CN219406213U - Emergency charging station based on wind-solar complementary power generation - Google Patents

Abstract

The application relates to the field of charging equipment, especially, relate to an emergency charging station based on wind-solar complementary power generation, it includes the pile body, sets up wind-solar power generation component and rifle that charges on the pile body, its characterized in that: the pile body is provided with a fixed slot for inserting the charging gun, and the edge of the fixed slot is provided with a protection component for opening and closing the fixed slot; the protection component comprises a sliding piece and a protection plate; the sliding piece comprises a sliding block, two fixed long strips and a plurality of balls; the two fixed strips are arranged on the edges of the two sides of the fixed slot, and the fixed strips are provided with sliding grooves; the sliding blocks are connected to the sliding grooves of the fixed strips in a sliding way through the balls; the guard plate is arranged on the sliding block. This application has the effect that promotes the protection effect to the rifle that charges.

Description

Emergency charging station based on wind-solar complementary power generation

Technical Field

The application relates to the field of charging equipment, in particular to an emergency charging station based on wind-solar complementary power generation.

Background

With the continuous development of new energy technology, electric vehicles are increasingly increased, and charging of electric vehicles becomes a relatively realistic problem, so that various charging piles are inoculated.

The emergency charging station is used as one of charging piles, can convert wind energy and solar energy into electric energy and store the electric energy, and is then used for charging the electric automobile.

In the related art, an emergency charging station charges an electric vehicle through a charging gun. When not charging, the charging gun is inserted on the fixed slot of the emergency charging station, so that the charging gun is placed.

With respect to the related art described above, the inventors consider that the emergency charging pile is used for emergency charging of an electric vehicle, and is often installed outdoors. Outdoor environment is abominable, when charging electric automobile, dust and steam in the air easily get into in the fixed slot to gather in the fixed slot, thereby insert behind locating the fixed slot at the rifle that charges, easily lead to the rifle damage that charges.

Disclosure of Invention

In order to promote the protection effect to the rifle that charges, this application provides an emergency charging station based on complementary electricity generation of scene.

The application provides an emergency charging station based on wind-solar complementary power generation adopts following technical scheme:

the utility model provides an emergency charging station based on complementary electricity generation of scene, includes the pile body, sets up the scene electricity generation subassembly and the rifle that charges on the pile body, its characterized in that: the pile body is provided with a fixed slot for inserting the charging gun, and the edge of the fixed slot is provided with a protection component for opening and closing the fixed slot;

the protection assembly comprises a sliding piece and a protection plate;

the sliding piece comprises a sliding block, two fixed long strips and a plurality of balls; the two fixed strips are arranged on the edges of the two sides of the fixed slot, and the fixed strips are provided with sliding grooves; the sliding blocks are connected to the sliding grooves of the fixed strips in a sliding way through the balls; the protection plate is arranged on the sliding block.

Through adopting above-mentioned technical scheme, wind-solar power generation component is used for converting wind energy and solar energy into solar energy, and is stored in the pile body, and the rifle that charges is used for dashing electric energy in the pile body to electric automobile. When not charging the electric automobile, the charging gun is inserted on the fixed slot, so that water vapor and dust are difficult to enter the fixed slot. When charging electric automobile, charge the rifle and take out on by fixed slot, stir the guard plate this moment and can make the slider remove on two fixed rectangular through a plurality of balls to make the guard plate seal fixed slot, with the possibility that reduces dust and steam and gather in fixed slot, and then promote the protection effect to charging the rifle.

Optionally, the protection assembly further comprises a reset piece, wherein the reset piece comprises two reels and two spring rolls;

the reel sets up in the one end of sliding tray one by one, the spring is rolled up one by one and is set up on the reel, the spring is rolled up and is connected with the slider.

Through adopting above-mentioned technical scheme, when charging the rifle and inserting and locating on the fixed slot, leave the interval between slider and the reel, the spring is rolled up and is stretched and drawn the slider to make the guard plate support and press on charging the rifle and strengthen the stability when charging the rifle and inserting and locating the fixed slot. When the charging gun is pulled out of the fixed slot, the movable plate and the charging gun are released from being pressed, and the two sliding blocks are respectively pulled down by the two spring rolls and respectively abutted on the two reels. The protection plate seals the fixed slot, so that in the period of charging the electric automobile, water vapor and dust are reduced to enter the fixed slot, and then the protection effect of the charging gun is improved.

Optionally, the spring coil is made of a memory alloy material.

Through adopting above-mentioned technical scheme, at the in-process that charges to electric automobile, the spring is rolled up and can often receive stretch-draw and shrink, uses the spring to roll up and select as memory alloy material can effectively promote the life of spring volume.

Optionally, a sealing wool top is arranged on the edge of the protection plate, which is close to one side of the sliding block, and the sealing wool top is abutted to the edge of the fixed slot.

Through adopting above-mentioned technical scheme, sealed wool top can block the dust to reduce the possibility that the dust got into in the fixed slot.

Optionally, a handle is arranged on one side of the protection plate far away from the sliding block.

By adopting the technical scheme, the force can be applied only by holding the handle when the protection plate needs to be moved.

Optionally, the protection plate is concave near the one end of reel.

Through adopting above-mentioned technical scheme, the lateral wall of rifle charges is arcuation, can adapt to with the lateral wall of rifle charges through setting up the one end of guard plate to sunken form to stability when can promoting the butt and charging the stake.

Optionally, be provided with the elastic layer on the one end that the guard plate was sunken form, the elastic layer can with charge the lateral wall butt of rifle.

Through adopting above-mentioned technical scheme, when the lateral wall of rifle is charged in guard plate butt, elastic deformation can take place for the elastic layer to promote with the compactness of guard plate and rifle butt that charges. Simultaneously, the elastic layer can also cushion, can promote the protection effect to the rifle that charges.

Optionally, the elastic layer is made of rubber.

By adopting the technical scheme, the rubber material has good elastic effect, and the manufacturing cost is low, so that the cost can be effectively reduced.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the fixed slot is closed or opened through the protection plate, the possibility that dust and water vapor accumulate in the fixed slot can be reduced, so that the charging gun is damaged by the dust and the water vapor when being inserted into the fixed slot again, and the protection effect of the charging gun is improved.

Drawings

Fig. 1 is a schematic overall structure of an embodiment of the present application.

Fig. 2 is a schematic structural view of a wind power generation element according to an embodiment of the present application.

Fig. 3 is a schematic structural diagram of the charging gun inserted into the fixing slot in the implementation of the present application.

Fig. 4 is a schematic structural diagram of the protection component when the charging gun is not inserted into the fixing slot in the embodiment of the present application.

Reference numerals: 1. a wind-light power generation assembly; 11. a wind power generation member; 111. a mounting frame; 112. rotating the blade; 113. a low-speed rotating shaft; 114. a gear box; 115. a high-speed rotating shaft; 116. a generator; 12. a solar power generation member; 121. a solar panel; 122. a solar controller; 123. a storage battery; 2. a pile body; 21. a fixed slot; 3. a charging gun; 4. a protective assembly; 41. a sliding member; 411. a slide block; 412. fixing the strip; 4121. a slip groove; 413. a ball; 42. a reset member; 421. a reel; 422. a spring roll; 43. a protection plate; 431. a grip; 432. sealing the wool tops; 433. an elastic layer.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-4.

The embodiment of the application discloses an emergency charging station based on wind-solar complementary power generation.

Referring to fig. 1, an emergency charging station based on wind-solar complementary power generation comprises a wind-solar power generation assembly 1, a pile body 2, a charging gun 3 and a protection assembly 4. Pile body 2 fixed connection is subaerial, and wind-light power generation subassembly 1 sets up on pile body 2, and wind-light power generation subassembly 1 and pile body 2 electricity are connected. The charging gun 3 is fixedly connected to the pile body 2, and the charging gun 3 is electrically connected with the pile body 2. One side of the pile body 2 is provided with a fixed slot 21, the protection component 4 is arranged on the edge of the fixed slot 21, and the charging gun 3 can open the protection component 4 and is inserted into the fixed slot 21.

The wind-solar power generation assembly 1 is used for generating power through wind energy and solar energy, the pile body 2 is further connected with a commercial power supply and can store electric energy, and the charging gun 3 can charge the electric automobile. The fixed slot 21 is used for fixing the charging gun 3 when not charging, and the protection component 4 is used for sealing and protecting the fixed slot 21 when the charging gun 3 charges the electric automobile.

The wind-solar power generation assembly 1 includes a wind power generation element 11 and a solar power generation element 12. The wind power generation piece 11 is arranged at one end of the pile body 2 far away from the ground, and the solar power generation piece 12 is arranged on the wind power generation piece 11. And the wind power generation piece 11 and the solar power generation piece 12 are respectively and electrically connected with the pile body 2.

Referring to fig. 1 and 2, the wind power generation element 11 includes a mounting frame 111, a rotor blade 112, a low-speed rotating shaft 113, a gear case 114, a high-speed rotating shaft 115, and a generator 116. The installation frame 111 is fixedly connected to one end of the pile body 2 far away from the ground, and the generator 116 is horizontally and fixedly connected to the bottom of the installation frame 111. One end of the high-speed rotating shaft 115 is coaxially and fixedly connected to the rotating shaft of the generator 116, the other end is connected to the gear case 114, one end of the low-speed rotating shaft is connected to the gear case 114, and the other end is connected to the rotating blades 112. Gearbox 114 is used to boost the rotational speed of the rotational shaft of generator 116, generator 116 being electrically connected to pile body 2.

The rotating blades 112 can rotate under the driving of wind, so that the low-speed rotating shaft 113 drives the high-speed rotating shaft 115 to rotate through the gear box 114, and the rotating shaft of the generator 116 is driven to rotate. Thereby completing the conversion from wind energy to mechanical energy and then to electric energy, and further completing the generation and storing in the pile body 2.

Referring to fig. 1 and 2, the solar power generation member 12 includes a solar panel 121, a solar controller 122, and a storage battery 123. The solar panel 121 is fixedly connected to the top of the mounting frame 111, and the solar controller 122 and the storage battery 123 are fixedly connected to one side of the solar panel 121 near the mounting frame 111. And the solar controller 122 is electrically connected with the solar panel 121, the storage battery 123 and the pile body 2, respectively.

When sunlight irradiates on the solar panel 121, the solar panel 121 converts solar energy into electric energy, and the solar controller 122 temporarily stores the electric energy in the storage battery 123. The solar controller 122 then stores the electric energy in the storage battery 123 in the pile body 2.

Referring to fig. 1 and 3, the shielding assembly 4 includes a slider 41, a reset member 42, and a shielding plate 43. The sliding member 41 is disposed on the edge of the fixed slot 21, and the resetting member 42 and the protection plate 43 are both disposed on the sliding member 41. The slider 41 can slide so as to leak or seal the fixing slot 21 by the shielding plate 43. The reset member 42 can reset the slider 41 to a state where the protection plate 43 seals the fixed slot 21.

The slider 41 comprises a slider 411, two fixed bars 412 and a plurality of balls 413. The two fixing strips 412 are respectively and fixedly connected to two opposite sides of the fixing slot 21 side by side, and the fixing strips 412 are provided with sliding grooves 4121 along the length direction of the fixing strips 412, and the sliding grooves 4121 are positioned at one side close to the other fixing strip 412. The balls 413 are rotatably connected to the sliding groove 4121 at equal intervals, and the sliding block 411 is slidably connected to the two fixed bars 412 through the balls 413.

Referring to fig. 1 and 4, a side middle portion of one end of the protection plate 43 is fixedly coupled to a side of the slider 411 away from the bottom of the fixing slot 21. Meanwhile, a grip 431 is fixedly connected to a side of the protection plate 43 away from the sliding block 411, so that the protection plate 43 is moved by the grip 431 to control the sliding of the sliding block 411. A sealing wool top 432 is adhered to the edge of the side, connected with the sliding block 411, of the protection plate 43, and the sealing wool top 432 is abutted to the edge of the fixing slot 21. The seal wool tops 432 can block the gap between the edge of the fixing slot 21 and the shielding plate 43, thereby reducing the possibility of dust entering into the fixing slot 21.

The return member 42 comprises two reels 421 and two spring rolls 422. The two reels 421 are fixedly connected to the two sliding grooves 4121, respectively, and the reels 421 are located at one ends of the sliding grooves 4121. Two spring rolls 422 are fixed on the two reels 421 in a one-to-one sleeved mode, and the ends of the spring rolls 422 are connected with the sliding blocks 411 in the corresponding sliding grooves 4121. When the slide block 411 is slid to enable the protection plate 43 to leak out of the fixing slot 21, the spring roll 422 stretches out, and a pulling force is applied to the slide block 411 to enable the slide block 411 to reset, so that the protection plate 43 seals the fixing slot 21 again.

In the embodiment of the present application, the spring roll 422 is made of a memory alloy material. Meanwhile, one end of the protection plate 43, which is close to the reel 421, is concave, and an elastic layer 433 is adhered to the end of the protection plate 43, and the side wall of the charging gun 3 can be abutted to the elastic layer 433. In the embodiment of the present application, the elastic layer 433 is made of rubber.

The implementation principle of the emergency charging station based on wind-solar complementary power generation is as follows: when the emergency charging station does not charge the electric vehicle, the charging gun 3 is inserted into the fixed slot 21. At this time, a space is reserved between the slider 411 and the reel 421, and the spring roll 422 stretches the slider 411, so that the concave end of the protection plate 43 is pressed against the charging gun 3, and the stability of the charging gun 3 when being inserted into the fixed slot 21 is enhanced.

When the electric vehicle needs to be charged by the emergency charging station, the protection plate 43 is moved through the handle 431, so that the movable plate and the charging gun 3 are released from the pressing force, then the charging gun 3 is taken down by the fixed slot 21 and the electric vehicle is charged, and at the moment, the two sliding blocks 411 are respectively pressed against the two reels 421 under the tension of the two spring rolls 422. The protection plate 43 seals the fixing slot 21, and the sealing wool tops 432 block the gap between the protection plate 43 and the fixing slot 21, so that moisture and dust are reduced from entering the fixing slot 21 during the period of charging the electric automobile. Thereby improving the protection effect of the charging gun 3.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (8)

1. The utility model provides an emergency charging station based on complementary electricity generation of scene, includes pile body (2), sets up wind-light power generation subassembly (1) and rifle (3) that charge on pile body (2), its characterized in that: a fixed slot (21) for inserting the charging gun (3) is formed in the pile body (2), and a protective component (4) for opening and closing the fixed slot (21) is arranged on the edge of the fixed slot (21);

the protection assembly (4) comprises a sliding piece (41) and a protection plate (43);

the sliding piece (41) comprises a sliding block (411), two fixed long strips (412) and a plurality of balls (413); the two fixing strips (412) are arranged on the two side edges of the fixing slot (21), and the fixing strips (412) are provided with sliding slots (4121); the balls (413) are rotatably connected in the sliding groove (4121), and the sliding block (411) is slidably connected on the sliding groove (4121) of the fixed strip (412) through the balls (413); the protection plate (43) is arranged on the sliding block (411).

2. The wind-solar complementary power generation-based emergency charging station of claim 1, wherein: the protection assembly (4) further comprises a reset piece (42), wherein the reset piece (42) comprises two reels (421) and two spring rolls (422);

the reels (421) are arranged at one ends of the sliding grooves (4121) one by one, the spring rolls (422) are arranged on the reels (421) one by one, and the spring rolls (422) are connected with the sliding blocks (411).

3. The wind-solar complementary power generation-based emergency charging station of claim 2, wherein: the spring coil (422) is made of memory alloy.

4. The wind-solar complementary power generation-based emergency charging station of claim 2, wherein: the edge of the protection plate (43) close to one side of the sliding block (411) is provided with a sealing wool top (432), and the sealing wool top (432) is abutted to the edge of the fixed slot (21).

5. The wind-solar complementary power generation-based emergency charging station of claim 2, wherein: a handle (431) is arranged on one side, far away from the sliding block (411), of the protection plate (43).

6. The wind-solar complementary power generation-based emergency charging station of claim 2, wherein: one end of the protection plate (43) close to the reel (421) is in a concave shape.

7. The wind-solar complementary power generation-based emergency charging station of claim 6, wherein: an elastic layer (433) is arranged at one end of the concave-shaped protection plate (43), and the elastic layer (433) can be abutted against the side wall of the charging gun (3).

8. The wind-solar complementary power generation-based emergency charging station of claim 7, wherein: the elastic layer (433) is made of rubber.