CN219196677U - Lifting climbing frame with wind power generation, solar power generation and power storage functions - Google Patents

Abstract

The utility model relates to a lifting climbing frame with wind power generation, solar power generation and power storage functions, and belongs to the technical field of building construction. The technical proposal is as follows: the solar energy power generation system comprises a wind energy power generation system (3), a solar energy power generation system (4) and a storage battery (5) which are arranged on a climbing frame body, wherein the storage battery (5) is arranged on an operation layer (2) of the climbing frame body, and a wind power generation unit (6) is connected with the storage battery (5) through a fan controller (8). The solar panel (11) is connected with the storage battery (5) through the photovoltaic controller (13). The utility model has the positive effects that: the advantage that building roof area is big and the position is high is utilized, through setting up wind power generation system and solar energy power generation system at the outside lift of building, utilize wind energy and solar energy to carry out renewable power generation, safe and reliable reduces the emergence of electric shock accident.

Description

Lifting climbing frame with wind power generation, solar power generation and power storage functions

Technical Field

The utility model relates to a lifting climbing frame with wind power generation, solar power generation and power storage functions, and belongs to the technical field of building construction.

Background

With the development of the building industry, more and more high-rise and high-rise construction buildings are built, and in order to increase the construction speed, attached lifting scaffolds are used for external protection during construction of the high-rise and high-rise construction buildings. The attached lifting scaffold has safe structure and reliable anti-falling system, but the illumination power supply in the scaffold body still uses 220v alternating current power supply to supply power in the construction process of high-rise buildings, thus easily causing electric shock accidents. The climbing frame is positioned at the top end of the construction surface, and wind power and solar energy are not collected and converted into electric energy for reuse in the prior art.

Disclosure of Invention

The utility model aims to provide the lifting climbing frame with wind power generation, solar power generation and power storage functions, which can convert wind power or solar energy into electric energy by utilizing the kinetic energy of wind or the photoelectric effect of a solar battery, provide a safe power supply for equipment such as illumination, remote monitoring and the like, reduce electric shock accidents and effectively solve the problems existing in the background technology.

The technical scheme of the utility model is as follows:

the lifting climbing frame with the functions of wind power generation, solar power generation and power storage comprises a wind power generation system and a storage battery, wherein the wind power generation system and the storage battery are arranged on a climbing frame body, the wind power generation system comprises a wind power generator set, a wind power generator connecting seat, a fan controller and a fan controller mounting frame, the wind power generator connecting seat is arranged at the top end of a vertical rod of the climbing frame body, the wind power generator set is arranged on the wind power generator connecting seat, the fan controller mounting frame is arranged on the vertical rod below the wind power generator connecting seat, and the fan controller is arranged on the fan controller mounting frame; the operation layer of the climbing frame body is provided with a storage battery, and the wind generating set is connected with the storage battery through a fan controller.

Further, the storage battery is arranged in a storage battery steel plate shell, and the storage battery steel plate shell is fixed on the operation layer to prevent the storage battery from aging.

Further, a solar power generation system can be further arranged on the climbing frame body, the solar power generation system comprises a solar panel mounting frame, a solar panel, a photovoltaic controller and a photovoltaic controller connecting seat, the solar panel mounting frame is arranged at the top end of the vertical rod of the climbing frame body, the solar panel is arranged on the solar panel mounting frame, the photovoltaic controller connecting seat is arranged on the vertical rod below the solar panel mounting frame, and the photovoltaic controller is arranged on the photovoltaic controller connecting seat; the solar panel is connected with the storage battery through the photovoltaic controller.

Preferably, the wind driven generator connecting seat comprises a U-shaped groove I, an inclined strut I, a cross rod I, a wind driven generator inclined strut and a baffle I, wherein the U-shaped groove I is fixed on the top end of a vertical rod through bolts, one end of the cross rod I is fixed on the U-shaped groove I, the baffle I is fixedly arranged at the other end of the cross rod I, a wind driven generator set is fixed on the upper end face of the cross rod I, the wind driven generator inclined strut is arranged between the upper end face of the cross rod I and a supporting rod of the wind driven generator set, and the inclined strut is arranged between the lower end face of the cross rod I and the U-shaped groove I.

Preferably, the fan controller mounting frame is an L-shaped mounting frame I formed by welding a steel plate I and a steel plate II, the steel plate I is fixed on the U-shaped groove I, and the fan controller is fixed on the L-shaped mounting frame I through screws.

Preferably, the solar panel mounting rack comprises a second cross rod, a second U-shaped groove, a second inclined strut and a second baffle, the number of the second U-shaped groove and the second cross rod is two, the two U-shaped grooves are respectively fixed on corresponding vertical rods, one ends of the second cross rods are fixed on the second corresponding U-shaped groove, the other ends of the second cross rods are respectively fixed with the second baffle, the upper end faces of the second cross rods are provided with solar panels, and the second inclined strut is respectively arranged between the lower end faces of the second cross rods and the corresponding vertical rods.

Preferably, the photovoltaic controller connecting seat is an L-shaped mounting frame II formed by welding a steel plate III and a steel plate IV, the steel plate III is fixed on the U-shaped groove II, and the photovoltaic controller is fixed on the L-shaped mounting frame II through screws.

The storage battery is connected with the lighting equipment or the monitoring equipment on the climbing frame body to supply power for the lighting equipment or the monitoring equipment. In addition, the storage battery can be connected with electric equipment in the building to supply power for the electric equipment in the building.

The utility model has the positive effects that: the advantage that building roof area is big and the position is high is utilized, through setting up wind power generation system and solar energy power generation system at the outside lift of building, utilize wind energy and solar energy to carry out renewable power generation, safe and reliable reduces the emergence of electric shock accident.

Drawings

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

FIG. 2 is a schematic view of the installation structure of the wind energy generation system (wall-mounted type);

FIG. 3 is a schematic view of the installation structure of the wind energy generation system (plate-type support type);

FIG. 4 is a top view of the wind energy generation system of the present utility model;

FIG. 5 is a left side view of the wind energy generation system of the present utility model;

FIG. 6 is a left side view of the solar power generation system of the present utility model;

FIG. 7 is a top view of the solar power generation system of the present utility model;

FIG. 8 is a schematic view of the installation structure of the solar power generation system (wall-mounted type);

FIG. 9 is a schematic view of the installation structure of the solar power generation system (plate-type support type);

FIG. 10 is a schematic diagram of a building peripheral application layout;

in the figure: the solar energy power generation system comprises a vertical rod 1, an operation layer 2, a wind energy power generation system 3, a solar energy power generation system 4, a storage battery 5, a wind power generation unit 6, a wind power generation unit connecting seat 7, a U-shaped groove I71, an inclined strut I72, a cross rod I73, a wind power generation unit inclined strut 74, a baffle I75, a fan controller 8, a fan controller mounting frame 9, a steel plate I91, a steel plate II 92, a solar panel mounting frame 10, a cross rod II 101, a U-shaped groove II 102, an inclined strut II 103, a baffle II 104, a solar panel 11, a storage battery steel plate housing 12, a photovoltaic controller 13, a photovoltaic controller connecting seat 14, a steel plate III 141, a steel plate IV 142 and a building outer wall 15.

Detailed Description

The utility model is further illustrated by the following examples in conjunction with the accompanying drawings:

referring to fig. 1 and 10, the present embodiment provides a lifting climbing frame with wind power generation, solar power generation and electricity storage functions, which comprises a plurality of groups of wind power generation systems 3, solar power generation systems 4 and storage batteries 5 arranged on a climbing frame body. The storage battery 5 stores power supplied by the wind power generation system 3 and the solar power generation system 4, and is connected with the lighting equipment or the monitoring equipment on the climbing frame body to supply power to the lighting equipment or the monitoring equipment. In addition, the storage battery 5 can be connected with electric equipment in the building to supply power for the electric equipment in the building.

Referring to fig. 2 and 3, the wind power generation system 3 includes a wind power generator set 6, a wind power generator connection seat 7, a fan controller 8 and a fan controller installation frame 9, the wind power generator connection seat 7 is installed at the top end of the vertical rod 1 of the climbing frame body, the wind power generator set 6 is arranged on the wind power generator connection seat 7, the fan controller installation frame 9 is arranged on the vertical rod below the wind power generator connection seat 7, and the fan controller 8 is arranged on the fan controller installation frame 9; the operation layer 2 of the climbing frame body is provided with a storage battery 5, and the wind generating set 6 is connected with the storage battery 5 through a fan controller 8. The storage battery 5 is arranged in the storage battery steel plate shell 12, the storage battery steel plate shell 12 is fixed on the operation layer 2, corrosion of the rainwater storage battery is prevented, and the service life of the storage battery is prolonged. Preferably, the battery steel plate housing 12 is formed by welding a plurality of steel plates.

Referring to fig. 4 and 5, the wind turbine connecting seat 7 includes a U-shaped groove one 71, an inclined strut one 72, a cross rod one 73, a wind turbine inclined strut 74 and a baffle one 75, the U-shaped groove one 71 is fixed on the top end of the upright 1 through a bolt, one end of the cross rod one 73 is fixed on the U-shaped groove one 71, the baffle one 75 is fixedly arranged on the other end of the cross rod one 73, the wind turbine generator set 6 is fixed on the upper end surface of the cross rod one 73, the wind turbine inclined strut 74 is arranged between the upper end surface of the cross rod one 73 and the supporting rod of the wind turbine generator set 6, and the wind turbine inclined strut 74 strengthens the fixing strength of the wind turbine generator set 6 to prevent the wind turbine generator set 6 from falling. And a diagonal brace 22 is arranged between the lower end surface of the first cross rod 73 and the first U-shaped groove 71, so that the fixing strength of the first cross rod 73 is enhanced.

The fan controller mounting frame 9 is an L-shaped mounting frame I formed by welding a steel plate I91 and a steel plate II 92, the steel plate I91 is fixed on the U-shaped groove I71, and the fan controller 8 is fixed on the L-shaped mounting frame I through screws. The fan controller mounting frame 9 can also be a groove type mounting frame I, and the fan controller 8 is fixed in the groove type mounting frame I through screws.

Referring to fig. 8 and 9, the solar power generation system 4 includes a solar panel mounting frame 10, a solar panel 11, a photovoltaic controller 13 and a photovoltaic controller connecting seat 14, wherein the solar panel mounting frame 10 is disposed at the top end of the upright 1 of the climbing frame body, the solar panel 11 is disposed on the solar panel mounting frame 10, the upright below the solar panel mounting frame 10 is provided with the photovoltaic controller connecting seat 14, and the photovoltaic controller 13 is disposed on the photovoltaic controller connecting seat 14; the solar panel 11 is connected to the battery 5 via a photovoltaic controller 13.

Referring to fig. 6 and 7, the solar panel mounting rack 10 includes two cross bars 101, two U-shaped grooves 102, two diagonal braces 103 and two baffles 104, the number of the two U-shaped grooves 102 and the two cross bars 101 is two, the two U-shaped grooves 102 are respectively fixed on corresponding vertical rods, one ends of the two cross bars 101 are fixed on the corresponding two U-shaped grooves 102, the other ends of the two cross bars 101 are respectively fixed with the corresponding baffles 104, the upper end faces of the two cross bars 101 are provided with solar panels 11, and diagonal braces 103 are respectively arranged between the lower end faces of the two cross bars 101 and the corresponding vertical rods.

The photovoltaic controller connecting seat 14 is an L-shaped mounting frame II formed by welding a steel plate III 141 and a steel plate IV 142, the steel plate III 141 is fixed on the U-shaped groove II 102, and the photovoltaic controller 13 is fixed on the L-shaped mounting frame II through screws. The photovoltaic controller connecting seat 14 can also be a groove type mounting frame II, and the photovoltaic controller 13 is fixed in the groove type mounting frame II through screws.

The utility model converts wind power and solar energy into electric energy by utilizing the advantages of large building roof area and high position and utilizing the kinetic energy of wind and the photoelectric effect of the solar battery. Wind power generation is a mature technology in the prior art, and wind power generation drives windmill blades to rotate by utilizing wind power, and then the rotating speed is increased through a speed increaser so as to promote a generator to generate electricity. According to windmill technology, the electric power can be generated at a breeze speed (breeze degree) of about three meters per second, so that a safe power supply can be provided for equipment such as illumination, remote monitoring and the like, and electric shock accidents can be reduced. Solar power generation is also a mature technology in the prior art, and solar energy is converted into electric energy by utilizing the photoelectric effect of a solar cell. A solar cell is a device for directly converting solar energy into electric energy due to a photovoltaic effect, and is a semiconductor photodiode, which converts solar energy into electric energy when solar light is irradiated onto the photodiode, thereby generating current. When a plurality of batteries are connected in series or in parallel, the solar battery array with larger output power can be formed, and a safe power supply can be provided for equipment such as illumination, remote monitoring and the like, so that electric shock accidents can be reduced.

Claims (8)

1. The utility model provides a frame is climbed in lift with wind power generation, solar energy power generation and electric power storage function which characterized in that: the wind power generation system (3) comprises a wind power generation system (3) and a storage battery (5) which are arranged on a climbing frame body, wherein the wind power generation system (3) comprises a wind power generation unit (6), a wind power generation unit connecting seat (7), a fan controller (8) and a fan controller mounting frame (9), the wind power generation unit connecting seat (7) is arranged at the top end of a vertical rod (1) of the climbing frame body, the wind power generation unit (6) is arranged on the wind power generation unit connecting seat (7), the fan controller mounting frame (9) is arranged on the vertical rod below the wind power generation unit connecting seat (7), and the fan controller (8) is arranged on the fan controller mounting frame (9); the operation layer (2) of the climbing frame body is provided with a storage battery (5), and the wind generating set (6) is connected with the storage battery (5) through a fan controller (8).

2. The lifting climbing frame with wind power generation, solar power generation and power storage functions according to claim 1, wherein the lifting climbing frame is characterized in that: the storage battery (5) is arranged in a storage battery steel plate shell (12), and the storage battery steel plate shell (12) is fixed on the operation layer (2).

3. The lifting climbing frame with wind power generation, solar power generation and power storage functions according to claim 1, wherein the lifting climbing frame is characterized in that: the climbing frame body is provided with a solar power generation system (4), the solar power generation system (4) comprises a solar panel mounting frame (10), a solar panel (11), a photovoltaic controller (13) and a photovoltaic controller connecting seat (14), the solar panel mounting frame (10) is arranged at the top end of a vertical rod (1) of the climbing frame body, the solar panel (11) is arranged on the solar panel mounting frame (10), the photovoltaic controller connecting seat (14) is arranged on the vertical rod below the solar panel mounting frame (10), and the photovoltaic controller (13) is arranged on the photovoltaic controller connecting seat (14); the solar panel (11) is connected with the storage battery (5) through the photovoltaic controller (13).

4. A lifting climbing frame with wind power generation, solar power generation and storage functions according to claim 1 or 3, characterized in that: the wind driven generator connecting seat (7) comprises a U-shaped groove I (71), an inclined strut I (72), a cross rod I (73), a wind driven generator inclined strut (74) and a baffle I (75), wherein the U-shaped groove I (71) is fixed on the top end of a vertical rod (1) through bolts, one end of the cross rod I (73) is fixed on the U-shaped groove I (71), the baffle I (75) is fixedly arranged at the other end of the cross rod I (73), a wind driven generator unit (6) is fixed on the upper end face of the cross rod I (73), the wind driven generator inclined strut (74) is arranged between the upper end face of the cross rod I (73) and a supporting rod of the wind driven generator unit (6), and an inclined strut (22) is arranged between the lower end face of the cross rod I (73) and the U-shaped groove I (71).

5. The lifting climbing frame with wind power generation, solar power generation and power storage functions according to claim 4, wherein the lifting climbing frame is characterized in that: the fan controller mounting frame (9) is an L-shaped mounting frame I formed by welding a steel plate I (91) and a steel plate II (92), the steel plate I (91) is fixed on the U-shaped groove I (71), and the fan controller (8) is fixed on the L-shaped mounting frame I through screws.

6. A lifting climbing frame with wind power generation, solar power generation and power storage functions according to claim 3, wherein: the solar panel mounting rack (10) comprises two cross bars (101), two U-shaped grooves (102), two inclined struts (103) and two baffle plates (104), wherein the two U-shaped grooves (102) and the two cross bars (101) are two in number, the two U-shaped grooves (102) are respectively fixed on corresponding vertical rods, one ends of the two cross bars (101) are fixed on the corresponding two U-shaped grooves (102), the other ends of the two cross bars (101) are respectively fixed with the corresponding baffle plates (104), the solar panels (11) are arranged on the upper end faces of the two cross bars (101), and two inclined struts (103) are respectively arranged between the lower end faces of the two cross bars (101) and the corresponding vertical rods.

7. The lifting climbing frame with wind power generation, solar power generation and power storage functions according to claim 3 or 6, wherein: the photovoltaic controller connecting seat (14) is an L-shaped mounting frame II formed by welding a steel plate III (141) and a steel plate IV (142), the steel plate III (141) is fixed on the U-shaped groove II (102), and the photovoltaic controller (13) is fixed on the L-shaped mounting frame II through screws.

8. A lifting climbing frame with wind power generation, solar power generation and storage functions according to claim 1 or 3, characterized in that: the storage battery (5) is connected with lighting equipment or monitoring equipment on the climbing frame body.

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