upper end part of the support, ventilation holes are made, each axis of which is located between the plane forming the surface of the lamp and the shell of the support.

In FIG. 1 shows an emergency lighting system,
in FIG. 2 - emergency lighting installation in longitudinal section,
in FIG. 3 - node mounting the shell of the support to the base,
in FIG. 4 is a diagram of the mounting of the support shell to the base during installation (lower flange in its highest position),
in FIG. 5 - another option for mounting the shell of the support to the base of the installation during installation,
in FIG. 6 - shell loop under the fastening ring,
in FIG. 7 is a view A in FIG. 6
in FIG. 8 - spiral shell under the fastening ring,
in FIG. 9 is a view B in FIG. 8,
in FIG. 10 - the relative position of the fastening elements of the shell of the support to the base in the position of tight contact of the end face of the annular stop and the outer surface of the base in another embodiment of the shell,
in FIG. 11 - stabilizer clamp and stabilizer mounted on a support,
in FIG. 12 is a view B in FIG. eleven,
in FIG. 13 is a view D in FIG. 1.

 Emergency lighting installation (Fig. 1) includes a base 1 with inner and outer surfaces 2 and 3 (Fig. 2), fixed on the base of the support 4, made of a transparent flexible thin thin airtight fabric. The support 4 is an inflatable airtight shell 5, which in the working inflated condition occupies the position of a vertically located support 4, which in the idle, transport position is transformed into the shell 5 and is in a folded compact state.

 On the upper end part 6 of the support 4, a lantern 7 is fixed, which is located in the inner cavity 8 of the support 4. The installation has means for attaching the support 4 to the base 1, made in the form of a flange 9 having a circular shape in this embodiment of the installation. Another means of fastening the lantern 7 to the upper end part 6 of the support 4 in this embodiment of the installation is also made in the form of a round flange 10. It should be noted that the said flanges can be made in the form of some other figure, for example, in the form of an oval, ellipse , parallelogram.

 The supercharger 11 of air into the air cavity 8 is connected with the latter through an opening 12, which is made in the base 1. The lantern 7 and the supercharger 11 are connected to the power supply 13 by electric wires 14 and 15. The installation is equipped with fasteners 16, 17 and 18 attached to the outer surface of the support 4 pressure stabilizers 19, 20 and 21, located sequentially at different levels of the support along its height. Each pressure stabilizer is made of elastic elastic material. The latches 16, 17 and 18 are mounted on the support 4 in a known manner with the possibility of formation between the outer surface of the support 4 and the inner surfaces 22, 23 and 24 of the latches of closed circuits with gaps 25, 26 and 27, in which the pressure stabilizers 19, 20 and 21 are freely located .

 In the given embodiment example (Fig. 1), the emergency lighting installation has several stabilizers fixed to the support 4 by means of clamps, the first of which is the lower stabilizer 19 fixed in the middle of the support 4 at the level N / 2, where H is the height of the support 4.

 The tensile strength R1 of the lower stabilizer 19 when air is filled with air 8 is less than the tensile strength R2 of the upper stabilizer 20, and the tensile strength R3 of the stabilizer 21 located above the stabilizer 20 is less than the tensile strength of the latter. The cross-sectional areas of the pressure stabilizers are selected different with increasing from the base 1 of the installation to its upper end part 6, while other options for choosing resistance to tensile pressure stabilizers are not excluded.

The means of fastening the support 4 to the base 1 (Fig. 2), which is the lower flange 9, has a bell 28 (central hole with flanging), an annular groove 29 and an annular stop 30, which are concentric about the axis 31 of the support 4 and the lower flange 9. Ring the stop 30 is located between the socket 28 and the annular groove 29 (Fig. 3), which is located on the periphery of the lower flange 9. The lower surface 32 of the flange 9 is made round and a gap 34 is formed between it and the outer surface 3 of the base 1. The thickness t of the end face 33 of the flange 9 less than the thickness t _{1 of the} ring pack 30, and the thickness t _{2 of the} central part of the flange or socket 28 forming the central hole is equal to the thickness t _{1 of the} ring stop 30. The socket 28 has a rounded surface 35 located on the side of the air cavity 8 of the support 4. The end face 36 of the ring stop 30 (Fig. 4) and the end face 37 of the socket 28 are located in the plane 38 with the possibility of tight contact with the outer surface 3 of the base 1, and the lower surface 32 of the flange 9 is located in another plane 39, which is located above the plane 38. The distance S (Fig. 3) between the planes 38 and 39 selected from the condition of free passage of the shell 5 of the support 4 in the gap 34 between the lower surface 32 of the flange 9 and the outer surface 3 of the base 1 (Fig. 3, 4 and 5).

 It should be noted that in another embodiment of the installation, the annular groove 29 can be formed by the inner surface of the flange 9 and the annular stop 30, which can be made of a number of separate protrusions located circumferentially around the axis of the flange.

 The shell 5 of the support 4 is connected to the base 1 by means of coupling fasteners 40 connecting the base 1 and the lower flange 9, and also by means of an elastic lower ring 41 (Figs. 4 and 5) located in the annular groove 29 of the lower flange 9. The ring 41 is made, for example, made of rubber, it is connected to the sheath 5 of the support 4 and is intended for fastening the sheath 5 in the annular groove 29 of the lower flange 9, to compensate and redistribute the dynamic loads on the fasteners in cases of a sharp change in air pressure in the air cavity 8 of the support 4, and also for self-sealing of the shell 5 in the lower flange 9. The diameter of the ring 41 in the cross section is selected from the condition of the ring deformation from the action of the coupling fasteners 40 when the shell is fixed on the base 1. In the compressed state, the ring 41 in the cross section takes the form of an oval 42 (Fig. 2, 3 and 10), the thickness of which is h = t + 2n, where t is the thickness of the end face 33 of the flange 9, and n is the thickness of the material from which the sheath 5 of the support 4 is made. In another embodiment of the installation, in the compressed state of the ring 42 (Fig. 10) when the end face 36 of the annular stop 30 is in tight contact with the outer surface 3 of the base 1 between the latter and the surface 43 of the shell 5, located under the lower surface 32 of the lower flange 9, a gap 44 is formed, providing a free location in it of one layer of the shell 5.

 The shell 5 (Fig. 3, 4, 6 and 7) is fixed on the lower elastic ring 41 by means of a loop 45 with the end of the loop 46 coming out of the annular groove 29 of the lower flange 9 and securing the loop end 46 with a seam 47 on the shell 5. The seam can be made by any in a known manner.

 In another embodiment (Figs. 5, 8, 9, and 10), the sheath 5 is fixed to the ring 41 by the compression force of the coil or spiral 48 of the sheath 5 located around the ring 41. In this case, the coil or spiral 48 of the sheath 5 interacts with the outer surface 3 of the base 1 and two surfaces 49 and 50 of the annular groove 29. The end face 51 of the shell is in the annular groove 29 of the lower flange 9.

 The lantern 7 (Fig. 2) is mounted on the upper end part 6 of the support 4 using the upper flange 10, which is connected by coupling fasteners 52 to the mounting flange 53, on which the lantern 7 is fixed.

 Between the upper and mounting flanges 10 and 53 is located the upper elastic ring 54. The upper and lower flanges and elastic rings have a unified identical design. The mounting flange 53 is a base to which the lantern 7 is attached by means of the flange 55 of the lantern 7.

 The clamping fasteners 40 and 52 are located in the corresponding holes of the base 1, the lower and upper flanges 9 and 10 and the mounting flange 53. The shell 5 of the upper part of the support 4 is fastened to the upper flange 10 and the ring 54 in the same way as the shell 5 attached to the base at the bottom supports 4. In the flange 55 of the lamp 7, ventilation holes 56 are made. The lamp 7 is mounted on the flange 55 by means of a cartridge. The flange 55 of the lantern 7 is mounted on the upper flange 10 by means of fasteners 57.

 The installation also includes stretch marks 58, 59 and 60 (Fig. 1 and 13) associated with the clamps 18 of the stabilizer 21, while the upper ends of the stretch marks are made with quick-release grippers 61, 62 and 63, which allow you to set the stretch marks at different levels of support 4 by securing them to latches located at other levels.

 In the cavity 8 (Fig. 2) of the support 4, a diaphragm 64 is located, the ends of which are fixedly mounted on the inner surface of the shell 5 of the support 4. A pneumatic inlet valve 65 with an inlet 66 for air flow coming from the supercharger 11 is fixed to the diaphragm, and a pneumatic outlet valve 67 with a bore 68 for air downward flow. Conventionally, the support cavity 8 is divided by the diaphragm 64 into the lower section located below the diaphragm 64 and the upper section located above the diaphragm.

The inlet valve 65 is designed for air pressure P _mouth , ensuring the hardness of the shell 5 and the stability of the lower section of the support when air is injected into it. If the air pressure in the lower section is greater than P _{mouth, the} inlet valve 65 opens.

The outlet valve 67 is designed to drop the air pressure in the lower section and opens when _a condition P> P _n, wherein R _n - air pressure in the lower section, and P _in - air pressure in the upper section. If the air pressure in the lower section is greater than the air pressure in the upper section, then the orifice 68 of the outlet valve 67 is closed and air from the lower section to the upper section flows through the orifice 66 of the valve 65.

 An air blower 11 is installed in the housing 69, which is fixed to the base 1 by means of shock absorbers 70 and fasteners 71. In the housing 69 and the base 1 corresponding to their intake windows 72 and 73 are made.

 The emergency lighting system operates as follows.

Power is supplied to the air supercharger 11 (Fig. 2) in the sheath 5 of the support 4. Through the air intake window 73 in the base 1 and the air intake window 72 of the housing 69 of the supercharger 11, air is sucked in by the supercharger from the atmosphere and, then, through the hole 12 in the base 1 and the bell 28 the flange 9 is supplied under pressure into the shell 5 (which in the initial position is in the folded state). With increasing pressure inside the shell 5, in particular in the lower section of the cavity 8, the latter is straightened, and when a certain pressure level P _{mouth of} air is reached in the lower section of the cavity, the shell 5 of the lower section of the support 4 is straightened, becomes stable and solid, occupies a vertical position. With increasing pressure in the lower section, exceeding P _mouth , the inlet valve 65 opens and air enters the upper section of the cavity 8 of the support 4. Since the tensile strength of the lower stabilizer 19 is less than the tensile strength of the stabilizer 20 located above the stabilizer 19, and the tensile strength of the stabilizer 21 is greater than the resistance tension of the stabilizer 20, then with a rapid increase in pressure in the upper section of the air cavity 8 of the support 4, the volume of air due to the upper stabilizer 21 in the upper part of the support 4 will have I less than the volume of air in the middle and lower parts of the support 4. This redistributes the air pressure in the air cavity 8 in the specified mode with the exhaust valve 67 closed. As a result, the hardness of the shell 5 of the upper part of the support 4 will be less when inflating it, and the carrier vertical load the ability of the upper part of the support will be lower than the bearing capacity of the lower part of the support 4.

 The process of pumping air into the cavity 8 of the support with a height of about 5 meters lasts several seconds and during this time the shell 5 acquires the hardness necessary for the perception of static and dynamic loads. Due to the action of stabilizers 19, 20 and 21, first the lower part of the support 4 begins to rise from the base 1 up, then the middle part of the support 4 rises up, after which the upper part of the support 4 rises, the shell 5 occupies a vertical position and is converted into a support 4 having the necessary hardness for stability and holding the lamp in the raised upper position. Next, turn on the flashlight 7 by connecting it to the power source 13 by means of an electric wire 14, which, when air is pumped into the cavity 8 of the support, rises up together with the upper part 6 of the latter.

 After performing the above steps, the air supply into the cavity 8 of the support 4 does not stop and the air flowing around the lantern (Fig. 2), through the socket of the upper flange 10 and the ventilation holes 56 of the flange 55 of the lantern 7 goes into the atmosphere, while cooling the surface of the lantern 7 located in on state.

 Further, if necessary, to ensure the stability of the support 4 (Fig. 1 and 13), the lower ends of the stretch marks 58, 59 and 60 are fixed to the ground. Since the stretch marks are connected at their upper ends to the clamps 18 of the stabilizer 21, when dynamic loads occur on the support 4, they are damped by the elasticity of the support.

 When the installation is turned off, the air blower 11 is turned off, while the pressure in the air cavity 8 decreases in the reverse order - the upper stabilizer 21 exerts more pressure on the shell 5 in the upper part of the support 4, valve 67 opens after the air pressure drops in the lower section of the cavity 8 (under aperture 64) and first the upper part of the support falls, then the middle and lower parts, which excludes a sharp fall of the support, its impact on the ground, including the lamp, and prevents their damage. In this case, the upper part of the support falls to the ground in slow motion, which makes it possible to support it and eliminates contamination of the surface of the shell 5 of the support from its contact with the ground.

 During operation of the installation during rapid injection of air into the cavity 8 of the support 4 at the ends of the shell 5 associated with the flanges of its fastening, significant dynamic loads arise at the joints of the shell, which are absorbed by the lower and upper elastic rings 41 and 54. The damping of dynamic loads occurs during exhaust shell 5 of the annular grooves of the lower and upper flanges, while the tension of the shell 5, the elasticity of the rings 41 and 54, as well as the elasticity of the pressure stabilizers 19, 20 and 21 provide damping of sharp loads.

 When the material of the sheath 5 is tensioned in a vertical direction along the axis 31 of the support 4 or when the support 4 is bent and the material of the sheath is pulled in the other direction, the elasticity of the rings 41 and 54 and the elasticity of the stabilizers 19, 20, and 21 eliminate tearing of the longitudinal fibers of the material. In this case, the rings 41 and 54 work as elastic shock absorbers - dampers and compensators for sharp dynamic loads.

 The technical solution described above, due to its design features, significantly increases the reliability of the emergency lighting installation, its service life, provides quick installation in emergency conditions and ease of transportation due to increased compactness due to the improved layout.

Sources of information
1. US patent 6012826, F 21 P 1/04, 2000

 2. US patent 5683167, F 21 V 33/00, 1997

 3. Japan patent 9217567, E 04 H 12/34, 1991

 4. Copyright certificate of the USSR 1767285, F 21 V 21/00, 1990

 5. Copyright certificate of the USSR 1756734, F 21 L 9/00, 1990

 6. US patent 5628558, F 21 V 19/02, 1997

 7. Prospectus of the Lighting Technologies Company. Emergency lighting installation "Light Tower", "Lighting Technologies", 2000 (prototype).

Claims (7)

 1. An 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, in which there is a lamp with a flange of its fastening to the upper end of the support, located in the upper and lower parts of the support means joints of the support shell with the base and the lamp, extensions associated with the top of the support and the ground, air pressure stabilizers in the shell, attached to the outer surface of the support shell in height the latter at different levels, each stabilizer is made of elastic elastic material, the tensile strength of each lower stabilizer is chosen less than the tensile strength of each upper stabilizer located above the lower stabilizer, the means for connecting the support shell to the base is made in the form of an elastic ring and a lower flange with an annular groove, which is an elastic ring connected along the perimeter with the end of the shell of the support, and the elastic ring is located between the fastened flange and the base with the possibility of forming a gap between them, in which the support shell is freely located, the lower stabilizer being located in the middle part of the support, and below the lower stabilizer, a diaphragm is fixed in the inner cavity of the support, separating the inner cavity into the lower and upper sections, and the diaphragm is made with an input and the outlet valves and the inlet of the inlet valve is smaller than the inlet of the outlet valve.  2. Emergency lighting installation according to claim 1, characterized in that the lower flange is made with an annular stop, an inner flange forming a central hole-bell for air passage, the end of the inner flange and the end of the ring stop of the lower flange are located in the same plane with the possibility of tight contact with an adjacent surface of the base, and the lower surface of the outer end of the flange is located above the plane.  3. Emergency lighting installation according to claim 1, characterized in that each end of the support shell is connected to the elastic ring by means of a loop made at the end of the shell, enclosing the ring around the perimeter of its cross section.  4. Emergency lighting installation according to claim 1, characterized in that each end of the support shell is connected to the elastic ring by means of a spiral formed by the end part of the shell located in the annular groove of the lower flange with the possibility of pinching the shell spiral in the annular groove during compression of the elastic ring.  5. Emergency lighting installation according to claim 1, characterized in that each stabilizer is fixed to the outer surface of the support shell by means of clamps located around the support perimeter and fixedly connected with the said surface.  6. Emergency lighting installation according to claim 1 or 5, characterized in that each extension is connected with a stabilizer latch.  7. Emergency lighting installation according to claim 1, characterized in that in the flange of the lantern to the upper end part of the support are made ventilation holes, each axis of which is located between the support shell and the plane that forms the surface of the lamp.

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