CN214461206U - Solar energy power supply inflatable mobile hangar - Google Patents

Abstract

A solar power supply inflatable mobile hangar comprises a solar power supply system, an air rib type hangar, an inflation device, an air rib pressure control system, a skin, an anchoring device and an upturning air rib gate; the skin is arranged on the surface of the air-ribbed hangar, so that a closed space is formed inside the air-ribbed hangar, the upper surface of the skin is connected with an oil fixed connecting piece through a magic tape, and the fixed connecting piece is connected with a track through a bolt; the solar power supply system comprises a photovoltaic thin-film battery panel, a charge controller, an inverter and a storage battery, wherein the photovoltaic thin-film battery panel is arranged on the outer surface of the skin and is in sliding connection with a track on the skin; the mobile hangar is simple and convenient to carry, and does not cause environmental pollution; on the other hand, the photovoltaic thin-film cell panel can be moved in the using process to receive the maximum radiation intensity, so that the generating capacity of the photovoltaic thin-film cell panel is improved, the using area of the photovoltaic thin-film cell panel is reduced, and the cost is saved.

Description

Solar energy power supply inflatable mobile hangar

Technical Field

The utility model belongs to the technical field of inflatable hangar, concretely relates to solar energy power supply inflatable removes hangar.

Background

With the development of science and technology, various weaponry of modern army are more and more, and when the field is battle or trained, various equipment often need to be regularly overhauled or maintained. In recent years, with the development of membrane structure technology, various inflatable hangars are emerging continuously, and although the defect that the traditional fixed hangars are not movable is overcome, the traditional fixed hangars usually need to carry bulky power generation facilities as power supply, consume traditional energy and generate a large amount of tail gas, thereby causing environmental pollution.

Therefore, a power supply system which is convenient to carry and does not cause environmental pollution is needed to provide a brand new solution for the power supply of each electric facility in the inflatable type machine room.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the utility model provides a solar energy power supply inflatable removes hangar. The movable photovoltaic film cell panel is additionally arranged on the outer surfaces of the air rib type hangar and the skin, so that on one hand, power supply support can be provided for electric facilities such as an air charging device, an air rib pressure control system, a winch and the like in the hangar, the portable solar cell panel is simple and convenient to carry compared with the traditional power generation facilities, and environmental pollution can not be caused; on the other hand, the photovoltaic thin-film cell panel can be moved in the using process to receive the maximum radiation intensity, so that the generating capacity of the photovoltaic thin-film cell panel is improved, the using area of the photovoltaic thin-film cell panel is reduced, and the cost is saved; in addition, the hangar also has the characteristics of variable volume, reusability and quick disassembly and assembly.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the utility model provides a solar energy power supply inflatable removes hangar comprises solar energy power supply system, air rib formula hangar, aerating device, air rib pressure control system, covering, anchor and the formula air rib gate of turning over on, the covering set up in air rib formula hangar surface makes the inside airtight space that forms of air rib formula hangar, the covering upper surface pastes through the magic and connects oily fixed connection spare, fixed connection spare has the track through bolted connection.

Furthermore, the solar power supply system comprises a photovoltaic thin-film cell panel, a charging controller, an inverter and a storage battery, and provides power supply support for all electrical appliances in the inflatable hangar; the photovoltaic thin-film solar panels are arranged on the outer surface of the skin, are in sliding connection with the tracks on the skin, and are uniformly distributed on the skin.

The inverter can convert direct current generated by the photovoltaic thin film cell panel into alternating current.

The storage battery can store redundant electric energy generated by the photovoltaic thin-film cell panel.

The charge controller is a type of automatic charge and discharge control device installed in the solar power supply system in order to protect the secondary battery from overcharge.

According to the inflatable mobile hangar, the photovoltaic thin-film cell panel is composed of a plurality of photovoltaic modules; the photovoltaic modules are connected through wires; and a protective outer frame is sleeved outside the photovoltaic thin-film cell panel.

According to the inflatable mobile hangar, the track control device comprises a photovoltaic thin film battery panel driving device, a braking device and a controller; the photovoltaic thin-film cell panel driving device comprises a driving motor, a roller and a conveying belt; the protective outer frame is connected with the conveyor belt in an embedded manner; the braking device can keep the roller still; the controller can control the photovoltaic thin film battery panel driving device and the braking device.

According to the inflatable mobile hangar, the air rib type hangar is formed by sequentially arranging a plurality of groups of arched inflatable air ribs, and the arched inflatable air ribs are communicated with each other through an inflatable pipeline.

Furthermore, fiber pulling points are respectively arranged on two sides of the arched inflatable air rib.

Further, the anchoring device comprises a counterweight sandbag, a fiber pulling point and a rope; the counterweight sandbag can be detachably fixed on the fiber pulling points on two sides of the arched inflatable air rib through the rope.

According to the inflatable mobile hangar, the inflating device can quickly fill gas into the sealed space of the air rib type hangar, so that the arch-shaped inflatable air ribs can be quickly molded.

The inflatable mobile hangar is characterized in that the air rib pressure control system is used for controlling the switch of the inflating device.

Preferably, when the pressure in the air rib is higher than a certain value, the air rib pressure control system automatically opens the safety valve for air discharge, and when the pressure in the air rib is lower than a certain value, the air rib pressure control system automatically opens the safety valve for air supply so as to keep the air pressure in the arched inflatable air rib constant.

According to the inflatable mobile hangar, the upturning type air rib gate is composed of an arched inflatable air rib, a lifting mechanism, a winch and a skin; and starting the winch to enable the hoisting mechanism to work to drive the arched inflatable air rib to turn upwards to complete the opening of the upturning type air rib gate.

The utility model discloses the beneficial effect who reaches does: the solar power supply system is used for providing power supply support for each electric facility in the hangar without carrying other external power supplies; no toxic substance is generated in the using process, and no environmental pollution is caused; the sliding connection of the photovoltaic thin-film cell panel reduces the use area of the photovoltaic thin-film cell panel, and greatly saves the cost; the air rib type hangar is composed of a plurality of arch-shaped air-inflated ribs, and a corresponding number of arch-shaped air-inflated ribs can be installed according to the actual needs of the site in the assembling process so as to adjust the actual size of the internal space of the hangar, so that the hangar also has the characteristic of variable volume; when needing to remove, this hangar can deflate fast, split, folding, packing, consequently has reuse and the quick characteristics of dismouting.

Drawings

FIG. 1 is the overall structure diagram of the solar powered inflatable mobile hangar of the present invention

FIG. 2 is a side view of the solar powered inflatable mobile hangar of the present invention

FIG. 3 is the schematic view of the fixing connector provided by the present invention

FIG. 4 is a schematic view of the connection between the photovoltaic thin-film cell panel (local) and the track

FIG. 5 is a schematic circuit diagram of a solar power supply system of the present invention

FIG. 6 is a schematic view of a rear door of a solar powered inflatable mobile hangar

The reference numbers are as follows:

the system comprises a photovoltaic thin-film battery panel 1, an air rib type hangar 2, a skin 3, an upturning air rib gate 4, an anchoring system 5, an air charging device 6, a rail 7, a bolt connecting hole 8, a rail placing groove 9, a protective outer frame 10, a rail 11, a roller 12 and a conveyor belt 13.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the following describes in detail a specific implementation of the solar powered inflatable mobile hangar with reference to the attached drawings.

As shown in fig. 1 and 2, the solar power supply inflatable mobile hangar is composed of a solar power supply system 1, an air rib type hangar 2, an inflating device 6, an air rib pressure control system (not shown), a skin 3, an anchoring device 5 and an upturning air rib gate 4; the solar power supply system comprises a photovoltaic thin film cell panel, a charge controller, a storage battery and an inverter; wherein the photovoltaic thin-film solar panels are arranged on the outer surface of the skin 3, are in sliding connection with the rails 7 on the skin 3, and are uniformly distributed on the skin 3; the rail 7 is connected with a fixed connecting piece on the skin 3 through a bolt; the fixed connecting piece is connected with the skin 3 through a magic tape.

As shown in fig. 3, the fixed connection member includes a bolt connection hole 8 and a rail seating groove 9, and the rail 7 is tightly connected with the fixed connection member by a bolt in the bolt connection hole 8; the fixed connecting pieces are uniformly distributed along the track direction.

The photovoltaic thin film cell panel is composed of a plurality of photovoltaic modules; the photovoltaic modules are connected through wires; the photovoltaic thin film cell panel is sleeved with a protective outer frame 10.

In an alternative embodiment, the photovoltaic module is a copper indium diselenide (CIS) cell film.

Fig. 4 is a schematic view showing the connection between (a part of) the photovoltaic thin-film cell panel and the track, and it should be noted that the track and the photovoltaic thin-film cell panel both have a certain radian, but the figure only shows the connection between the track and the photovoltaic thin-film cell panel, and the track and the photovoltaic thin-film cell panel work under the action of a track control device, wherein the track control device comprises a photovoltaic thin-film cell panel driving device, a braking device and a controller; the photovoltaic thin film battery panel driving device comprises a driving motor, a roller 12 and a conveying belt 13; the protective outer frame 10 is connected with the conveyor belt 13 in an embedded manner; the braking device can keep the roller still; the controller may control the photovoltaic thin film panel driving device and the braking device.

In this embodiment, the position of the photovoltaic thin-film panel is adjusted by the track control device so that the photovoltaic thin-film panel always receives the maximum solar radiation intensity.

In an alternative embodiment, the power for moving the photovoltaic thin-film cell panel may also be manually pulled, or may be driven by a power device such as a hydraulic cylinder, an air cylinder, or the like, that is, it only needs to drive the photovoltaic thin-film cell panel to slide on the rail.

Fig. 5 is a schematic circuit diagram of a solar power system, wherein the inverter is a device for converting direct current generated by the photovoltaic thin film panel into alternating current; the storage battery is a device for storing redundant electric energy generated by the photovoltaic thin-film cell panel; the charge controller is a type of automatic charge and discharge control device installed in the solar power supply system in order to protect the storage battery from overcharge; the charging controller is connected between the photovoltaic thin-film cell panel and the storage battery, the electric energy stored in the storage battery is converted into alternating current through the inverter, and the alternating current can be used by alternating current loads, and some direct current loads can be directly connected with the charging controller to obtain power supply support; the solar power supply system can meet the power utilization requirements of all loads, the sunshine is bright in the daytime, the output power of the photovoltaic thin-film cell panel is larger than the rated power of the power utilization equipment, the surplus electric quantity can be stored in the storage battery, the output power of the flexible solar thin-film cell is smaller than the rated power of the power utilization equipment at night, and the electric quantity stored in the storage battery can be used for supplying power to the power utilization equipment.

The air rib type hangar 2 is formed by sequentially arranging a plurality of groups of arched inflatable air ribs; the arch-shaped air inflation rib can be made of high-strength and good-air-tightness membrane materials through high-frequency welding, and the internal working pressure of the arch-shaped air inflation rib can be 5 KPa-20 KPa; the arched inflatable ribs are communicated with each other through an inflatable pipeline; therefore, when the air inflation device is inflated, only one of the air inflation columns is provided with the air inflation hole, and correspondingly, the air inflation operation of a group of integral arched air inflation columns can be completed only by too much air inflation machine, so that the energy is greatly saved.

The air charging device 6 can rapidly charge air into the sealed space, so that the arched air charging rib can be rapidly molded.

The air rib pressure control system (not shown in the figure) is used for controlling the switch of the air charging device, a safety valve for automatically opening and discharging air when the internal pressure of the air rib is higher than a certain value, and a safety valve for automatically opening and supplying air when the internal pressure of the air rib is lower than a certain value, so as to keep the air pressure in the arched air charging air rib constant.

The skin 3 is arranged on the surface of the air rib type hangar, so that a closed space is formed inside the air rib type hangar; the PU coating oxford fabric is sewn, and a sealing strip is welded at a sewing joint, so that the integral sealing performance of the skin is ensured, and the rain and snow prevention function can be realized; which is connected with the arched inflatable air rib through a nylon hasp.

The anchoring device comprises a counterweight sandbag, a fiber pulling point and a rope; the counterweight sandbag can be detachably fixed on the fiber pulling points on two sides of the arched inflatable air rib through the rope.

The upturning type air rib gate 4 consists of an arched inflatable air rib, a lifting mechanism, a winch and a skin; the upturning type air rib gate 4 is of a circular arch folding and dropping type, and the winch is started to enable the hoisting mechanism to work to drive the arch-shaped air rib to upturn to complete opening of the upturning type air rib gate.

Fig. 6 is a schematic view of a rear door of the solar power supply inflatable mobile hangar, wherein the rear door is composed of a plurality of vertical air ribs, and a space is reserved below two air ribs for people and vehicles to enter and exit, so that the upturning type air rib door 4 which is complicated to open and close is avoided, and the use process is optimized.

The solar power supply system 1 provides power supply support for all electrical appliances in the inflatable garage.

The solar power supply inflatable mobile hangar provided by the embodiment of the utility model utilizes the solar power supply system to provide power supply support for each electric facility in the hangar, and other external power supplies are not required to be carried; no toxic substance is generated in the using process, and no environmental pollution is caused; the sliding connection of the photovoltaic thin-film cell panel reduces the use area of the photovoltaic thin-film cell panel, and greatly saves the cost; the air rib type hangar is composed of a plurality of arch-shaped air-inflated ribs, and a corresponding number of arch-shaped air-inflated ribs can be installed according to the actual needs of the site in the assembling process so as to adjust the actual size of the internal space of the hangar, so that the hangar also has the characteristic of variable volume; when needing to remove, this hangar can deflate fast, split, folding, packing, consequently has reuse and the quick characteristics of dismouting.

The utility model is not the best known technology.

The above embodiments are only for illustrating the technical concept and features of the present invention, and the purpose of the embodiments is to enable people skilled in the art to understand the contents of the present invention and to implement the present invention, which cannot limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered by the protection scope of the present invention.

Claims (10)

1. The utility model provides a solar energy power supply inflatable removes hangar which characterized in that: the solar air rib type air rib door system comprises a solar power supply system, an air rib type machine library, an air charging device, an air rib pressure control system, a skin, an anchoring device and an upturning air rib door;

the skin is arranged on the surface of the air-ribbed hangar, so that a closed space is formed inside the air-ribbed hangar, the upper surface of the skin is connected with an oil fixed connecting piece through a magic tape, and the fixed connecting piece is connected with a track through a bolt;

the solar power supply system comprises a photovoltaic thin-film cell panel, a charge controller, an inverter and a storage battery and provides power supply support for all electrical appliances in the inflatable mobile garage;

wherein the photovoltaic thin-film solar panel is arranged on the outer surface of the skin and is in sliding connection with the rail on the skin;

the inverter can convert direct current generated by the photovoltaic thin film cell panel into alternating current;

the storage battery can store redundant electric energy generated by the photovoltaic thin-film cell panel;

the charge controller is a type of automatic charge and discharge control device installed in the solar power supply system in order to protect the secondary battery from overcharge.

2. The solar-powered inflatable mobile hangar of claim 1, wherein said photovoltaic thin film panel is formed from a plurality of photovoltaic modules; the photovoltaic modules are connected through wires; and a protective outer frame is sleeved outside the photovoltaic thin-film cell panel.

3. The solar-powered inflatable mobile hangar of claim 2, further comprising track control means, said track control means comprising photovoltaic thin film panel drive means, brake means and controls; the photovoltaic thin-film cell panel driving device comprises a driving motor, a roller and a conveying belt; the protective outer frame is connected with the conveyor belt in an embedded manner; the braking device can keep the roller still; the controller can control the photovoltaic thin film battery panel driving device and the braking device.

4. The solar powered inflatable mobile hangar of claim 1, wherein said air-ribbed hangar is formed by a plurality of sets of arched inflatable air ribs arranged in sequence, said arched inflatable air ribs being interconnected by inflatable ducts.

5. The solar-powered inflatable mobile hangar as claimed in claim 4, wherein the arched inflatable ribs are provided with fiber pulling points on both sides thereof.

6. The solar-powered inflatable mobile hangar of claim 5, wherein said anchoring means comprises weighted sandbags, tow points, ropes; the counterweight sandbag can be detachably fixed on the fiber pulling points on two sides of the arched inflatable air rib through the rope.

7. The solar powered inflatable mobile hangar according to any of claims 4 to 6, wherein said inflation means is capable of rapidly filling said rib-type hangar enclosed space with gas to rapidly form said arcuate inflatable ribs.

8. The solar-powered inflatable mobile hangar of claim 7, wherein said air rib pressure control system is adapted to control the opening and closing of said inflation means.

9. The solar powered inflatable mobile hangar of claim 8, wherein said air rib pressure control system automatically opens said air release safety valve when the air rib internal pressure is above a certain level and said air rib pressure control system automatically opens said air supplement safety valve when the air rib internal pressure is below a certain level to maintain the air pressure in said arched inflatable air ribs constant.

10. The solar-powered inflatable mobile hangar of claim 1, wherein the upturned air rib gate is comprised of an arched inflatable air rib, a lifting mechanism, a winch, and a skin; and starting the winch to enable the hoisting mechanism to work to drive the arched inflatable air rib to turn upwards to complete the opening of the upturning type air rib gate.

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