CN218664950U - Integral hoisting tool for photovoltaic support - Google Patents

Abstract

The utility model discloses a photovoltaic support integral hoisting instrument, include: the hoisting frame is provided with a hanging point for hanging a hoisting rope; the telescopic beam assembly at least comprises a set of, the telescopic beam assembly including set up in first telescopic beam and the flexible roof beam of second on the hoist and mount frame, the flexible roof beam of first telescopic beam and second is arranged relatively, and is located same straight line, first telescopic beam be used for with the support sloping of photovoltaic support one end be connected, the flexible roof beam of second be used for with the other end of support sloping is connected. The utility model discloses insert the both ends of support sloping respectively in first flexible roof beam and the flexible roof beam of second to realize that photovoltaic support and this photovoltaic support integral hoisting instrument's reliable connection. The whole photovoltaic support can be lifted by traction of the lifting rope. The utility model discloses simple structure, the atress route is clear and definite, low in manufacturing cost, moreover with photovoltaic support be connected very reliably, the operation is also very simple and convenient in the use, convenient to use and later stage dimension guarantor.

Description

Integral hoisting tool for photovoltaic support

Technical Field

The utility model relates to a marine photovoltaic technology field especially relates to a photovoltaic support integral hoisting instrument.

Background

In recent years, with the rapid development of onshore photovoltaics, the number of fields suitable for building photovoltaics is less and less, meanwhile, the country also strictly limits the project of building photovoltaics in partial areas, and the sea has wide areas and good sunlight conditions, so that the offshore photovoltaics industry is gradually heated. At present, the construction of offshore photovoltaic continues the development mode of onshore photovoltaic, and a construction mode of assembling parts is adopted. For the tidal flat sea area, the assembly construction of parts is acceptable because large ship equipment cannot enter the field for construction. With the deepening of the water depth, the mode of assembling the parts is not suitable for use. The integral hoisting mode is undoubtedly a very good mode, and a plurality of groups of photovoltaic supports, purlines and photovoltaic panels are integrally installed, so that the efficiency of offshore construction can be greatly improved, a large amount of offshore construction time and cost are saved, the use cost of the ship engine is reduced, and the ship engine is an inevitable trend of future offshore photovoltaic development.

However, the photovoltaic support is not integrally hoisted by using a tool in the prior art, so that a constructor is required to hoist the lifting rope bound on the photovoltaic support, the construction efficiency is low, the lifting rope bound is influenced by the proficiency of the constructor, and once the binding rope is loosened due to inexperience, the construction case source is influenced.

Therefore, how to realize the integral hoisting of the photovoltaic support to improve the construction efficiency and the safety is a technical problem to be solved by the technical personnel in the field.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model aims at providing a photovoltaic support integral lifting device to can realize the integral lifting of photovoltaic support, in order to improve efficiency of construction and security.

In order to achieve the above object, the present invention provides the following technical solutions:

a photovoltaic support integral hoisting tool comprises:

the hoisting frame is provided with a hanging point for hanging a hoisting rope;

the telescopic beam assembly at least comprises a set of, the telescopic beam assembly including set up in first telescopic beam and the flexible roof beam of second on the hoist and mount frame, the flexible roof beam of first telescopic beam and second is arranged relatively, and is located same straight line, first telescopic beam be used for with the support sloping of photovoltaic support one end be connected, the flexible roof beam of second be used for with the other end of support sloping is connected.

Optionally, in the above photovoltaic support integral lifting device, the first telescopic beam and the second telescopic beam each include:

the fixed sleeve is arranged on the hoisting frame;

the telescopic pipe sleeve is inserted into the fixed sleeve in a sliding manner, and the end part of the bracket oblique beam is inserted into a pipe hole of the telescopic pipe sleeve;

and the telescopic driving piece is arranged on the fixed sleeve and used for driving the telescopic pipe sleeve to slide along the fixed sleeve.

Optionally, in the integral photovoltaic support hoisting tool, the telescopic driving part is a hydraulic oil cylinder, a cylinder body of the hydraulic oil cylinder is arranged on the fixed sleeve, and a piston rod of the hydraulic oil cylinder is connected with the telescopic pipe sleeve.

Optionally, in the integral photovoltaic support hoisting tool, two ends of the telescopic pipe sleeve are exposed out of the fixed sleeve, a first end of the telescopic pipe sleeve is used for being inserted into an end of the support sloping beam, and a piston rod of the hydraulic oil cylinder is connected with a second end of the telescopic pipe sleeve.

Optionally, in the integral photovoltaic bracket hoisting tool, a limiting baffle is arranged in a pipe hole of the telescopic pipe sleeve, and the limiting baffle is used for limiting the insertion depth of the bracket oblique beam.

Optionally, in the integral photovoltaic bracket hoisting tool, cushion pads are arranged on the inner wall and the outer wall of one end, used for being inserted into the bracket oblique beam, of the telescopic pipe sleeve.

Optionally, in the above photovoltaic support integral hoisting tool, the hoisting frame includes:

the hanging point is arranged on the horizontal frame;

the first longitudinal beam is arranged on the first side of the horizontal frame, and the first telescopic beam is arranged on the first longitudinal beam;

and the second longitudinal beam is arranged on the second side of the horizontal frame, and the second telescopic beam is arranged on the second longitudinal beam.

Optionally, in the photovoltaic bracket integral hoisting tool, the length of the first longitudinal beam is smaller than that of the second longitudinal beam, so that an included angle between the first longitudinal beam and the horizontal frame is the same as an included angle between the bracket oblique beam and a horizontal plane.

Optionally, in the photovoltaic bracket integral hoisting tool, the horizontal frame is parallel to the horizontal plane.

Optionally, in the above photovoltaic bracket integral hoisting tool, reinforcing diagonal bracing beams are respectively disposed between the horizontal frame and the first longitudinal beam, and between the horizontal frame and the second longitudinal beam.

The utility model provides a photovoltaic support integral hoisting tool through the lifting rope with hang the being connected of point, can wholly hoist the flexible beam subassembly that lifting frame and it set up on it. The telescopic beam assembly comprises a first telescopic beam and a second telescopic beam which are arranged on the hoisting frame, and the first telescopic beam and the second telescopic beam are oppositely arranged and are positioned on the same straight line.

In actual use, after the photovoltaic support integral hoisting tool is lowered to a proper position, the first telescopic beam and the second telescopic beam respectively correspond to two ends of the support oblique beam of the photovoltaic support, and then the first telescopic beam and the second telescopic beam extend out, so that two ends of the support oblique beam are respectively inserted into the first telescopic beam and the second telescopic beam, and the photovoltaic support integral hoisting tool are reliably connected. The whole photovoltaic support can be lifted by traction of the lifting rope. The utility model discloses simple structure, the atress route is clear and definite, low in manufacturing cost, very reliable with being connected of photovoltaic support moreover, the operation is also very simple and convenient in the use, convenient to use and later stage dimension guarantor.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a front view of a photovoltaic bracket integral hoisting tool provided by an embodiment of the present invention;

fig. 2 is a top view of the photovoltaic bracket integral hoisting tool provided by the embodiment of the present invention;

fig. 3 is a side view of the photovoltaic bracket integral hoisting tool provided by the embodiment of the present invention;

fig. 4 is a side view of the photovoltaic support integral hoisting tool provided by the embodiment of the present invention after a lifting rope is removed;

fig. 5 is a side view of the photovoltaic support integral hoisting tool provided by the embodiment of the present invention when separated from the photovoltaic support;

fig. 6 is a side view of the photovoltaic support integral hoisting tool provided by the embodiment of the present invention after being inserted into a photovoltaic support;

fig. 7 is a schematic view of a partial structure of a telescopic pipe sleeve according to an embodiment of the present invention.

The meaning of the various reference symbols in the figures is as follows:

101 is a hoisting frame, 1011 is a first longitudinal beam, 1012 is a second longitudinal beam, 1013 is a horizontal frame, 1014 is a hanging point, 102 is a lifting rope, 103 is a fixed sleeve, 104 is a telescopic pipe sleeve, 1041 is a limit baffle, 105 is a telescopic driving piece, 106 is a photovoltaic bracket, and 1061 is a bracket oblique beam.

Detailed Description

The core of the utility model lies in providing a photovoltaic support integral hoisting tool to can realize the integral hoisting of photovoltaic support, with improvement efficiency of construction and security.

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in FIGS. 1-4, the embodiment of the utility model discloses a photovoltaic support integral hoisting tool, its characterized in that, including hoist and mount frame 101 and telescopic beam subassembly.

The hoisting frame 101 is a main supporting frame of the integral hoisting tool for the photovoltaic support, and the structure of the hoisting frame can be any, so long as the telescopic beam assembly can be fixed. The hoisting frame 101 is provided with a hanging point 1014 for hanging the hoisting rope 102. As shown in fig. 2, four hanging points 1014 can be arranged and uniformly distributed around the center of gravity of the hoisting frame 101, so that when hoisting is performed through the hoisting rope 102, the hoisting frame 101 can be ensured to be stable and not to be deflected in the hoisting process.

The telescopic beam assemblies at least comprise one group, the telescopic beam assemblies on the hoisting frame 101 can be arranged as required, and specifically can be arranged according to the number of the bracket inclined beams 1061 of the photovoltaic bracket 106, for example, if the photovoltaic bracket 106 has four bracket inclined beams 1061, four groups of telescopic beam assemblies can be arranged on the hoisting frame 101. It should be noted that even if the photovoltaic support 106 has four support oblique beams 1061, the hoisting frame 101 may be provided with only one or two sets of telescopic beam assemblies. Of course, a greater number of telescopic beam assemblies may be provided on the lifting frame 101, so that a plurality of photovoltaic supports 106 may be lifted simultaneously.

The telescopic beam assembly comprises a first telescopic beam and a second telescopic beam which are arranged on the hoisting frame 101, the first telescopic beam and the second telescopic beam are oppositely arranged and are positioned on the same straight line, the first telescopic beam is used for being connected with one end of a support oblique beam 1061 of the photovoltaic support 106, and the second telescopic beam is used for being connected with the other end of the support oblique beam 1061.

The utility model provides a photovoltaic support integral hoisting tool through lifting rope 102 and the connection of hanging 1014, can be with the whole hoisting frame 101 and the flexible beam subassembly that sets up on it hoist. The telescopic beam assembly comprises a first telescopic beam and a second telescopic beam which are arranged on the hoisting frame 101, and the first telescopic beam and the second telescopic beam are oppositely arranged and are positioned on the same straight line.

In practical use, after the photovoltaic support integral hoisting tool is lowered to a proper position, the first telescopic beam and the second telescopic beam are respectively corresponding to two ends of the support oblique beam 1061 of the photovoltaic support 106, and then the first telescopic beam and the second telescopic beam are extended out, so that two ends of the support oblique beam 1061 are respectively inserted into the first telescopic beam and the second telescopic beam, and the photovoltaic support 106 and the photovoltaic support integral hoisting tool are reliably connected. The entire photovoltaic support 106 (which may contain photovoltaic panels) can now be lifted by pulling with the lifting rope 102. The utility model discloses simple structure, the atress route is clear and definite, low in manufacturing cost, moreover with photovoltaic support 106 be connected very reliably, the operation is also very simple and convenient in the use, convenient to use and later stage dimension guarantor.

As shown in fig. 4, in an embodiment of the present invention, the first telescopic beam and the second telescopic beam have the same structure, and each of the first telescopic beam and the second telescopic beam includes a fixed sleeve 103, a telescopic pipe sleeve 104, and a telescopic driving member 105.

Wherein, the fixed sleeve 103 is arranged on the hoisting frame 101, the telescopic pipe sleeve 104 is slidably inserted into the fixed sleeve 103, and under the action of external force, the telescopic pipe sleeve 104 can be driven to slide along the fixed sleeve 103 so as to adjust the length of the telescopic pipe sleeve 104 extending out of the fixed sleeve 103, i.e. the distance between the two telescopic pipe sleeves 104 of the telescopic beam assembly. The end of the bracket stringer 1061 is adapted to be inserted into the bore of the telescoping tube sleeve 104.

The telescopic driving member 105 is disposed on the fixed sleeve 103, and is used for driving the telescopic pipe sleeve 104 to slide along the fixed sleeve 103. As shown in fig. 5, after the photovoltaic support integral lifting tool is lowered to a proper position, the telescopic pipe sleeves 104 of the first telescopic beam and the telescopic pipe sleeves 104 of the second telescopic beam are respectively corresponding to two ends of the support inclined beam 1061 of the photovoltaic support 106.

As shown in fig. 6, the telescopic pipe sleeve 104 of the first telescopic beam is pushed out to the end where the telescopic pipe sleeve 104 is sleeved on the bracket sloping beam 1061 by the telescopic driving member 105 of the first telescopic beam, and the telescopic pipe sleeve 104 of the second telescopic beam is pushed out to the end where the telescopic pipe sleeve 104 is sleeved on the bracket sloping beam 1061 by the telescopic driving member 105 of the second telescopic beam, so as to realize the reliable connection between the photovoltaic bracket 106 and the integral photovoltaic bracket hoisting tool, and then the photovoltaic bracket is hoisted to a proper position.

Specifically, the telescopic driving member 105 may be a hydraulic cylinder, a cylinder body of the hydraulic cylinder is disposed on the fixed sleeve 103, and a piston rod of the hydraulic cylinder is connected to the telescopic pipe sleeve 104. Specifically, the fixing sleeve 103 may be provided with a fixing lug for fixing the cylinder body of the hydraulic cylinder, and the cylinder body of the hydraulic cylinder is fixed to the fixing lug through a pin. The connection mode of the piston rod of the hydraulic oil cylinder and the telescopic pipe sleeve 104 can also adopt the same fixing mode as the cylinder body of the hydraulic oil cylinder.

It should be noted that the telescopic driving member 105 may be an air cylinder, a linear motor, a screw mechanism, etc., and the specific structural form of the telescopic driving member 105 is not limited as long as the telescopic pipe sleeve 104 can be driven to move.

In order to prevent the piston rod of the telescopic drive 105 from interfering with the photovoltaic support 106 when it is extended. In an embodiment of the present invention, both ends of the telescopic tube sleeve 104 are exposed out of the fixing sleeve 103, and the first end of the telescopic tube sleeve 104 is used for being inserted into the end of the bracket sloping 1061, and the piston rod of the hydraulic cylinder is connected to the second end of the telescopic tube sleeve 104. Namely, when a piston rod of the hydraulic oil cylinder extends out, the first end of the telescopic pipe sleeve 104 is driven to move towards the direction of the fixed sleeve 103, so that the distance between the two telescopic pipe sleeves 104 is increased, and therefore preparation is made before hoisting, or the photovoltaic support 106 which is hoisted in place is separated from the integral hoisting tool for the photovoltaic support. When a piston rod of the hydraulic oil cylinder retracts, the first end of the telescopic pipe sleeve 104 is driven to move towards the direction away from the fixed sleeve 103 so as to reduce the distance between the two telescopic pipe sleeves 104, and therefore the two telescopic pipe sleeves 104 are sleeved at the two ends of the support oblique beam 1061, and the photovoltaic support 106 is reliably connected with the photovoltaic support integral hoisting tool.

As shown in fig. 7, in order to prevent the end of the bracket stringer 1061 from being inserted too deeply into the telescopic tube housing 104, which is disadvantageous to the withdrawal of the telescopic tube housing 104. In this embodiment, a limiting baffle 1041 is disposed in the tube hole of the telescopic tube sleeve 104, and the limiting baffle 1041 is used for limiting the insertion depth of the bracket oblique beam 1061. The position of the limit baffle 1041 can be set by a person skilled in the art according to requirements to ensure that the bracket oblique beam 1061 is inserted to a proper depth. The position of the limit baffle 1041 should be able to ensure the hoisting safety, avoid the bracket sloping 1061 to be separated from the telescopic pipe sleeve 104 during the hoisting process, and avoid the influence on the hoisting efficiency due to too deep insertion.

Since there is inevitably a collision during the insertion of the bracket stringer 1061 and the telescopic tube 104, the bracket stringer 1061 and the telescopic tube 104 are damaged in order to prevent the collision. In one embodiment of the present invention, the inner and outer walls of the end of the telescoping tube sleeve 104 for insertion into the bracket stringer 1061 are provided with a bumper pad. When the telescopic pipe sleeve 104 and the bracket sloping beam 1061 approach each other, if the telescopic pipe sleeve 104 and the bracket sloping beam 1061 are not aligned effectively, and collision occurs, under the action of the cushion pad, the deformation of the telescopic pipe sleeve 104 and the bracket sloping beam 1061 caused by hard collision can be avoided, and the influence on normal use can be avoided.

As shown in fig. 3, in an embodiment of the present invention, the lifting frame 101 comprises a horizontal frame 1013, a first longitudinal beam 1011 and a second longitudinal beam 1012. The hanging point 1014 is arranged on the horizontal frame 1013, and the horizontal frame 1013 is ensured to be in a horizontal state as much as possible in the hoisting process.

The first longitudinal beam 1011 is arranged on a first side of the horizontal frame 1013, and the first telescopic beam is arranged on the first longitudinal beam 1011; the second longitudinal beam 1012 is disposed on a second side of the horizontal frame 1013, and the second telescopic beam is disposed on the second longitudinal beam 1012.

In order to increase the strength of the first telescopic beam, reinforcing plates can be arranged on the first telescopic beam and the first longitudinal beam 1011 to prevent the first telescopic beam from failing due to the torque of the first telescopic beam during hoisting. Similarly, a reinforcing plate may be provided on the second telescoping beam and the second longitudinal beam 1012 to prevent the second telescoping beam from failing due to the torque applied to the second telescoping beam during hoisting.

Further, the length of the first longitudinal beam 1011 is smaller than the length of the second longitudinal beam 1012, so that the angle between the first longitudinal beam 1011 and the horizontal frame 1013 is the same as the angle between the bracket stringer 1061 and the horizontal plane. So set up, horizontal frame 1013 is parallel with the horizontal plane when can guaranteeing to hoist, and the state of photovoltaic support 106 when hoist simultaneously, the state after the installation is the same, and the angle of support sloping 1061 when hoist is the same with the angle after photovoltaic support 106 installs, can guarantee that the support post of photovoltaic support 106 is vertical state when hoist, guarantees to move the in-process, and the focus of photovoltaic support 106 is unchangeable, improves the stability of operation.

Further, reinforcing diagonal bracing beams are arranged between the horizontal frame 1013 and the first longitudinal beam 1011, and between the horizontal frame 1013 and the second longitudinal beam 1012, so as to improve the strength of the hoisting frame 101.

It should be noted that, in the present specification, the embodiments are all described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments may be referred to each other.

As used in this application and in the claims, the terms "a," "an," "the," and/or "the" are not intended to be inclusive in the singular, but rather are intended to include the plural, unless the context clearly dictates otherwise. In general, the terms "comprises" and "comprising" merely indicate that steps and elements are included which are explicitly identified, that the steps and elements do not form an exclusive list, and that a method or apparatus may include other steps or elements. An element defined by the phrase "comprising a component of ' 8230 ' \8230; ' does not exclude the presence of additional identical elements in the process, method, article, or apparatus that comprises the element.

In the following, the terms "first", "second" are used for descriptive purposes only and are not to be understood as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature.

The principles and embodiments of the present invention have been explained herein using specific examples, and the above descriptions of the embodiments are only used to help understand the core concepts of the present invention. It should be noted that, for those skilled in the art, without departing from the principle of the present invention, the present invention can be further modified and modified, and such modifications and modifications also fall within the protection scope of the appended claims.

Claims (10)

1. The utility model provides a photovoltaic support integral hoisting tool which characterized in that includes:

a hoisting frame (101) provided with a hanging point (1014) for hanging a hoisting rope (102);

the telescopic beam assembly at least comprises a group, the telescopic beam assembly comprises a first telescopic beam and a second telescopic beam, the first telescopic beam and the second telescopic beam are arranged on the hoisting frame (101) oppositely and located on the same straight line, the first telescopic beam is used for being connected with one end of a support oblique beam (1061) of the photovoltaic support (106), and the second telescopic beam is used for being connected with the other end of the support oblique beam (1061).

2. The photovoltaic support integral hoisting tool of claim 1, wherein the first and second telescoping beams each comprise:

the fixed sleeve (103) is arranged on the hoisting frame (101);

the telescopic pipe sleeve (104) is slidably inserted into the fixed sleeve (103), and the end part of the bracket oblique beam (1061) is inserted into a pipe hole of the telescopic pipe sleeve (104);

and the telescopic driving piece (105) is arranged on the fixed sleeve (103) and is used for driving the telescopic pipe sleeve (104) to slide along the fixed sleeve (103).

3. The photovoltaic bracket integral hoisting tool is characterized in that the telescopic driving part (105) is a hydraulic oil cylinder, a cylinder body of the hydraulic oil cylinder is arranged on the fixed sleeve (103), and a piston rod of the hydraulic oil cylinder is connected with the telescopic pipe sleeve (104).

4. The photovoltaic support integral hoisting tool as claimed in claim 3, wherein both ends of the telescopic pipe sleeve (104) are exposed out of the fixed sleeve (103), a first end of the telescopic pipe sleeve (104) is used for being inserted into an end of the support oblique beam (1061), and a piston rod of the hydraulic oil cylinder is connected with a second end of the telescopic pipe sleeve (104).

5. The photovoltaic support integral hoisting tool as claimed in claim 2, wherein a limit baffle (1041) is arranged in the pipe hole of the telescopic pipe sleeve (104), and the limit baffle (1041) is used for limiting the insertion depth of the support oblique beam (1061).

6. The photovoltaic support integral hoisting tool as claimed in claim 2, wherein the telescopic pipe sleeve (104) is provided with a buffer pad on the inner wall and the outer wall of the end for inserting the support oblique beam (1061).

7. Photovoltaic support integral hoisting tool according to any one of claims 1-6, wherein the hoisting frame (101) comprises:

a horizontal frame (1013), the hang point (1014) being arranged on the horizontal frame (1013);

a first longitudinal beam (1011) disposed on a first side of the horizontal frame (1013), the first telescoping beam being disposed on the first longitudinal beam (1011);

and a second longitudinal beam (1012) disposed on a second side of the horizontal frame (1013), wherein the second telescopic beam is disposed on the second longitudinal beam (1012).

8. Photovoltaic support integral hoisting tool according to claim 7, characterized in that the length of the first longitudinal beam (1011) is smaller than the length of the second longitudinal beam (1012) so that the angle between the first longitudinal beam (1011) and the horizontal frame (1013) is the same as the angle between the support stringer (1061) and the horizontal plane.

9. Photovoltaic support integral hoisting tool according to claim 8, characterized in that the horizontal frame (1013) is parallel to the horizontal plane when hoisted.

10. Photovoltaic support integral hoisting tool according to claim 7, characterized in that a reinforcing raker beam is arranged between the horizontal frame (1013) and the first longitudinal beam (1011) and between the horizontal frame (1013) and the second longitudinal beam (1012).

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