CN221010044U - Flexible photovoltaic energy storage assembly - Google Patents

Abstract

The utility model discloses a flexible photovoltaic energy storage component, which relates to the technical field of photovoltaic components and comprises a fixed base, a supporting unit, a mounting unit, a solar photovoltaic panel, a fixed unit and an adjusting unit; the fixed unit comprises a fixed plate fixedly connected to the bottom of the solar photovoltaic plate, a fixed sliding strip fixedly connected to the front end and the rear end of the fixed plate and used for limiting and fixing, the adjusting unit comprises a servo motor fixedly connected to the center of the bottom of the fixed base, and a connecting sliding block movably arranged on one side of the supporting unit and used for adjusting the angle of the solar photovoltaic plate. The flexible photovoltaic energy storage component can fix the solar photovoltaic panel in a clamping manner, is convenient and quick to assemble and disassemble, high in stability, convenient to replace or maintain in the later period, capable of adjusting angles of the solar photovoltaic panel, high in stability during angle adjustment, suitable for adjustment of different illumination angles, and good in practicability.

Description

Flexible photovoltaic energy storage assembly

Technical Field

The utility model relates to the technical field of photovoltaic modules, in particular to a flexible photovoltaic energy storage module.

Background

It is known that single solar cells cannot be used directly as power sources. Several single batteries must be connected in series, parallel and tightly packaged into an assembly to be used as a power supply. Solar cell modules (also called solar panels) are the core part of and the most important part of a solar power generation system. The solar energy is converted into electric energy, or is sent to a storage battery for storage, or the load is pushed to work.

Publication (bulletin) number: CN219204412U discloses a flexible photovoltaic energy storage component, which is convenient for adjusting the height of the photovoltaic component, and adopts single adjustment of two supporting legs, so that the convenience of use can be greatly improved while the supporting legs are adapted to the placement environment, and good limiting effect can be achieved when the supporting legs are unfolded or stored, so that the stability of using or storing the photovoltaic component is ensured, and the rotation generated in the moving or transporting process is avoided, and the practicability of the photovoltaic energy storage component is improved.

In the above-mentioned patent, although can carry out the regulation of altitude mixture control to photovoltaic module, do not possess and carry out the regulation of angle to photovoltaic module, can not adapt to different illumination angles, and inconvenient photovoltaic module's whole dismouting, dismouting inefficiency is unfavorable for the change or the maintenance in later stage, consequently, is necessary to provide a flexible photovoltaic energy storage module.

Disclosure of utility model

The utility model mainly aims to provide a flexible photovoltaic energy storage component, which can effectively solve the problems that the angle of the photovoltaic component is not adjusted, the photovoltaic energy storage component cannot adapt to different illumination angles, the whole disassembly and assembly of the photovoltaic component are inconvenient, the disassembly and assembly efficiency is low, and the later replacement or maintenance is not facilitated in the background technology.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows: the flexible photovoltaic energy storage assembly comprises a fixed base, a supporting unit fixedly connected to the top of the fixed base, a mounting unit hinged to the top of the supporting unit, a solar photovoltaic panel mounted on the top of the mounting unit, a fixing unit arranged between the solar photovoltaic panel and the mounting unit, and adjusting units arranged on two sides of the supporting unit;

The fixing unit comprises a fixing plate fixedly connected to the bottom of the solar photovoltaic plate and a fixing sliding strip fixedly connected to the front end and the rear end of the fixing plate and used for limiting and fixing;

The adjusting unit comprises a servo motor fixedly connected to the center of the bottom of the fixed base and a connecting sliding block movably arranged on one side of the supporting unit and used for adjusting the angle of the solar photovoltaic panel.

Preferably, the supporting unit comprises a supporting seat fixedly connected to the center of the top of the fixed base, and a vertical sliding groove formed in one side of the supporting seat.

Preferably, the installation unit comprises an installation table hinged to the top of the supporting seat, an installation groove formed in the top of the installation table, a positioning slot formed in the opposite inner wall surface of the installation groove, a positioning clamping hole formed in the inner wall of one end of the positioning slot in a penetrating mode, and a transverse sliding groove formed in the bottom of one end of the installation table.

Preferably, the fixing unit further comprises a positioning clamp column movably arranged inside the side wall at one end of the fixed sliding strip, a reset spring fixedly connected to one end of the positioning clamp column, and a pressing groove formed in the other end of the positioning clamp column.

Preferably, the adjusting unit further comprises a screw rod fixedly connected to the driving end of the servo motor, a threaded block in threaded connection with the outer surface of the screw rod, a rotating seat a fixedly connected to one side of the connecting sliding block, a rotating seat b fixedly connected to the bottom of one end of the mounting table, a supporting rod a connected between the rotating seat a and the rotating seat b, a rotating seat c fixedly connected to one side of the supporting seat, a sliding rotating seat movably arranged in the transverse sliding groove, and a supporting rod b connected between the rotating seat c and the sliding rotating seat.

Preferably, the size of the fixing plate is matched with the size of the inner dimension of the mounting groove, the section dimension of the fixed slide bar is matched with the inner dimension of the positioning slot, the inner diameter dimension of the positioning clamping hole is matched with the outer diameter dimension of the positioning clamping column, and the reset spring is fixedly connected between the positioning clamping column and the inner wall of the fixed slide bar.

Preferably, one side of the thread block is fixedly connected with one end of the connecting sliding block, the connecting sliding block is movably arranged in the vertical sliding groove, the supporting rod a is rotationally connected between the rotating seat a and the rotating seat b, and the supporting rod b is rotationally connected between the rotating seat c and the sliding rotating seat.

Compared with the prior art, the utility model has the following beneficial effects:

1. According to the solar photovoltaic panel fixing device, the fixing plate provided with the solar photovoltaic panel is provided with the mounting grooves corresponding to the mounting tables, the fixed sliding strips at the front end and the rear end of the fixing plate are aligned to the positioning slots and are inserted, the positioning clamping columns at one end side of the fixed sliding strips are extruded by the inner walls of the positioning slots, the reset spring is enabled to compress and drive the positioning clamping columns to move inwards until the fixing plate is mounted to the bottom, the positioning clamping columns and the positioning clamping holes are located on the same horizontal plane at the moment, after the reset spring loses extrusion force, the positioning clamping columns are ejected into the positioning clamping holes through elastic recovery, and therefore the fixing plate can be detached by only inserting a columnar rod body into the pressing grooves to press the positioning clamping columns when the solar photovoltaic panel is detached.

2. According to the solar photovoltaic panel angle adjusting mechanism, the servo motor is started to drive the screw rod to rotate, the screw rod is driven to rotate to drive the threaded block to move up and down on the outer surface of the screw rod, the connecting sliding block is driven to slide up and down in the vertical sliding groove, one end of the installation table is driven to deflect up and down through the rotating connection of the rotating seat a, the supporting rod a and the rotating seat b, one end of the installation table deflects up and down, the rotating seat c, the supporting rod b and the sliding rotating seat are connected in a rotating manner, the sliding rotating seat deflects reversely under the condition that the inner part of the horizontal sliding groove transversely slides, the angle adjusting mechanism can adjust the angle of the solar photovoltaic panel, the stability is high during angle adjustment, and the solar photovoltaic panel angle adjusting mechanism can be suitable for adjustment of different illumination angles and has good practicability.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic diagram of the front view and inner cross-section structure of the present utility model;

FIG. 3 is a schematic view of a partial side view of the present utility model in cross-section;

FIG. 4 is an enlarged schematic view of the structure of FIG. 3A according to the present utility model;

fig. 5 is an enlarged schematic view of the structure of fig. 2B according to the present utility model.

In the figure:

100. A fixed base;

200. a supporting unit; 201. a support base; 202. a vertical chute;

300. An installation unit; 301. a mounting table; 302. a mounting groove; 303. positioning the slot; 304. positioning the clamping holes; 305. a horizontal sliding groove;

400. A solar photovoltaic panel;

500. A fixing unit; 501. a fixing plate; 502. a fixed slide bar; 503. positioning a clamping column; 504. a return spring; 505. a pressing groove;

600. An adjusting unit; 601. a servo motor; 602. a screw rod; 603. a screw block; 604. the connecting slide block; 605. a rotating seat a; 606. a supporting rod a; 607. a rotating seat b; 608. a rotating seat c; 609. a support rod b; 610. sliding rotary seat.

Detailed Description

Example 1

Referring to fig. 1 to 5, the present utility model is a flexible photovoltaic energy storage assembly, which includes a fixing base 100, a supporting unit 200 fixedly connected to the top of the fixing base 100, a mounting unit 300 hinged to the top of the supporting unit 200, a solar photovoltaic panel 400 mounted on the top of the mounting unit 300, a fixing unit 500 disposed between the solar photovoltaic panel 400 and the mounting unit 300, and an adjusting unit 600 disposed at both sides of the supporting unit 200;

The adjusting unit 600 includes a servo motor 601 fixedly connected to the center of the bottom of the fixing base 100, and a connection slider 604 movably provided at one side of the supporting unit 200 for adjusting the angle of the solar photovoltaic panel 400.

As shown in fig. 1, 2 and 5, the supporting unit 200 includes a supporting seat 201 fixedly connected to the center of the top of the fixed base 100, and a vertical chute 202 formed on one side of the supporting seat 201, where the top of the supporting seat 201 is in an arc structure and hinged to the center of the bottom of the mounting table 301, so as to facilitate the adjustment of the angle of the solar photovoltaic panel 400, and the formed vertical chute 202 is used for moving the structure during the adjustment of the angle of the solar photovoltaic panel 400.

As shown in fig. 1 to 4, the mounting unit 300 includes a mounting table 301 hinged to the top of the supporting seat 201, a mounting groove 302 formed in the top of the mounting table 301, a positioning slot 303 formed in the opposite inner wall surface of the mounting groove 302, a positioning clip hole 304 formed through the inner wall of one end of the positioning slot 303, and a horizontal sliding groove 305 formed in the bottom of one end of the mounting table 301, the mounting table 301 carries out limit mounting on the fixing plate 501 by the fixing slide 502 through the mounting groove 302 and the positioning slot 303, and enters the fixing clip column 503 through the positioning clip hole 304.

As shown in fig. 1, 3 and 4, the fixing unit 500 includes a fixing plate 501 fixedly connected to the bottom of the solar photovoltaic panel 400, and a fixing slide bar 502 fixedly connected to the front and rear ends of the fixing plate 501 for limiting and fixing, the fixing unit 500 further includes a positioning clamp post 503 movably disposed inside a side wall at one end of the fixing slide bar 502, a return spring 504 fixedly connected to one end of the positioning clamp post 503, and a pressing groove 505 formed at the other end of the positioning clamp post 503, the size of the fixing plate 501 is matched with the inner size of the mounting groove 302, the cross-section size of the fixing slide bar 502 is matched with the inner size of the positioning slot 303, the inner diameter size of the positioning clamp hole 304 is matched with the outer diameter size of the positioning clamp post 503, and the return spring 504 is fixedly connected between the positioning clamp post 503 and the inner wall of the fixing slide bar 502.

Working principle: firstly, the fixing plate 501 provided with the solar photovoltaic panel 400 is corresponding to the mounting groove 302 formed in the mounting table 301, the fixed slide bar 502 at the front end and the rear end of the fixing plate 501 is aligned to the positioning slot 303 and inserted, along with the deep of the fixing plate 501, the positioning clamping column 503 at one end side surface of the fixed slide bar 502 is extruded by the inner wall of the positioning slot 303, the reset spring 504 compresses and drives the positioning clamping column 503 to move inwards until the fixing plate 501 is mounted at the bottom, at the moment, the positioning clamping column 503 and the positioning clamping hole 304 are positioned on the same horizontal plane, after the reset spring 504 loses extrusion force, the elastic recovery ejects the positioning clamping column 503 into the positioning clamping hole 304, so that the solar photovoltaic panel 400 is completely mounted, otherwise, when the solar photovoltaic panel 400 is dismounted, the fixing plate 501 can be dismounted by only pressing the positioning clamping column 503 by inserting a columnar rod body into the pressing groove 505.

Example 2

Referring to fig. 1 to 5, the present utility model is a flexible photovoltaic energy storage assembly, which includes a fixing base 100, a supporting unit 200 fixedly connected to the top of the fixing base 100, a mounting unit 300 hinged to the top of the supporting unit 200, a solar photovoltaic panel 400 mounted on the top of the mounting unit 300, a fixing unit 500 disposed between the solar photovoltaic panel 400 and the mounting unit 300, and an adjusting unit 600 disposed at both sides of the supporting unit 200;

The fixing unit 500 includes a fixing plate 501 fixedly connected to the bottom of the solar photovoltaic panel 400, and a fixing slide bar 502 fixedly connected to the front and rear ends of the fixing plate 501 for limiting fixation.

As shown in fig. 1, 2 and 5, the supporting unit 200 includes a supporting seat 201 fixedly connected to the center of the top of the fixed base 100, and a vertical chute 202 formed on one side of the supporting seat 201, where the top of the supporting seat 201 is in an arc structure and hinged to the center of the bottom of the mounting table 301, so as to facilitate the adjustment of the angle of the solar photovoltaic panel 400, and the formed vertical chute 202 is used for moving the structure during the adjustment of the angle of the solar photovoltaic panel 400.

As shown in fig. 1 to 4, the mounting unit 300 includes a mounting table 301 hinged to the top of the supporting seat 201, a mounting groove 302 formed in the top of the mounting table 301, a positioning slot 303 formed in the opposite inner wall surface of the mounting groove 302, a positioning clip hole 304 formed through the inner wall of one end of the positioning slot 303, and a horizontal sliding groove 305 formed in the bottom of one end of the mounting table 301, the mounting table 301 carries out limit mounting on the fixing plate 501 by the fixing slide 502 through the mounting groove 302 and the positioning slot 303, and enters the fixing clip column 503 through the positioning clip hole 304.

As shown in fig. 1, 2 and 5, the adjusting unit 600 includes a servo motor 601 fixedly connected to the bottom center of the fixed base 100, a connection slider 604 movably disposed at one side of the supporting unit 200 and used for adjusting the angle of the solar photovoltaic panel 400, a screw rod 602 fixedly connected to the driving end of the servo motor 601, a screw block 603 screwed to the outer surface of the screw rod 602, a rotating seat a605 fixedly connected to one side of the connection slider 604, a rotating seat b607 fixedly connected to the bottom of one end of the mounting table 301, a supporting rod a606 connected between the rotating seat a605 and the rotating seat b607, a rotating seat c608 fixedly connected to one side of the supporting seat 201, a sliding rotating seat 610 movably disposed in the horizontal sliding groove 305, and a supporting rod b609 connected between the rotating seat c608 and the sliding rotating seat 610, one side of the screw block 603 is fixedly connected to one end of the connection slider 604, the connecting slider 604 is movably disposed in the vertical sliding groove 202, the supporting rod a606 is rotatably connected between the rotating seat a605 and the rotating seat b607, and the supporting rod b609 is rotatably connected between the rotating seat c608 and the sliding rotating seat 610.

Working principle: when the solar photovoltaic panel 400 needs to be adjusted according to illumination, the servo motor 601 drives the screw rod 602 to rotate through starting the servo motor 601, the screw rod 602 rotates to drive the threaded block 603 to move up and down on the outer surface of the screw rod 602, and the connecting sliding block 604 is driven to slide up and down in the vertical sliding groove 202, so that one end of the installation table 301 is driven to deflect up and down through the rotating connection of the rotating seat a605, the supporting rods a and 606 and the rotating seat b607, one end of the installation table 301 deflects up and down, the rotating connection of the rotating seat c608, the supporting rod b609 and the sliding rotating seat 610 is adopted, and the sliding rotating seat 610 deflects reversely under the inner transverse sliding of the transverse sliding groove 305.

Claims (7)

1. The flexible photovoltaic energy storage assembly comprises a fixed base (100), a supporting unit (200) fixedly connected to the top of the fixed base (100), a mounting unit (300) hinged to the top of the supporting unit (200), and a solar photovoltaic panel (400) mounted on the top of the mounting unit (300), and is characterized by further comprising a fixed unit (500) arranged between the solar photovoltaic panel (400) and the mounting unit (300) and adjusting units (600) arranged on two sides of the supporting unit (200);

The fixing unit (500) comprises a fixing plate (501) fixedly connected to the bottom of the solar photovoltaic panel (400) and a fixing sliding strip (502) fixedly connected to the front end and the rear end of the fixing plate (501) and used for limiting and fixing;

the adjusting unit (600) comprises a servo motor (601) fixedly connected to the center of the bottom of the fixed base (100), and a connecting sliding block (604) movably arranged on one side of the supporting unit (200) and used for adjusting the angle of the solar photovoltaic panel (400).

2. The flexible photovoltaic energy storage assembly of claim 1, wherein: the supporting unit (200) comprises a supporting seat (201) fixedly connected to the center of the top of the fixed base (100), and a vertical sliding groove (202) formed in one side of the supporting seat (201).

3. A flexible photovoltaic energy storage assembly according to claim 2, wherein: the mounting unit (300) comprises a mounting table (301) hinged to the top of the supporting seat (201), a mounting groove (302) formed in the top of the mounting table (301), a positioning slot (303) formed in the opposite inner wall surface of the mounting groove (302), a positioning clamping hole (304) formed in the inner wall of one end of the positioning slot (303) in a penetrating mode, and a transverse sliding groove (305) formed in the bottom of one end of the mounting table (301).

4. A flexible photovoltaic energy storage assembly according to claim 3, wherein: the fixing unit (500) further comprises a positioning clamping column (503) movably arranged in the side wall of one end of the fixed sliding strip (502), a reset spring (504) fixedly connected to one end of the positioning clamping column (503), and a pressing groove (505) formed in the other end of the positioning clamping column (503).

5. A flexible photovoltaic energy storage assembly according to claim 3, wherein: the adjusting unit (600) further comprises a screw rod (602) fixedly connected to the driving end of the servo motor (601), a threaded block (603) in threaded connection with the outer surface of the screw rod (602), a rotating seat a (605) fixedly connected to one side of the connecting sliding block (604), a rotating seat b (607) fixedly connected to the bottom of one end of the mounting table (301), a supporting rod a (606) connected between the rotating seat a (605) and the rotating seat b (607), a rotating seat c (608) fixedly connected to one side of the supporting seat (201), a sliding rotating seat (610) movably arranged in the transverse sliding groove (305), and a supporting rod b (609) connected between the rotating seat c (608) and the sliding rotating seat (610).

6. The flexible photovoltaic energy storage assembly of claim 4, wherein: the size of the fixing plate (501) is matched with the size of the inner dimension of the mounting groove (302), the section size of the fixed sliding strip (502) is matched with the inner dimension of the positioning slot (303), the inner diameter size of the positioning clamping hole (304) is matched with the outer diameter size of the positioning clamping column (503), and the reset spring (504) is fixedly connected between the positioning clamping column (503) and the inner wall of the fixed sliding strip (502).

7. The flexible photovoltaic energy storage assembly of claim 5, wherein: one side of the thread block (603) is fixedly connected with one end of the connecting sliding block (604), the connecting sliding block (604) is movably arranged in the vertical sliding groove (202), the supporting rod a (606) is rotationally connected between the rotating seat a (605) and the rotating seat b (607), and the supporting rod b (609) is rotationally connected between the rotating seat c (608) and the sliding rotating seat (610).