CN219826032U - Scaffold for mountain region photovoltaic construction - Google Patents

Abstract

The utility model provides a scaffold for mountain photovoltaic construction, and relates to the technical field of photovoltaic construction equipment. The scaffold for mountain region photovoltaic construction includes plummer, four telescopic landing legs and first enhancement subassembly. One end of the supporting leg is rotationally connected with the bearing table; two ends of the first reinforcing component are movably connected between the supporting leg and the bearing table; the scaffold has an unfolding state and a folding state, in the unfolding state, four supporting legs are unfolded to support the bearing table, and the first reinforcing component is supported between the supporting legs and the bearing table and forms a triangular stable structure; in the folded state, the support legs and the first reinforcing component are linked to rotate towards the bearing table to fold. The utility model can solve the problems of difficult scaffold erection, poor stability and safety in the mountain photovoltaic construction process in the prior art, and has the effects of simple and convenient erection, safety, stability, folding storage and portability.

Description

Scaffold for mountain region photovoltaic construction

Technical Field

The utility model relates to the technical field of photovoltaic construction equipment, in particular to a scaffold for mountain photovoltaic construction.

Background

With the development of photovoltaic industry, the demand of the photovoltaic power station land is gradually increased, and the photovoltaic power station land can only be generally selected to be located on unused lands such as barren mountains and beaches. Most photovoltaic power stations currently select unused land for construction in mountainous areas. With the rapid increase of the number of photovoltaic power stations built in the years, mountains with better orientations and terrains are difficult to find, site topographic conditions of the power stations are worse, and building difficulty is higher.

In the photovoltaic construction process, the photovoltaic panel needs to be installed by using a scaffold. In mountain photovoltaic field areas, more rugged and soft areas exist, and the topography are more complicated. In the mountain region photovoltaic board work progress, because the topography is complicated, the topography is uneven, and ordinary scaffold frame is set up the difficulty, and is difficult to steadily use, low to complicated topography suitability, the problem of easily taking place to empty, the security is poor, and installation and transport waste time and energy, influence the operating efficiency, further increase the construction degree of difficulty.

Disclosure of Invention

The technical problem to be solved by the utility model is to overcome the defects of difficult scaffold erection, poor stability and poor safety in the mountain photovoltaic construction process in the prior art, thereby providing the scaffold for mountain photovoltaic construction.

In order to solve the problems, the utility model provides a scaffold for mountain photovoltaic construction, which comprises a bearing table, four telescopic supporting legs and a first reinforcing component; one end of the supporting leg is rotationally connected with the bearing table; two ends of the first reinforcing component are movably connected between the supporting leg and the bearing table; the scaffold has an unfolding state and a folding state, in the unfolding state, four supporting legs are unfolded to support the bearing table, and the bearing table, the supporting legs and the first reinforcing component form a triangular stable structure; in the folded state, the support legs and the first reinforcing component are linked to rotate towards the bearing table to fold.

Optionally, the landing leg includes mutual telescopic connection's fixed section and at least one flexible section, and fixed section rotates with the plummer to be connected, is equipped with the hasp that is used for restricting flexible section telescopic movement between fixed section and the flexible section, or between the adjacent flexible section.

Optionally, the hasp includes presses the knot, presses the knot to include to press cover and clamp plate, presses the cover suit on the landing leg, and clamp plate and pressure cover rotate to be connected, and when the clamp plate rotated to laminating pressure cover, the pressure cover was pressed two adjacent flexible sections to restrict the flexible motion between two adjacent flexible sections.

Optionally, the included angle between the supporting leg and the bearing table is greater than 90 degrees, the first reinforcing component comprises at least two first reinforcing rods which are movably connected, and in the unfolded state, the plurality of first reinforcing rods are unfolded to be collinear, and opposite tensile forces are applied to the bearing table and the supporting leg; in the folded state, the first reinforcing rod is rotatably accommodated between the supporting leg and the bearing table.

Optionally, a second reinforcing component is connected between any two adjacent supporting legs, the second reinforcing component comprises at least two movably connected second reinforcing rods, and in the unfolded state, the plurality of second reinforcing rods are unfolded to be collinear, and opposite tensile forces are applied to the two supporting legs.

Optionally, the second reinforcing component comprises two second reinforcing rods, the two second reinforcing rods are rotationally connected through a second rotating shaft, and the second rotating shaft is parallel to the bearing table; the two ends of the second reinforcing component are respectively connected with the fixed sections of the two supporting legs in a rotating way.

Optionally, the bearing platform is provided with at least two hanging structures, and two or more hanging structures are distributed at intervals relative to the bearing platform.

Optionally, the bearing platform comprises a first bearing area and a second bearing area which are arranged along the length direction of the bearing platform, the first bearing area and the second bearing area are rotationally connected, and in an unfolding state, the bearing surface of the first bearing area is flush with the bearing surface of the second bearing area; in the folded state, the bearing surface of the first bearing area is folded in half relative to the second bearing area, and the supporting leg and the first reinforcing component are contained between the first bearing area and the second bearing area.

Optionally, the two hanging structures are respectively arranged at the edges of the first bearing area and the second bearing area, and the hanging structures are suitable for being connected with the mountain photovoltaic bracket through the hanging parts.

Optionally, the bearing surface of the bearing table is suitable for placing the photovoltaic panel, and an anti-slip structure is arranged on the bearing surface.

The utility model has the following advantages:

1. by utilizing the technical scheme of the utility model, the support leg support device is used for construction operation of a mountain photovoltaic bracket and a photovoltaic panel, when the support leg support device is used, four support legs are unfolded to support a bearing table, a first reinforcing component is unfolded in a linkage way, the support legs are adapted to mountain terrains through telescopic adjustment, the bearing table is leveled, and a worker can stand on the bearing table to build the photovoltaic panel; after the construction is finished, the worker leaves the bearing table, shortens the telescopic supporting leg, rotates the supporting leg to enable the telescopic supporting leg to be close to the bearing table for folding and storing, and in the storing process, the first reinforcing component is linked and stored. The scaffold for mountain photovoltaic construction provided by the embodiment of the utility model has the advantages of simple structure, convenience in operation and easiness in erection, can adapt to operation sites with different conditions, and provides convenience for building the photovoltaic in mountain. Due to the arrangement of the first reinforcing component, in the unfolded state, a triangular stable structure is formed among the first reinforcing component, the bearing table and the supporting legs, so that the support is safe and stable. The scaffold support leg for mountain region photovoltaic is scalable, rotatable, is convenient for accomodate and carry.

2. The lock catch is arranged between the fixed section and the telescopic section of the supporting leg, when the supporting leg is extended to the required length, the fixed section and the telescopic section or adjacent telescopic sections are prevented from relative movement through the lock catch, and the safety performance of the scaffold for mountain photovoltaic construction in the use process is further improved.

3. Through setting up the second and strengthen the subassembly for under the expansion state, receive the pulling force effect of second and strengthen the subassembly between two landing legs, make the mountain region photovoltaic scaffold for construction firm more, further improve security performance.

4. Through setting up two at least articulations structure, scaffold frame is used in mountain region photovoltaic construction in the use, will articulate the structure and articulate on mountain region photovoltaic support through the articulated elements, prevent that scaffold frame from taking place to empty, further improve the security performance, provide the guarantee for constructor's personal safety.

5. The plummer sets up first bearing area and second bearing area along length direction, and rotates between first bearing area and the second bearing area to be connected for the plummer is collapsible accomodate, further reduces the volume of mountain region photovoltaic construction scaffold after accomodating, further improves the portability of scaffold. When the length of the first bearing area is equal to that of the second bearing area, the length of the bearing table in the folded state is half of that of the bearing table in the unfolded state, and the storage volume of the scaffold is greatly reduced.

6. The anti-slip structure is arranged on the bearing surface of the bearing table, so that an anti-slip effect is achieved, and when the photovoltaic panel is placed on the bearing surface of the bearing table, the photovoltaic panel can be prevented from being damaged by slipping.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are needed in the description of the embodiments or the prior art will be briefly described, and it is obvious that the drawings in the description below are some embodiments of the present utility model, and other drawings can be obtained according to the drawings without inventive effort for a person skilled in the art.

Fig. 1 shows a schematic structural view of a scaffold for mountain photovoltaic construction in an unfolded state according to an embodiment of the present utility model;

FIG. 2 shows a schematic view of a partial construction of a leg with a latch;

fig. 3 is a schematic structural view showing a scaffold for mountain photovoltaic construction in a storage state according to an embodiment of the present utility model;

FIG. 4 shows a schematic structural view of a rotary connection;

fig. 5 shows a schematic structural diagram of a scaffold for mountain photovoltaic construction according to an embodiment of the present utility model when connected to a photovoltaic bracket.

Reference numerals illustrate:

1. a carrying platform; 11. a first carrying area; 12. a second carrying area; 2. a support leg; 21. a fixed section; 22. a telescoping section; 23. locking; 231. pressing the sleeve; 232. a pressing plate; 3. a first stiffening component; 31. a first reinforcing rod; 32. a first rotating shaft; 33. a hinge base; 4. a second reinforcement assembly; 41. a second reinforcing rod; 5. a hitching structure; 6. an anti-slip structure; 7. a handle; 10. a scaffold; 20. a photovoltaic support; 30. and a hanging piece.

Detailed Description

The following description of the embodiments of the present utility model will be made apparent and fully in view of the accompanying drawings, in which some, but not all embodiments of the utility model are shown. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

In addition, the technical features of the different embodiments of the present utility model described below may be combined with each other as long as they do not collide with each other.

For the purpose of illustrating the concepts of the utility model, the drawings and detailed description are to be regarded as illustrative in nature and not as restrictive.

Example 1

A scaffold 10 for mountain photovoltaic construction, referring to fig. 1-5, comprises a carrying platform 1, four telescopic legs 2 and a first reinforcing assembly 3. Wherein, one end of the supporting leg 2 is rotationally connected with the bearing table 1; both ends of the first reinforcement member 3 are movably connected between the support legs 2 and the carrying platform 1; the scaffold 10 has an unfolded state in which the four legs 2 are unfolded to support the carrying platform 1, and a folded state in which the carrying platform 1, the legs 2 and the first reinforcing assembly 3 form a triangular stable structure; in the folded state, the leg 2 and the first reinforcement member 3 are linked, and are folded rotatably toward the loading table 1.

By utilizing the technical scheme of the utility model, the support frame is used for construction operation of the mountain photovoltaic bracket 20 and the photovoltaic panel, when the support frame is used, the four support legs 2 are unfolded to support the bearing table 1, the first reinforcing component 3 is unfolded in a linkage way, the support legs 2 are adapted to mountain terrains through telescopic adjustment of the support legs 2, the bearing table 1 is leveled, and workers can stand on the bearing table 1 to build the photovoltaic panel; after the construction is finished, the worker leaves the bearing table 1, shortens the telescopic supporting leg 2, rotates the supporting leg 2 to enable the telescopic supporting leg to be close to the bearing table 1 and fold and store, and in the storage process, the first reinforcing component 3 is linked and stored. The scaffold 10 for mountain photovoltaic construction provided by the embodiment of the utility model has the advantages of simple structure, convenience in operation and easiness in erection, can adapt to operation sites with different conditions, and provides convenience for building the photovoltaic in the mountain. Due to the arrangement of the first reinforcing component 3, in the unfolded state, a triangular stable structure is formed among the bearing table 1, the supporting legs 2 and the first reinforcing component 3, so that the bearing table is safe and stable. The landing leg 2 of the mountain region photovoltaic scaffold 10 is telescopic and rotatable, and is convenient to store and carry.

Optionally, the supporting leg 2 comprises a fixing section 21 and at least one telescopic section 22 which are connected with each other in a telescopic manner, the fixing section 21 is rotationally connected with the bearing table 1, and a lock catch 23 for limiting telescopic movement of the telescopic section 22 is arranged between the fixing section 21 and the telescopic section 22 or between adjacent telescopic sections 22. Specifically, the first end of the fixed section 21 is rotatably connected to the carrying platform 1, and the second end of the fixed section 21 is telescopically connected to the telescopic section 22. As an alternative embodiment, the fixed section 21 and the telescopic section 22 are in a tubular structure, the telescopic section 22 is telescopically inserted into the fixed section 21, and between adjacent telescopic sections 22, the telescopic section 22 far from the fixed section 21 is inserted into the telescopic section 22 near the fixed section 21. Specifically, the leg 2 has a cylindrical structure, and the diameter of the expansion section 22 gradually becomes smaller in a direction away from the fixed section 21. When the scaffold 10 is built in a mountain, the four legs 2 are unfolded to support the bearing table 1, and then the length of each leg 2 is adjusted according to the topography. Specifically, the length of the leg 2 at the high topography is smaller than the length of the leg 2 at the low topography, thereby leveling the bearing table 1. After the support leg 2 is adjusted to a proper length, the support leg is locked by the lock catch 23, so that telescopic movement between the fixed section 21 and the telescopic section 22 and between the adjacent telescopic sections 22 is prevented, and the current length of the support leg 2 is kept.

The lock catch 23 is arranged between the fixed section 21 and the telescopic section 22 of the supporting leg 2, when the supporting leg 2 stretches to the required length, the locking is performed through the lock catch 23, the fixed section 21 and the telescopic section 22 are prevented from moving relatively, and the safety performance of the scaffold 10 for mountain photovoltaic construction in the use process is further improved.

Optionally, in this embodiment, referring to fig. 2, the lock catch 23 includes a pressing buckle, where the pressing buckle includes a pressing sleeve 231 and a pressing plate 232, where the pressing sleeve 231 is sleeved on the supporting leg 2, the pressing plate 232 is rotationally connected with the pressing sleeve 231, and when the pressing plate 232 rotates to fit the pressing sleeve 231, the pressing sleeve 231 compresses the two adjacent telescopic sections 22 to limit the telescopic movement between the two adjacent telescopic sections 22. As one of the embodiments, in this embodiment, the process of rotating the pressing plate 232 toward the direction approaching the leg 2 is a locking process, and the length of the leg 2 is not adjustable during locking; the process of rotating the pressing plate 232 towards the direction away from the supporting leg 2 is an unlocking process, after unlocking, the length of the supporting leg 2 is adjustable, when a construction site is replaced, the length of the supporting leg 2 can be adjusted according to the terrain, or the telescopic section 22 is retracted, and the folding type folding leg is stored in a folded state and is convenient to carry. The stepless adjustment of the supporting leg 2 can be realized by adopting the pressing buckle, and the supporting leg can be stretched to any length. The press buckle is realized by the prior art, and is not limited herein.

Of course, other structures of the prior art that can be used to lock and unlock the shackle 23 can be used.

Optionally, the included angle between the supporting leg 2 and the bearing table 1 is greater than 90 degrees, the first reinforcement component 3 comprises at least two movably connected first reinforcement rods 31, and in the unfolded state, the plurality of first reinforcement rods 31 are unfolded to be collinear, and opposite pulling forces are applied to the bearing table 1 and the supporting leg 2; in the folded state, the first reinforcing bar 31 is rotatably received between the leg 2 and the loading table 1.

Specifically, the supporting legs 2 and the bearing table 1 are connected through a first hinge structure, the supporting legs 2 can rotate towards two directions, the bearing table 1 is of a rectangular structure in the structure shown in fig. 1, and the supporting legs 2 can rotate along the length direction of the bearing table 1 or along the width direction of the bearing table 1. Fig. 1 is a schematic structural diagram of the scaffold 10 in the unfolded state of the present embodiment, which is changed from the unfolded state to the folded state, and the four support legs 2 are rotated in two directions, namely, the four support legs 2 are rotated in the width direction of the carrying platform 1, so that the two support legs 2 at the same end of the carrying platform 1 are retracted to a position close to parallel to each other, and then are rotated and folded in the length direction of the carrying platform 1, so that the four support legs 2 are accommodated in the attaching carrying platform 1. Optionally, the first hinge structure comprises a universal ball hinge.

Referring to fig. 1, in the present embodiment, the first reinforcing component 3 includes two first reinforcing rods 31, and the two first reinforcing rods 31 are rotatably connected by a second hinge structure, and the second hinge structure includes a first rotating shaft 32, where the first rotating shaft 32 is arranged parallel to the carrying platform 1. Specifically, referring to fig. 4, a hinge seat 33 is provided on the carrying platform 1 or the supporting leg 2, an axle hole is provided on an ear plate of the hinge seat 33, an axle hole is also provided at an end of the first reinforcing rod 31, the first reinforcing rod 31 is provided between the two ear plates, and a first rotating shaft 32 is inserted into the axle hole to rotationally connect the hinge seat 33 and the first reinforcing rod 31. Because there are two directions of rotation of the support leg 2 during folding, a movable gap is left between the shaft hole between the two first reinforcing rods 31 and the first rotating shaft 32, and a movable gap is left between the first reinforcing rods 31 and the two ear plates of the hinge seat 33, so that displacement along the width direction of the bearing table 1 is allowed to occur between the two first reinforcing rods 31 when the support leg 2 rotates along the width direction of the bearing table 1, and the two first reinforcing rods 31 rotate around the first rotating shaft 32 and are linked with the support leg 2 and are folded and accommodated at a position close to the bearing table 1 when the support leg 2 rotates along the length direction of the bearing table 1. In the unfolded state, the included angle between the supporting leg 2 and the carrying platform 1 is larger than 90 degrees, so that the two first reinforcing rods 31 of the first reinforcing assembly 3 are unfolded to be in a collinear state, and the carrying platform 1 and the supporting leg 2 are applied with a tensile force along the direction of the first reinforcing rods 31, so that the stability of the scaffold 10 in the use process is ensured.

Optionally, a second reinforcing component 4 is connected between any two adjacent support legs 2, the second reinforcing component 4 comprises at least two movably connected second reinforcing rods 41, and in the unfolded state, the plurality of second reinforcing rods 41 are unfolded to be collinear, and opposite pulling forces are applied to the two support legs 2. Since the angle between the legs 2 and the carrying platform 1 is larger than 90 °, when a worker stands on the carrying platform 1, the outwardly expanding pressure is applied to the legs 2, and the second reinforcing member 4 can apply a tensile force along the second reinforcing bar 41 to the two legs 2.

Through setting up second reinforcing component 4 for receive the pulling force effect of second reinforcing component 4 between two landing legs 2 under the expansion state, make mountain region photovoltaic construction scaffold 10 more firm, further improve the security performance.

Optionally, in this embodiment, referring to fig. 1, the second reinforcing component 4 includes two second reinforcing rods 41, and the two second reinforcing rods 41 are rotationally connected by a third hinge structure, where the third hinge structure includes a second rotation shaft, and the second rotation shaft is parallel to the bearing table 1; the two ends of the second reinforcing member 4 are rotatably connected to the fixed sections 21 of the two legs 2, respectively. When the leg 2 is turned in the width direction of the loading table 1, the two second reinforcing bars 41 are turned to form an included angle. As an alternative embodiment, one end of the second reinforcement bar 41 is rotatably connected to the fixed section 21 of the leg 2, and the other end of the second reinforcement bar 41 is telescopically connected to the other second reinforcement bar 41, wherein the telescopic connection comprises a sliding connection. When the legs 2 are received, the two legs connected by the second reinforcement member 4 are moved toward each other, and in the process, the two second reinforcement bars 41 are slidably contracted to bring the two legs 2 toward each other.

Optionally, the carrying platform 1 is provided with at least two hanging structures 5, and two or more hanging structures 5 are distributed at intervals with respect to the carrying platform 1.

Through setting up two at least hanging structure 5, in the scaffold frame 10 for mountain region photovoltaic construction in the use, will hang structure 5 and be connected through hanging piece 30 and mountain region photovoltaic support 20, prevent scaffold frame 10 emergence and empty, further improve the security performance, provide the guarantee for constructor's personal safety.

Optionally, the two hanging structures 5 are respectively arranged at edges of the first bearing area 11 and the second bearing area 12. Referring to fig. 1, in the present embodiment, two hanging structures 5 are provided and are disposed on opposite sides of the carrying platform 1. The hanging structure 5 comprises a hanging ring, the hanging piece 30 comprises a rope, one end of the rope is connected with the hanging ring in construction, and the other end of the rope is connected with the mountain photovoltaic bracket 20, as shown in fig. 4. Alternatively, the hanging ring can be made of flexible materials or rigid materials. Of course, as an alternative embodiment, the hanging ring may also be a hook.

Optionally, the carrying platform 1 includes a first carrying area 11 and a second carrying area 12 disposed along a length direction of the carrying platform 1, the first carrying area 11 and the second carrying area 12 are rotationally connected, and in an unfolded state, a carrying surface of the first carrying area 11 is flush with a carrying surface of the second carrying area 12; in the folded state, the first carrying area 11 is turned in half relative to the second carrying area 12, and the leg 2 and the first reinforcing member 3 are received between the first carrying area 11 and the second carrying area 12, as shown in fig. 3.

Optionally, a mutually matched limiting structure is arranged between the first bearing area 11 and the second bearing area 12, so that in the unfolded state, the bearing surface of the first bearing area 11 and the bearing surface of the second bearing area 12 are at the maximum unfolding angle when being coplanar.

Optionally, the limiting structure is disposed on opposite sides between the first bearing area 11 and the second bearing area 12. Specifically, in this embodiment, the first bearing area 11 has a first side surface near the second bearing area 12, a first included angle is formed between the first side surface and the first bearing surface of the first bearing area 11, the second bearing area 12 has a second side surface near the first bearing area 11, a second included angle is formed between the second side surface and the second bearing surface of the second bearing area 12, and the first included angle and the second included angle are complementary, so that in the unfolded state, when the first side surface and the second side surface abut, the first bearing surface and the second bearing surface are coplanar, and the included angle between the first bearing surface and the second bearing surface is 180 °.

The plummer 1 sets up first bearing zone 11 and second bearing zone 12, and rotates between first bearing zone 11 and the second bearing zone 12 to be connected for plummer 1 collapsible accomodates, further reduces the volume of mountain region photovoltaic construction scaffold 10 after accomodating, further improves scaffold 10's portability.

Four legs 2 are arranged in pairs in the first bearing area 11 and the second bearing area 12 respectively.

Optionally, the loading surface of plummer 1 is suitable for placing the photovoltaic board temporarily, makes things convenient for constructor to take and install the photovoltaic board. The bearing surface is provided with an anti-slip structure 6.

The anti-slip structure 6 is arranged on the bearing surface of the bearing table 1, and plays a role in preventing slipping, so that the photovoltaic panel can be prevented from slipping off and being damaged when the photovoltaic panel is placed on the bearing surface of the bearing table 1.

Optionally, the anti-slip structure 6 is any one or more of a stud, a cleat or a slip layer. The antiskid strip or the antiskid layer is made of rubber materials.

Optionally, two handles 7 are provided on the carrying platform 1. Specifically, in this embodiment, the two handles 7 are located at edges of the same side of the first carrying area 11 and the second carrying area 12, and in the folded state, the positions of the two handles 7 correspond to each other, so that the two handles are convenient to be extracted and carried in the folded state, as shown in fig. 3.

In this embodiment, the carrying platform 1 is rectangular. Of course, the carrying platform 1 can be adjusted to other shapes according to actual use requirements.

Optionally, the bearing platform 1 is a frame structure formed by connecting transverse rods and longitudinal rods in a staggered manner.

As an alternative embodiment, the carrying platform 1 is a plate-like structure.

Alternatively, the scaffold 10 is made of steel.

According to the above description, the present patent application has the following advantages:

1. the scaffold 10 can be used for construction operation of the mountain photovoltaic bracket 20 and the photovoltaic panel, the supporting legs 2 can be adjusted in a telescopic manner, the scaffold is suitable for various terrains, and the condition range of an application operation site is wide; the operation is simple and convenient, the erection difficulty is low, the safety and the stability are high, and the large-area popularization is convenient; the folding storage is convenient for carrying manually and using;

2. the appearance structure is simple, the material consumption is less, and the mechanical manufacturing cost is low.

It is apparent that the above examples are given by way of illustration only and are not limiting of the embodiments. Other variations or modifications of the above teachings will be apparent to those of ordinary skill in the art. It is not necessary here nor is it exhaustive of all embodiments. While still being apparent from variations or modifications that may be made by those skilled in the art are within the scope of the utility model.

Claims (10)

1. Scaffold frame for mountain region photovoltaic construction, characterized in that includes:

a carrying platform (1);

the four telescopic supporting legs (2), one end of each supporting leg (2) is rotationally connected with the bearing table (1);

-a first stiffening assembly (3), the two ends of the first stiffening assembly (3) being movably connected between the leg (2) and the carrying platform (1);

the scaffold has an unfolded state and a folded state, in the unfolded state, four support legs (2) are unfolded to support the bearing platform (1), and a triangular stable structure is formed among the bearing platform (1), the support legs (2) and the first reinforcing component (3); in the folded state, the supporting leg (2) and the first reinforcing component (3) are linked, and the supporting leg is folded towards the bearing table (1) in a rotating mode.

2. Scaffolding for mountain photovoltaic construction according to claim 1, characterized in that the leg (2) comprises a fixed section (21) and at least one telescopic section (22) telescopically connected to each other, the fixed section (21) being rotationally connected to the carrying platform (1), a lock catch (23) being arranged between the fixed section (21) and the telescopic section (22) or between adjacent telescopic sections (22) for limiting the telescopic movement of the telescopic section (22).

3. Scaffolding for photovoltaic construction in hills according to claim 2, characterized in that the lock catch (23) comprises a press buckle, the press buckle comprises a press sleeve (231) and a press plate (232), the press sleeve (231) is sleeved on the supporting leg (2), the press plate (232) is rotationally connected with the press sleeve (231), and when the press plate (232) rotates to be attached to the press sleeve (231), the press sleeve (231) compresses two adjacent telescopic sections (22) to limit telescopic movement between the two adjacent telescopic sections (22).

4. A scaffolding for mountain photovoltaic construction according to any one of claims 1-3, characterized in that the angle between the leg (2) and the carrying platform (1) is greater than 90 °, the first reinforcement assembly (3) comprising at least two movably connected first reinforcement bars (31), in the unfolded state a plurality of the first reinforcement bars (31) being unfolded to be co-linear, exerting opposing tensile forces on the carrying platform (1) and the leg (2); in the folded state, the first reinforcing rod (31) is rotatably accommodated between the support leg (2) and the carrying table (1).

5. A scaffold for mountain photovoltaic construction according to claim 2 or 3, characterized in that a second reinforcement assembly (4) is connected between any adjacent two of the legs (2), the second reinforcement assembly (4) comprising at least two movably connected second reinforcement bars (41), in the unfolded state a plurality of the second reinforcement bars (41) are unfolded to be co-linear, exerting opposing tensile forces on the two legs (2).

6. Scaffolding for mountain photovoltaic construction according to claim 5, characterized in that said second reinforcement assembly (4) comprises two said second reinforcement bars (41), the two said second reinforcement bars (41) being rotatably connected by a second rotation axis, said second rotation axis being parallel to said carrying platform (1); the two ends of the second reinforcing component (4) are respectively connected with the fixed sections (21) of the two supporting legs (2) in a rotating way.

7. A scaffold for mountain photovoltaic construction according to any of claims 1-3, characterized in that the carrying platform (1) is provided with at least two hitching structures (5), two or more hitching structures (5) being spaced apart with respect to the carrying platform (1).

8. Scaffolding for mountain photovoltaic construction according to claim 7, characterized in that the carrying platform (1) comprises a first carrying area (11) and a second carrying area (12) arranged in the longitudinal direction of the carrying platform (1), the first carrying area (11) and the second carrying area (12) being rotationally connected, in the unfolded state the carrying surfaces of the first carrying area (11) and the second carrying area (12) being flush; in the folded state, the first bearing area (11) is folded in half relative to the second bearing area (12), and the support leg (2) and the first reinforcing component (3) are contained between the first bearing area (11) and the second bearing area (12).

9. Scaffolding for mountain photovoltaic construction according to claim 8, characterized in that two of said hitching structures (5) are provided at the edges of said first carrying area (11) and said second carrying area (12), respectively, said hitching structures (5) being adapted to be connected to a mountain photovoltaic support (20) by hitching means (30).

10. Scaffolding for mountain photovoltaic construction according to any of the claims 1-3, characterized in that the bearing surface of the bearing table (1) is adapted for the placement of photovoltaic panels, on which bearing surface an anti-slip structure (6) is provided.