CN113364403A

CN113364403A - A field operations photovoltaic unit for multisource power supply integration energy support system

Info

Publication number: CN113364403A
Application number: CN202110651946.4A
Authority: CN
Inventors: 傅志栋; 林永清
Original assignee: Jiangsu Hewangyuan Electric Co ltd
Current assignee: Jiangsu Hewangyuan Electric Co ltd
Priority date: 2021-06-11
Filing date: 2021-06-11
Publication date: 2021-09-07

Abstract

The invention discloses a field operation photovoltaic unit for a multi-source power supply integrated energy support system, which comprises a plate trailer, a plurality of photovoltaic plates, a slide rail trailer, a bottom plate and a bottom plate lifting driving mechanism, wherein one side of the bottom plate is hinged on one side edge of the plate trailer, the lower side of the bottom plate is connected with the bottom plate lifting driving mechanism fixed on the plate trailer, the photovoltaic plates are hinged with each other in pairs to form a foldable photovoltaic plate assembly, one side of the photovoltaic plate assembly is hinged at one end part of the plate trailer, the other side of the photovoltaic plate assembly is hinged on the slide rail trailer, the slide rail is fixed on the upper side of the bottom plate, and the slide rail trailer is arranged on the slide rail. The invention can rapidly complete the deployment of the field photovoltaic unit, the whole process is less than 1 minute, and the plate trailer can be directly towed by a truck, so that the deployment and the transfer are convenient.

Description

A field operations photovoltaic unit for multisource power supply integration energy support system

Technical Field

The invention relates to a field operation photovoltaic unit, in particular to a field operation photovoltaic unit for a multi-source power supply integrated energy support system, and belongs to the field of energy support systems.

Background

The multi-source power supply integrated energy support system is mainly used for guaranteeing energy supply under the camping condition, mainly comprises two sets of 15kW photovoltaic units, one set of 120kWh energy storage unit, one set of 75kW diesel generator power station unit and a wind power generation unit, and can realize power supply of multiple ways under the field condition, so that the electric energy supply under the camping condition of army is guaranteed.

At present, photovoltaic units are mainly fixed photovoltaic units and are inconvenient to carry and transport, although some foldable photovoltaic panel unit structures are arranged in the prior art, the folding problems of two unit panels can be basically realized by the structures, however, two sets of 15kW photovoltaic units need to be constructed in the field by the multi-source power supply integrated energy support system, the number of the required photovoltaic panels is large, the transportation is troublesome, the assembly workload after arriving is large, and the requirements of rapid deployment and rapid transfer of actual combat are difficult to adapt.

Disclosure of Invention

The technical problem to be solved by the invention is to provide a field operation photovoltaic unit for a multi-source power supply integrated energy support system, and realize rapid deployment and transfer of the photovoltaic unit.

In order to solve the technical problems, the technical scheme adopted by the invention is as follows:

the utility model provides a field operations photovoltaic unit for multisource power supply integration energy support system which characterized in that: contain the wooden handcart, polylith photovoltaic board, a slide rail, the slide rail car, bottom plate and bottom plate lift actuating mechanism, bottom plate one side articulates on one side of wooden handcart, the bottom plate downside is connected with the bottom plate lift actuating mechanism who fixes on the wooden handcart, polylith photovoltaic board hinges each other between two liang and constitutes folding photovoltaic board subassembly, one side of photovoltaic board subassembly articulates at wooden handcart one end tip, the opposite side of photovoltaic board subassembly articulates on the slide rail car, the slide rail is fixed at the bottom plate upside, the slide rail car sets up on the slide rail.

Further, the lower side of the plate trailer is provided with wheels, a traction support is arranged at the end part of one end of the plate trailer, and guardrails are arranged on two sides of the plate trailer.

Further, the sum of the widths of the plurality of photovoltaic panels matches the length of the cart, and the number of photovoltaic panels is an even number.

Furthermore, the photovoltaic panel assembly comprises six photovoltaic panels, and the photovoltaic panel assembly comprises a first photovoltaic panel, a second photovoltaic panel, a third photovoltaic panel, a fourth photovoltaic panel, a fifth photovoltaic panel and a sixth photovoltaic panel, wherein one side of the first photovoltaic panel is hinged to one end of the flat car, the other side of the first photovoltaic panel is hinged to one side of the second photovoltaic panel through a first hinge, the other side of the second photovoltaic panel is hinged to one side of the third photovoltaic panel through a second hinge, the other side of the third photovoltaic panel is hinged to one side of the fourth photovoltaic panel through a third hinge, the other side of the fourth photovoltaic panel is hinged to one side of the fifth photovoltaic panel through a fourth hinge, the other side of the fifth photovoltaic panel is hinged to one side of the sixth photovoltaic panel through a fifth hinge, and one side of the sixth photovoltaic panel is hinged to one end of the slide car through a sixth hinge.

Further, the first hinge is located on the lower sides of the first photovoltaic panel and the second photovoltaic panel, the second hinge is located on the upper sides of the second photovoltaic panel and the third photovoltaic panel, the third hinge is located on the lower sides of the third photovoltaic panel and the fourth photovoltaic panel, the fourth hinge is located on the upper sides of the fourth photovoltaic panel and the fifth photovoltaic panel, the fifth hinge is located on the lower sides of the fifth photovoltaic panel and the sixth photovoltaic panel, and the sixth hinge is located on the upper side of the sixth photovoltaic panel.

Further, one end of the plate trailer is provided with a vertical baffle, and the vertical baffle is arranged in the vertical direction and fixed at one end of the plate trailer.

Further, lift actuating mechanism contains electric putter, and it has the recess that matches with electric putter to open on the last side of wooden handcart, and electric putter sets up in the recess and electric putter's one end is articulated with wooden handcart opposite side border, and electric putter's the other end articulates the middle part at the downside of bottom plate.

Furthermore, the number of the slide rails is two, the two slide rails are arranged on two sides of the upper side surface of the bottom plate in parallel along the length direction of the bottom plate, and each slide rail is provided with a slide rail vehicle.

Furthermore, the slide rail vehicle comprises a vehicle body, slide rail wheels on two sides, a rotating shaft, a first helical gear, a second helical gear and a driving mechanism, wherein the slide rail wheels on two sides are respectively fixed at two ends of the rotating shaft, the rotating shaft is rotatably arranged on the vehicle body, the first helical gear is fixed on the rotating shaft, the second helical gear is fixed on an output shaft of the driving mechanism and is meshed with the first helical gear, and the driving mechanism is composed of a driving motor and a reduction gearbox.

Furthermore, the slide rail wheels on the two sides respectively comprise a wheel body and a side wheel plate, wherein the diameter of the side wheel plate is larger than that of the wheel body, the side wheel plate is fixed on one side of the wheel body, the other side of the wheel body is fixed with one end of the rotating shaft, the wheel body is arranged on the upper end face of the slide rail, and the inner side face of the side wheel plate is arranged on the outer side face of the slide rail.

Compared with the prior art, the invention has the following advantages and effects: according to the invention, the photovoltaic panels are assembled into a required size, then the assembled photovoltaic panels are hinged at the head to form a foldable photovoltaic panel assembly, one side of the assembly is hinged on the flat car, the other side of the assembly is guided by the slide rail car to realize automatic folding and unfolding of the photovoltaic panel assembly, the whole bottom plate is lifted to a required angle after the assembly is unfolded, so that the deployment of field photovoltaic units is rapidly completed, the whole process is less than 1 minute, the flat car can be directly dragged by a truck, the deployment and transfer are convenient, after the photovoltaic panel assembly is stored and folded, the rest space of the flat car can be used for transporting other power supply units in the multi-source power supply integrated energy source guarantee system, and the rapid deployment and transfer of the whole system are realized.

Drawings

FIG. 1 is a schematic diagram of a field photovoltaic unit for a multi-source power integrated energy assurance system of the present invention.

FIG. 2 is a side view of a field photovoltaic unit for a multi-source power integrated energy assurance system of the present invention.

Fig. 3 is a schematic view of a plurality of photovoltaic panels of the present invention.

Fig. 4 is a schematic view of the railcar and the slide rail of the present invention.

Detailed Description

To elaborate on technical solutions adopted by the present invention to achieve predetermined technical objects, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, it is obvious that the described embodiments are only partial embodiments of the present invention, not all embodiments, and technical means or technical features in the embodiments of the present invention may be replaced without creative efforts, and the present invention will be described in detail below with reference to the drawings and in conjunction with the embodiments.

As shown in fig. 1 and 2, the field operation photovoltaic unit for the multi-source power supply integrated energy support system comprises a plate trailer 1, a plurality of photovoltaic plates 2, a slide rail 3, a slide rail trailer 4, a bottom plate 5 and a bottom plate lifting driving mechanism 6, wherein one side of the bottom plate 5 is hinged to one side edge of the plate trailer 1, the lower side of the bottom plate 5 is connected with the bottom plate lifting driving mechanism 6 fixed on the plate trailer 1, the photovoltaic plates 2 are hinged to each other in pairs to form a foldable photovoltaic plate assembly, one side of the photovoltaic plate assembly is hinged to one end of the plate trailer 1, the other side of the photovoltaic plate assembly is hinged to the slide rail trailer 4, the slide rail 3 is fixed on the upper side of the bottom plate 5, and the slide rail trailer 4 is arranged on the slide rail 3. When needing to transport, polylith photovoltaic board 2 is the folding one end at wooden handcart 1 of vertical direction, and the rest of wooden handcart 1 then leaves freely, can be arranged in transporting other power supply units in the multisource power supply integration energy support system, like diesel engine, wind-powered electricity generation unit etc.. When the field photovoltaic unit is transported to a designated position, after the rest power supply units are unloaded, the sliding rail vehicle 4 moves towards the other end of the plate trailer 1 along the sliding rail 3 to open the plurality of photovoltaic plates 2 folded together, when the sliding rail vehicle 4 moves to the end part of the other end of the plate trailer 1, the plurality of photovoltaic plates 2 are completely unfolded to form a large photovoltaic plate, the lower side of the large photovoltaic plate is supported on the upper side face of the sliding rail 3, and then the bottom plate lifting driving mechanism 6 drives the bottom plate 5 to rotate and lift along the hinged part with the side plate 1, so that the large photovoltaic plate is lifted to a required angle, and the field photovoltaic unit is rapidly deployed.

Wheels 5 are arranged on the lower side of the plate trailer 1, a traction support 6 is arranged at one end of the plate trailer 1, and guardrails 7 are arranged on two sides of the plate trailer 1. The sum of the width of polylith photovoltaic board 2 matches with the length of wooden handcart 1 to the quantity of photovoltaic board 2 is the even number, thereby guarantees that the both ends tip of the photovoltaic board subassembly after folding all is located the downside.

As shown in fig. 3, the photovoltaic panel assembly has six photovoltaic panels, the photovoltaic panel assembly includes a first photovoltaic panel 8, a second photovoltaic panel 9, and a third photovoltaic panel 10, the photovoltaic system comprises a fourth photovoltaic panel 11, a fifth photovoltaic panel 12 and a sixth photovoltaic panel 13, wherein one side of the first photovoltaic panel 8 is hinged to one end of the trolley 1, the other side of the first photovoltaic panel 8 is hinged to one side of the second photovoltaic panel 9 through a first hinge 14, the other side of the second photovoltaic panel 9 is hinged to one side of the third photovoltaic panel 10 through a second hinge 15, the other side of the third photovoltaic panel 10 is hinged to one side of the fourth photovoltaic panel 11 through a third hinge 16, the other side of the fourth photovoltaic panel 11 is hinged to one side of the fifth photovoltaic panel 12 through a fourth hinge 17, the other side of the fifth photovoltaic panel 12 is hinged to one side of the sixth photovoltaic panel 13 through a fifth hinge 18, and one side of the sixth photovoltaic panel 13 is hinged to one end of the slide rail trolley 4 through a sixth hinge 19. Through the articulated mode that the head links to each other like this, add six photovoltaic boards and constitute one and can be the folding photovoltaic board subassembly of Z type. The first hinge 14 is located on the lower side of the first photovoltaic panel 8 and the second photovoltaic panel 9, the second hinge 15 is located on the upper side of the second photovoltaic panel 9 and the third photovoltaic panel 10, the third hinge 16 is located on the lower side of the third photovoltaic panel 10 and the fourth photovoltaic panel 11, the fourth hinge 17 is located on the upper side of the fourth photovoltaic panel 11 and the fifth photovoltaic panel 12, the fifth hinge 18 is located on the lower side of the fifth photovoltaic panel 12 and the sixth photovoltaic panel 13, and the sixth hinge 19 is located on the upper side of the sixth photovoltaic panel 13. Because the photovoltaic panel has a certain thick bottom, the photovoltaic panel assembly can be ensured to form a large flat large photovoltaic panel without large gaps in a flattening state in a mode of hinging up and down in a staggered mode.

One end of the plate trailer 1 is provided with a vertical baffle 20, and the vertical baffle 20 is arranged along the vertical direction and fixed at one end of the plate trailer 1. When polylith photovoltaic board 2 was folding, the side of going up of first photovoltaic board 8 pastes on the medial surface of leaning on vertical baffle 20, and is spacing to the vertical angle of whole photovoltaic board subassembly. Rubber pads can be added on the inner wall of the vertical baffle 20 to protect the photovoltaic panel according to requirements.

Lifting drive mechanism 6 contains electric putter, and it has the recess that matches with electric putter to open on the last side of wooden handcart 1, and electric putter sets up in the recess and electric putter's one end is articulated with wooden handcart 1 opposite side border, and electric putter's the other end articulates the middle part at the downside of bottom plate 5.

As shown in fig. 4, two slide rails 3 are provided, the two slide rails 3 are arranged in parallel on two sides of the upper side surface of the bottom plate 5 along the length direction of the bottom plate 5, and each slide rail 3 is provided with one slide rail car 4. The slide rail car 4 comprises a car body 21, slide rail wheels 22 on two sides, a rotating shaft 23, a first bevel gear 24, a second bevel gear 25 and a driving mechanism, wherein the slide rail wheels 22 on two sides are respectively fixed at two ends of the rotating shaft 23, the rotating shaft 23 is rotatably arranged on the car body 21, the first bevel gear 24 is fixed on the rotating shaft 23, the second bevel gear 25 is fixed on an output shaft of the driving mechanism and is meshed with the first bevel gear 24, and the driving mechanism is composed of a driving motor 26 and a reduction gearbox 27. The slide rail wheels 22 on both sides respectively include a wheel body 28 and a side wheel plate 29, wherein the diameter of the side wheel plate 29 is greater than the diameter of the wheel body 28, the side wheel plate 29 is fixed on one side of the wheel body 28, the other side of the wheel body 28 is fixed with one end of the rotating shaft 23, the wheel body 28 is arranged on the upper end surface of the slide rail 3, and the inner side surface of the side wheel plate 29 is arranged on the outer side surface of the slide rail 3. The driving motor 26 drives the two side rail wheels 22 to rotate on the slide rail 3 to drive the slide rail car 4 to move through the transmission of the first bevel gear 24 and the second bevel gear 25 after being decelerated by the reduction gearbox 27.

According to the invention, the photovoltaic panels are assembled into a required size, then the assembled photovoltaic panels are hinged at the head to form a foldable photovoltaic panel assembly, one side of the assembly is hinged on the flat car, the other side of the assembly is guided by the slide rail car to realize automatic folding and unfolding of the photovoltaic panel assembly, the whole bottom plate is lifted to a required angle after the assembly is unfolded, so that the deployment of field photovoltaic units is rapidly completed, the whole process is less than 1 minute, the flat car can be directly dragged by a truck, the deployment and transfer are convenient, after the photovoltaic panel assembly is stored and folded, the rest space of the flat car can be used for transporting other power supply units in the multi-source power supply integrated energy source guarantee system, and the rapid deployment and transfer of the whole system are realized.

Although the present invention has been described with reference to a preferred embodiment, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims

1. The utility model provides a field operations photovoltaic unit for multisource power supply integration energy support system which characterized in that: contain the wooden handcart, polylith photovoltaic board, a slide rail, the slide rail car, bottom plate and bottom plate lift actuating mechanism, bottom plate one side articulates on one side of wooden handcart, the bottom plate downside is connected with the bottom plate lift actuating mechanism who fixes on the wooden handcart, polylith photovoltaic board hinges each other between two liang and constitutes folding photovoltaic board subassembly, one side of photovoltaic board subassembly articulates at wooden handcart one end tip, the opposite side of photovoltaic board subassembly articulates on the slide rail car, the slide rail is fixed at the bottom plate upside, the slide rail car sets up on the slide rail.

2. The field operations photovoltaic unit for a multi-source power supply integration energy support system of claim 1, characterized in that: the downside of wooden handcart is provided with the wheel to the one end tip of wooden handcart is provided with pulls the support, and the both sides of wooden handcart are provided with the guardrail.

3. The field operations photovoltaic unit for a multi-source power supply integration energy support system of claim 1, characterized in that: the sum of the widths of the photovoltaic panels matches the length of the pallet, and the number of photovoltaic panels is even.

4. The field operations photovoltaic unit for a multi-source power supply integrated energy supply system of claim 3, wherein: the photovoltaic panel of photovoltaic panel subassembly quantity is six, and photovoltaic panel subassembly contains first photovoltaic board, second photovoltaic board, third photovoltaic board, fourth photovoltaic board, fifth photovoltaic board and sixth photovoltaic board, one side of first photovoltaic board articulates the one end tip at the wooden handcart, the opposite side of first photovoltaic board is articulated through one side of first hinge and second photovoltaic board, the opposite side of second photovoltaic board is articulated through one side of second hinge and third photovoltaic board, the opposite side of third photovoltaic board is articulated through one side of third hinge and fourth photovoltaic board, the opposite side of fourth photovoltaic board is articulated through one side of fourth hinge and fifth photovoltaic board, the opposite side of fifth photovoltaic board is articulated through one side of fifth hinge and sixth photovoltaic board, one side of sixth photovoltaic board is articulated through one end of sixth hinge and slide rail car.

5. The field operations photovoltaic unit for the multi-source power supply integration energy support system of claim 4, characterized in that: the first hinge is located on the lower sides of the first photovoltaic panel and the second photovoltaic panel, the second hinge is located on the upper sides of the second photovoltaic panel and the third photovoltaic panel, the third hinge is located on the lower sides of the third photovoltaic panel and the fourth photovoltaic panel, the fourth hinge is located on the upper sides of the fourth photovoltaic panel and the fifth photovoltaic panel, the fifth hinge is located on the lower sides of the fifth photovoltaic panel and the sixth photovoltaic panel, and the sixth hinge is located on the upper side of the sixth photovoltaic panel.

6. The field operations photovoltaic unit for a multi-source power supply integration energy support system of claim 1, characterized in that: one end of the plate trailer is provided with a vertical baffle which is arranged along the vertical direction and fixed at one end of the plate trailer.

7. The field operations photovoltaic unit for a multi-source power supply integration energy support system of claim 1, characterized in that: the lifting driving mechanism comprises an electric push rod, a groove matched with the electric push rod is formed in the upper side face of the plate trailer, the electric push rod is arranged in the groove, one end of the electric push rod is hinged to the edge of the other side of the plate trailer, and the other end of the electric push rod is hinged to the middle of the lower side face of the bottom plate.

8. The field operations photovoltaic unit for a multi-source power supply integration energy support system of claim 1, characterized in that: the slide rail is two, and two slide rails set up the both sides of the upper flank of bottom plate along the length direction parallel arrangement of bottom plate, set up a slide rail car on every slide rail respectively.

9. The field operations photovoltaic unit for a multi-source power supply integrated energy supply system of claim 8, wherein: the sliding rail vehicle comprises a vehicle body, sliding rail wheels on two sides, a rotating shaft, a first helical gear, a second helical gear and a driving mechanism, wherein the sliding rail wheels on the two sides are respectively fixed at two ends of the rotating shaft, the rotating shaft is rotatably arranged on the vehicle body, the first helical gear is fixed on the rotating shaft, the second helical gear is fixed on an output shaft of the driving mechanism and is meshed with the first helical gear, and the driving mechanism is composed of a driving motor and a reduction gearbox.

10. The field operations photovoltaic unit for a multi-source power supply integrated energy supply system of claim 9, wherein: the sliding rail wheels on the two sides respectively comprise wheel bodies and side wheel plates, the diameter of each side wheel plate is larger than that of each wheel body, each side wheel plate is fixed to one side of each wheel body, the other side of each wheel body is fixed to one end of a rotating shaft, each wheel body is arranged on the upper end face of each sliding rail, and the inner side faces of the side wheel plates are arranged on the outer side faces of the sliding rails.