CN220556716U - Equipment bracket for photovoltaic power generation assembly - Google Patents

Abstract

The utility model relates to an equipment support for a photovoltaic power generation assembly. The device comprises a mounting frame, a panel mounting frame and a driving adjusting assembly, wherein the top of the mounting frame is provided with a mounting top plate, and two groups of driving adjusting assemblies are arranged on the mounting top plate; the active X-shaped frame is arranged between the panel mounting frame and the two groups of active adjusting components, the upper end part of the active X-shaped frame is pivotally connected with the panel mounting frame, and the lower end part of the active X-shaped frame is movably connected with the two groups of active adjusting components; the active X-shaped frame comprises two groups of X-shaped adjusting units, and a locking connecting unit is arranged between the two groups of X-shaped adjusting units and used for synchronously adjusting the positions of hinge points of the two groups of X-shaped adjusting units; the X-shaped adjusting unit further comprises an inner wall adjusting block and an outer arm adjusting block which are pivotally connected at the lower end parts of the two groups of X-shaped adjusting units, and the inner wall adjusting block and the outer arm adjusting block are respectively connected with the two groups of active adjusting components. The photovoltaic panel can be overturned and moved in two quadrants, so that the utilization rate of the photovoltaic panel is improved, and the working efficiency of the photovoltaic power generation assembly is improved.

Description

Equipment bracket for photovoltaic power generation assembly

Technical Field

The utility model belongs to the technical field of photovoltaic supports, and particularly relates to an equipment support for a photovoltaic power generation assembly.

Background

Photovoltaic power generation is based on the principle of photovoltaic effect, and solar energy is directly converted into electric energy by using a solar cell. The photovoltaic power generation system mainly comprises three parts of a solar panel assembly, a controller and an inverter, wherein the three parts are independently used or grid-connected power generation is realized.

In the application of the photovoltaic power generation technology, a required core device of the photovoltaic power generation system is a solar panel, a photovoltaic bracket is generally used for mounting the solar panel, and the photovoltaic bracket is a special bracket designed for placing, mounting and fixing the solar panel. The traditional photovoltaic bracket is generally formed by welding and fixedly connecting profiles made of aluminum alloy, carbon steel and stainless steel. The photovoltaic support is provided with an installation inclined plane, and the solar panel is fixedly installed on the installation inclined plane through bolts. In the actual working process, workers find that although the photovoltaic support can be used for installing the photovoltaic panel, the inclination angle of the photovoltaic panel is a fixed value and cannot be adjusted according to the seasonal periodic change of the sunlight angle, and in order to solve the problems, technicians design the support of the inclination angle of the photovoltaic panel.

However, the angle adjustment range of the improved support is smaller, the angle adjustment can be performed only in one quadrant, when the sun rotates to the back of the photovoltaic panel, the angle of the photovoltaic panel cannot be adjusted according to needs, the use ratio of the photovoltaic panel is seriously reduced, and the working efficiency of the photovoltaic power generation assembly is reduced.

Disclosure of Invention

The utility model provides a device bracket for a photovoltaic power generation assembly, which is reasonable in structural design and high in working efficiency, and solves the technical problems in the prior art. The photovoltaic panel can be overturned and moved in two quadrants, so that the utilization rate of the photovoltaic panel is improved, and the working efficiency of the photovoltaic power generation assembly is improved.

The utility model adopts the technical proposal for solving the technical problems in the prior art that: the equipment bracket for the photovoltaic power generation assembly comprises a mounting frame, a panel mounting frame and a panel mounting frame, wherein the mounting frame is provided with a mounting top plate at the top, two groups of active adjusting assemblies are symmetrically arranged on the mounting top plate, and the panel mounting frame is arranged above the active adjusting assemblies and is used for mounting a photovoltaic panel; the active X-shaped frame is arranged between the panel mounting frame and the two groups of active adjusting components, the upper end part of the active X-shaped frame is pivotally connected with the panel mounting frame, and the lower end part of the active X-shaped frame is movably connected with the two groups of active adjusting components; the active X-shaped frame comprises two groups of X-shaped adjusting units which are oppositely arranged, and a locking connecting unit is arranged between the two groups of X-shaped adjusting units and is used for synchronously adjusting the positions of hinge points of the two groups of X-shaped adjusting units; the X-shaped adjusting unit further comprises an inner wall adjusting block and an outer arm adjusting block which are pivotally connected at the lower end parts of the two groups of X-shaped adjusting units, and the inner wall adjusting block and the outer arm adjusting block are respectively connected with the two groups of active adjusting components.

The utility model has the advantages and positive effects that: the utility model provides a device bracket for a photovoltaic power generation assembly, which is formed by arranging two groups of X-shaped adjusting units and a locking connecting unit for synchronously adjusting the positions of hinge points of the two groups of X-shaped adjusting units, wherein the shapes of the two groups of X-shaped adjusting units can be adjusted according to the actual situation; through setting up two sets of initiative adjusting part, cooperation foretell initiative X type frame, the position of two lower extreme stabilizer blades of adjustable two sets of X type adjusting unit, cooperation locking connection unit simultaneously can realize the purpose of adjusting the inclination of panel mounting bracket in two quadrants, and then guarantees that photovoltaic panel can overturn between two opposite inclination, avoids photovoltaic panel unable make full use when the sun rotates to the photovoltaic panel back, has improved photovoltaic panel's rate of utilization, and then has improved photovoltaic power generation assembly's work efficiency.

Preferably: the X-shaped adjusting unit comprises an active inner arm and an active outer arm which are arranged in an X-shaped hinged manner, strip-shaped holes extending along the length direction of the active inner arm and the active outer arm are formed in the active inner arm and the active outer arm, and the locking connecting unit is arranged in the strip-shaped holes formed in the active inner arm and the active outer arm in a penetrating mode and is in locking connection with the X-shaped adjusting unit; the lower end part of the driving inner arm is pivotally connected with the inner wall adjusting block, and the upper end part of the driving inner arm is pivotally connected with the driving installation panel; the lower end part of the driving outer arm is pivotally connected with the outer arm adjusting block, and the upper end part of the driving outer arm is pivotally connected with the driving installation panel.

Preferably: the locking connection unit comprises a rear connection supporting rod arranged between the two groups of X-shaped adjustment units, and two ends of the rear connection supporting rod are respectively arranged in strip-shaped holes formed in the corresponding X-shaped adjustment units in a penetrating manner; the rear locking slide blocks are sleeved at the two ends of the rear connecting support rod respectively, the two groups of rear locking slide blocks are connected with the two groups of driving outer arms in a sliding mode respectively, and the rear locking slide blocks further comprise locking nuts which are screwed at the end portions of the rear connecting support rod and used for locking and connecting the corresponding rear locking slide blocks with the driving outer arms.

Preferably: the active adjusting assembly comprises an adjusting installation seat connected with the installation top plate, a plurality of groups of transversely arranged adjusting guide rails are fixedly connected on the adjusting installation seat, and an inner wall adjusting block and an outer arm adjusting block are respectively connected with the corresponding adjusting guide rails in a sliding manner through sliding blocks; the inner wall adjusting block and the outer arm adjusting block are respectively connected with the corresponding adjusting screw rods through nuts; the adjusting device also comprises an adjusting hand wheel connected with the adjusting screw rod.

Preferably: the panel mounting frame is characterized by further comprising two groups of symmetrically arranged driven guide assemblies arranged on the mounting top plate, a driven X-shaped frame is arranged between the panel mounting frame and the two groups of driven guide assemblies, the upper end part of the driven X-shaped frame is pivotally connected with the panel mounting frame, and the lower end part of the driven X-shaped frame is movably connected with the two groups of driven guide assemblies.

Preferably: the driven X-shaped frame comprises two groups of X-shaped folding units which are oppositely arranged, and a hinge locking unit is arranged between the two groups of X-shaped folding units and is used for synchronously adjusting the positions of hinge points of the two groups of X-shaped folding units; the folding device further comprises an inner arm sliding block and an outer arm sliding block which are pivotally connected at the lower ends of the two groups of X-shaped folding units, and the inner arm sliding block and the outer arm sliding block are respectively connected with the two groups of driven guide assemblies.

Preferably: the X-shaped folding unit comprises a driven inner arm and a driven outer arm which are arranged in an X-shaped hinged manner, strip-shaped holes extending along the length direction of the driven inner arm and the driven outer arm are formed in the driven inner arm and the driven outer arm, and the hinged locking unit is arranged in the strip-shaped holes formed in the driven inner arm and the driven outer arm in a penetrating manner and is in locking connection with the X-shaped folding unit; the lower end part of the driven inner arm is pivotally connected with the inner arm sliding block, and the upper end part of the driven inner arm is pivotally connected with the driven mounting panel; the lower end part of the driven outer arm is pivotally connected with the outer arm sliding block, and the upper end part of the driven outer arm is pivotally connected with the driven mounting panel.

Preferably: the hinged locking unit comprises a front connecting support rod arranged between the two groups of X-shaped folding units, and two ends of the front connecting support rod are respectively penetrated into strip-shaped holes formed in the corresponding X-shaped folding units; the front locking slide blocks are sleeved at the two ends of the front connecting support rod respectively, the two groups of front locking slide blocks are connected with the two groups of driven outer arms in a sliding mode respectively, and the front locking slide blocks further comprise locking nuts which are screwed at the end portions of the front connecting support rod and used for locking and connecting the corresponding front locking slide blocks with the driven outer arms.

Preferably: the driven guide assembly comprises a guide mounting seat connected with the mounting top plate, a plurality of groups of transversely arranged driven guide rails are fixedly connected on the guide mounting seat, and the inner arm sliding block and the outer arm sliding block are in sliding connection with the corresponding driven guide rails through the sliding blocks.

Drawings

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

FIG. 2 is a schematic perspective view of an active X-shaped frame and active adjustment assembly according to the present utility model;

fig. 3 is a schematic perspective view of a driven X-frame and driven guide assembly in accordance with the present utility model.

In the figure: 1. counterweight stone piers; 2. a mounting frame; 3. installing a top plate; 4. a driven X-shaped frame; 4-1, an inner arm sliding block; 4-2, driven inner arms; 4-3, front connecting support rods; 4-4, a front locking slide block; 4-5, driven outer arm; 4-6, a driven mounting panel; 4-7, an outer arm sliding block; 5. a driven guide assembly; 5-1, a guide mounting seat; 5-2, a driven guide rail; 6. an active X-shaped frame; 6-1, an inner wall adjusting block; 6-2, an active inner arm; 6-3, connecting the post with the supporting rod; 6-4, a rear locking slide block; 6-5, an active outer arm; 6-6, actively installing a panel; 6-7, an outer arm adjusting block; 7. an active adjustment assembly; 7-1, adjusting a mounting seat; 7-2, adjusting the guide rail; 7-3, adjusting a hand wheel; 7-4, adjusting a screw rod; 8. and a panel mounting frame.

Detailed Description

For a further understanding of the utility model, its features and advantages, the following examples are set forth in detail:

referring to fig. 1, the equipment support for a photovoltaic power generation assembly of the present utility model includes a mounting frame 2 with a top plate 3, a plurality of sets of weight stone piers 1 are mounted at the bottom of the mounting frame 2, a plurality of sets of bolts are buried on the weight stone piers 1, through holes corresponding to the bolts are formed in the mounting frame 2, and the bolts are inserted into the through holes formed in the mounting frame 2 and connected with the weight stone piers 1 through locking nuts.

As shown in fig. 1, two groups of active adjustment assemblies 7 are symmetrically arranged on the mounting top plate 3, and a panel mounting frame 8 is arranged above the active adjustment assemblies 7 and is used for mounting a photovoltaic panel. In addition, the embodiment also comprises an active X-shaped frame 6 arranged between the panel mounting frame 8 and the two groups of active adjusting components 7, wherein the upper end part of the active X-shaped frame 6 is pivotally connected with the panel mounting frame 8, and the lower end part of the active X-shaped frame is movably connected with the two groups of active adjusting components 7;

with further reference to fig. 2, the active X-shaped frame 6 comprises two sets of X-shaped adjusting units arranged oppositely, and a locking connection unit is arranged between the two sets of X-shaped adjusting units and is used for synchronously adjusting the positions of hinge points of the two sets of X-shaped adjusting units; the X-shaped adjusting unit further comprises an inner wall adjusting block 6-1 and an outer arm adjusting block 6-7 which are pivotally connected at the lower end parts of the two groups of X-shaped adjusting units, and the inner wall adjusting block 6-1 and the outer arm adjusting block 6-7 are respectively connected with the two groups of active adjusting components 7. The active X-frame 6 further comprises an active mounting panel 6-6 connected to the panel mounting frame 8, wherein the upper ends of both sets of X-adjustment units are pivotally connected to the active mounting panel 6-6.

In this embodiment, the X-shaped adjusting unit includes an active inner arm 6-2 and an active outer arm 6-5 which are mounted in an X-shaped hinge manner, bar-shaped holes extending along the length direction of the active inner arm 6-2 and the active outer arm 6-5 are formed in the active inner arm 6-2 and the active outer arm 6-5, and the locking connection unit is inserted into the bar-shaped holes formed in the active inner arm 6-2 and the active outer arm 6-5 and is connected with the X-shaped adjusting unit in a locking manner. The lower end of the driving inner arm 6-2 is pivotally connected with the inner wall adjusting block 6-1 through a pin shaft, and the upper end is pivotally connected with the driving mounting panel 6-6 through a pin shaft. The lower end part of the driving outer arm 6-5 is pivotally connected with the outer arm adjusting block 6-7 through a pin shaft, and the upper end part is pivotally connected with the driving installation panel 6-6 through a pin shaft. It is noted that the structure of the driving inner arm 6-2 is identical with that of the driving outer arm 6-5, and the two ends of the driving inner arm 6-2 are provided with pin shaft holes.

In addition, in this embodiment, the locking connection unit includes a rear connection strut 6-3 disposed between two groups of X-shaped adjustment units, and two ends of the rear connection strut 6-3 are respectively inserted into bar-shaped holes formed on the corresponding X-shaped adjustment units. The locking connection unit further comprises rear locking sliding blocks 6-4 sleeved at two ends of the rear connection supporting rod 6-3 respectively, the two groups of rear locking sliding blocks 6-4 are connected with the two groups of driving outer arms 6-5 in a sliding mode respectively, namely sliding grooves are formed in the rear locking sliding blocks 6-4, and the outer edges of the driving outer arms 6-5 are embedded into the sliding grooves formed in the rear locking sliding blocks 6-4 and are in sliding contact with the sliding grooves. The locking connection unit further comprises a lock nut screwed at the end of the rear connection strut 6-3 for locking connection of the corresponding rear locking slide 6-4 and the active outer arm 6-5. For convenient operation, the lock nut is a lug nut.

For convenient operation, as shown in fig. 2, in this embodiment, the active adjusting component 7 includes an adjusting mounting seat 7-1 connected with the mounting top plate 3, a plurality of groups of adjusting guide rails 7-2 arranged transversely are fixedly connected on the adjusting mounting seat 7-1, and the inner wall adjusting block 6-1 and the outer arm adjusting block 6-7 are respectively connected with the corresponding adjusting guide rails 7-2 in a sliding manner through sliding blocks; for dust-proof operation, a corrugated dust cover is installed between the inner wall adjusting block 6-1 and the adjusting mount 7-1, and between the outer arm adjusting block 6-7 and the adjusting mount 7-1. The active adjusting assembly 7 further comprises an adjusting screw rod 7-4 rotatably connected to the adjusting mounting seat 7-1, and the adjusting screw rod 7-4 is arranged in parallel with the adjusting guide rail 7-2; the inner wall adjusting block 6-1 and the outer arm adjusting block 6-7 are respectively connected with the corresponding adjusting screw rod 7-4 through nuts. For convenience of staff, the active adjusting assembly 7 further comprises an adjusting hand wheel 7-3 connected to the adjusting screw rod 7-4.

When the turning angle of the panel mounting frame 8 needs to be adjusted, the locking connection between the locking connection unit and the two groups of X-shaped adjusting units needs to be released, namely, the locking nuts in the locking connection unit are unscrewed first, so that the hinge points of the driven inner arm 4-2 and the driven outer arm 4-5 can move along the strip-shaped holes formed in the driven inner arm and the driven outer arm.

After the locking connection between the locking connection unit and the two groups of X-shaped adjusting units is released, if the adjusting screw rod 7-4 in the group of active adjusting components 7 is driven to rotate, the panel mounting frame 8 can be driven to turn over in one quadrant, and then the inclination angle of the photovoltaic panel can be adjusted in one quadrant.

If the adjusting screw rods 7-4 in the two groups of movable adjusting assemblies 7 are driven to rotate simultaneously, the inclined active mounting panel 6-6 can be gradually adjusted to be in a horizontal state, then the inclined active mounting panel is adjusted to be inclined in a direction opposite to the previous inclined direction, and further the large-range overturning adjusting operation of the panel mounting frame 8 is realized, the purpose that the photovoltaic panel is overturned in two quadrants is finally realized, the problem that the photovoltaic panel cannot be fully used when the sun rotates to the back of the photovoltaic panel is avoided, the utilization rate of the photovoltaic panel is improved, and the working efficiency of the photovoltaic power generation assembly is further improved.

In order to improve the strength of the panel mounting frame 8 and the stability of the overturning movement of the panel mounting frame, the normal use of the photovoltaic power generation assembly is prevented from being influenced by deformation of the panel mounting frame 8 after long-term use, as shown in fig. 1, the embodiment further comprises two groups of symmetrically arranged driven guide assemblies 5 mounted on the mounting top plate 3, a driven X-shaped frame 4 is arranged between the panel mounting frame 8 and the two groups of driven guide assemblies 5, the upper end part of the driven X-shaped frame 4 is in pivot connection with the panel mounting frame 8 through a pin shaft, and the lower end part of the driven X-shaped frame is in movable connection with the two groups of driven guide assemblies 5 through the pin shaft.

With further reference to fig. 3, in the present embodiment, the driven X-shaped frame 4 includes two sets of X-shaped folding units disposed opposite to each other, and a hinge locking unit is disposed between the two sets of X-shaped folding units for synchronously adjusting positions of hinge points of the two sets of X-shaped folding units; the driven X-shaped frame 4 further comprises an inner arm sliding block 4-1 and an outer arm sliding block 4-7 which are pivotally connected at the lower end parts of the two groups of X-shaped folding units, and the inner arm sliding block 4-1 and the outer arm sliding block 4-7 are respectively connected with the two groups of driven guide assemblies 5. In addition, the driven X-shaped frame 4 further comprises a driven mounting panel 4-6 connected with the panel mounting frame 8, and the upper end parts of the two groups of X-shaped folding units are pivotally connected with the driven mounting panel 4-6.

As shown in FIG. 3, the X-shaped folding unit comprises a driven inner arm 4-2 and a driven outer arm 4-5 which are installed in an X-shaped hinged manner, strip-shaped holes extending along the length direction of the driven inner arm 4-2 and the driven outer arm 4-5 are formed in the driven inner arm 4-2 and the driven outer arm 4-5, and the hinged locking unit is arranged in the strip-shaped holes formed in the driven inner arm 4-2 and the driven outer arm 4-5 in a penetrating mode and is in locking connection with the X-shaped folding unit. Wherein, the lower end part of the driven inner arm 4-2 is pivotally connected with the inner arm sliding block 4-1 through a pin shaft, and the upper end part is pivotally connected with the driven mounting panel 4-6 through a pin shaft; the lower end part of the driven outer arm 4-5 is pivotally connected with the outer arm sliding block 4-7 through a pin shaft, and the upper end part is pivotally connected with the driven mounting panel 4-6 through a pin shaft.

Further, in this embodiment, the hinge locking unit includes a front connection strut 4-3 disposed between two groups of X-shaped folding units, and two ends of the front connection strut 4-3 are respectively disposed in a bar-shaped hole formed on the corresponding X-shaped folding unit in a penetrating manner; the front locking slide blocks 4-4 are sleeved at the two ends of the front connecting support rod 4-3 respectively, the two groups of front locking slide blocks 4-4 are connected with the two groups of driven outer arms 4-5 in a sliding mode respectively, namely, sliding grooves are formed in the front locking slide blocks 4-4, and the outer edges of the driven outer arms 4-5 are embedded into the sliding grooves formed in the front locking slide blocks 4-4 and are in sliding contact with the sliding grooves. And a locking nut screwed at the end part of the front connecting strut 4-3 is also included for locking and connecting the corresponding front locking slide block 4-4 and the driven outer arm 4-5. For convenient operation, the lock nut is a lug nut.

As shown in fig. 3, in this embodiment, the driven guide assembly 5 includes a guide mounting seat 5-1 connected with the mounting top plate 3, multiple groups of driven guide rails 5-2 transversely arranged are fixedly connected on the guide mounting seat 5-1, the driven guide rails 5-2 are arranged in parallel with the adjusting guide rails 7-2, and the inner arm sliding block 4-1 and the outer arm sliding block 4-7 are slidably connected with the corresponding driven guide rails 5-2 through sliding blocks.

When the adjusting screw rod 7-4 on the driving adjusting assembly 7 is rotated to adjust the inclination angle of the panel mounting frame 8, the locking connection between the hinged locking unit and the two groups of X-shaped folding units is required to be released, namely, the locking nuts in the locking units are unscrewed, so that the inner arm sliding block 4-1 and the outer arm sliding block 4-7 move along the driven guide rail 5-2 when the panel mounting frame 8 is turned over. Thereby maintaining the stability of the turning movement of the panel mount 8.

Working principle:

the active X-shaped frame 6 is arranged to be pivotally connected with the panel mounting frame 8, so that the inclination angle of the panel mounting frame 8 can be adjusted according to real-time conditions, the inclination angle of the photovoltaic panel can be further adjusted, and the photovoltaic panel can be further fully used; the active X-shaped frame 6 comprises two groups of X-shaped adjusting units formed by the active inner arm 6-2 and the active outer arm 6-5 which are arranged in a crossing way and a locking connecting unit for connecting the two groups of X-shaped adjusting units, so that the joint point of the two groups of X-shaped adjusting units is in an adjustable state, the position of the locking connecting unit can be adjusted according to the actual situation, and the shape of the two groups of X-shaped adjusting units can be adjusted; through setting up two sets of initiative adjusting part 7, but the position of two lower extreme stabilizer blades of two sets of X type adjusting unit, the purpose of adjusting the inclination of panel mounting bracket 8 can be realized to the cooperation locking connection unit simultaneously, as before, when adjusting the inclination of panel mounting bracket 8 in same quadrant, only need be under the circumstances of releasing the locking connection of locking connection unit and two sets of X type adjusting unit, alone operation initiative adjusting part 7 can, if adjust the inclination of panel mounting bracket 8 in two quadrants, then need be under the circumstances of releasing the locking connection of locking connection unit and two sets of X type adjusting unit, operate two initiative adjusting part 7 simultaneously, in addition, when carrying out foretell regulation, need be released the articulated locking unit in the driven X type frame 4 and the locking connection of two sets of X type folding unit.

Claims (9)

1. An equipment support for photovoltaic power generation module, characterized by: the photovoltaic panel mounting device comprises a mounting frame (2) with a mounting top plate (3) at the top, two groups of active adjusting components (7) symmetrically arranged on the mounting top plate (3), and a panel mounting frame (8) arranged above the active adjusting components (7) for mounting the photovoltaic panel; the device also comprises an active X-shaped frame (6) arranged between the panel mounting frame (8) and the two groups of active adjusting components (7), wherein the upper end part of the active X-shaped frame (6) is pivotally connected with the panel mounting frame (8), and the lower end part of the active X-shaped frame is movably connected with the two groups of active adjusting components (7); the active X-shaped frame (6) comprises two groups of X-shaped adjusting units which are oppositely arranged, and a locking connecting unit is arranged between the two groups of X-shaped adjusting units and is used for synchronously adjusting the positions of hinge points of the two groups of X-shaped adjusting units; the X-shaped adjusting unit further comprises an inner wall adjusting block (6-1) and an outer arm adjusting block (6-7) which are pivotally connected at the lower end parts of the two groups of X-shaped adjusting units, and the inner wall adjusting block (6-1) and the outer arm adjusting block (6-7) are respectively connected with the two groups of active adjusting components (7).

2. The equipment rack for a photovoltaic power generation module of claim 1, wherein: the X-shaped adjusting unit comprises an active inner arm (6-2) and an active outer arm (6-5) which are arranged in an X-shaped hinged manner, strip-shaped holes extending along the length direction of the active inner arm (6-2) and the active outer arm (6-5) are formed in the active inner arm (6-2) and the active outer arm (6-5), and the locking connecting unit is arranged in the strip-shaped holes formed in the active inner arm (6-2) and the active outer arm (6-5) in a penetrating manner and is in locking connection with the X-shaped adjusting unit; the lower end part of the driving inner arm (6-2) is pivotally connected with the inner wall adjusting block (6-1), and the upper end part is pivotally connected with the driving installation panel (6-6); the lower end part of the driving outer arm (6-5) is pivotally connected with the outer arm adjusting block (6-7), and the upper end part is pivotally connected with the driving mounting panel (6-6).

3. The equipment rack for a photovoltaic power generation module according to claim 2, characterized in that: the locking connection unit comprises a rear connection supporting rod (6-3) arranged between the two groups of X-shaped adjustment units, and two ends of the rear connection supporting rod (6-3) are respectively penetrated in strip-shaped holes formed in the corresponding X-shaped adjustment units; the rear locking device further comprises rear locking sliding blocks (6-4) sleeved at two ends of the rear connecting supporting rod (6-3), the two groups of rear locking sliding blocks (6-4) are respectively connected with the two groups of driving outer arms (6-5) in a sliding mode, and locking nuts screwed at the ends of the rear connecting supporting rod (6-3) are used for locking and connecting the corresponding rear locking sliding blocks (6-4) with the driving outer arms (6-5).

4. The equipment rack for a photovoltaic power generation module of claim 1, wherein: the active adjusting assembly (7) comprises an adjusting installation seat (7-1) connected with the installation top plate (3), a plurality of groups of transversely arranged adjusting guide rails (7-2) are fixedly connected on the adjusting installation seat (7-1), and an inner wall adjusting block (6-1) and an outer arm adjusting block (6-7) are respectively connected with the corresponding adjusting guide rails (7-2) in a sliding mode through sliding blocks; the device also comprises an adjusting screw rod (7-4) which is rotationally connected with the adjusting installation seat (7-1), and the inner wall adjusting block (6-1) and the outer arm adjusting block (6-7) are respectively connected with the corresponding adjusting screw rod (7-4) through nuts; the device also comprises an adjusting hand wheel (7-3) connected with the adjusting screw rod (7-4).

5. The equipment rack for a photovoltaic power generation module of claim 1, wherein: the automatic control device is characterized by further comprising two groups of symmetrically arranged driven guide assemblies (5) arranged on the mounting top plate (3), wherein a driven X-shaped frame (4) is arranged between the panel mounting frame (8) and the two groups of driven guide assemblies (5), the upper end part of the driven X-shaped frame (4) is pivotally connected with the panel mounting frame (8), and the lower end part of the driven X-shaped frame is movably connected with the two groups of driven guide assemblies (5).

6. The equipment rack for a photovoltaic power generation module according to claim 5, wherein: the driven X-shaped frame (4) comprises two groups of X-shaped folding units which are oppositely arranged, and a hinge locking unit is arranged between the two groups of X-shaped folding units and is used for synchronously adjusting the positions of hinge points of the two groups of X-shaped folding units; the folding device further comprises an inner arm sliding block (4-1) and an outer arm sliding block (4-7) which are pivotally connected at the lower end parts of the two groups of X-shaped folding units, and the inner arm sliding block (4-1) and the outer arm sliding block (4-7) are respectively connected with the two groups of driven guide components (5).

7. The equipment rack for a photovoltaic power generation module according to claim 6, wherein: the X-shaped folding unit comprises a driven inner arm (4-2) and a driven outer arm (4-5) which are arranged in an X-shaped hinged manner, strip-shaped holes extending along the length direction of the driven inner arm (4-2) and the driven outer arm (4-5) are formed in the driven inner arm (4-2) and the driven outer arm (4-5), and the hinged locking unit is arranged in the strip-shaped holes formed in the driven inner arm (4-2) and the driven outer arm (4-5) in a penetrating manner and is in locking connection with the X-shaped folding unit; the lower end part of the driven inner arm (4-2) is pivotally connected with the inner arm sliding block (4-1), and the upper end part is pivotally connected with the driven mounting panel (4-6); the lower end part of the driven outer arm (4-5) is pivotally connected with the outer arm sliding block (4-7), and the upper end part is pivotally connected with the driven mounting panel (4-6).

8. The equipment rack for a photovoltaic power generation module according to claim 7, wherein: the hinged locking unit comprises a front connecting support rod (4-3) arranged between the two groups of X-shaped folding units, and two ends of the front connecting support rod (4-3) are respectively penetrated into strip-shaped holes formed in the corresponding X-shaped folding units; the front locking device further comprises front locking sliding blocks (4-4) sleeved at two ends of the front connecting supporting rod (4-3), the two groups of front locking sliding blocks (4-4) are respectively connected with the two groups of driven outer arms (4-5) in a sliding mode, and locking nuts screwed at the ends of the front connecting supporting rod (4-3) are used for locking and connecting the corresponding front locking sliding blocks (4-4) with the driven outer arms (4-5).

9. The equipment rack for a photovoltaic power generation module according to claim 6, wherein: the driven guide assembly (5) comprises a guide mounting seat (5-1) connected with the mounting top plate (3), a plurality of groups of transversely arranged driven guide rails (5-2) are fixedly connected on the guide mounting seat (5-1), and the inner arm sliding block (4-1) and the outer arm sliding block (4-7) are both in sliding connection with the corresponding driven guide rails (5-2) through the sliding blocks.