CN220673659U - Horizontal pole leveling system of photovoltaic support - Google Patents

Abstract

The utility model discloses a photovoltaic bracket cross bar leveling system, which comprises upright C steel ribs; the support is installed on the vertical C steel rib in a lifting controllable way, and a plurality of longitudinal through holes which are collinear and distributed at intervals are arranged on a longitudinal rod of the support; the angle steel beam support is provided with two through holes, and is fixed on the longitudinal rod through nuts after penetrating through the longitudinal through holes by two longitudinal bolts; the horizontal adjustment stay wire is adjusted to a horizontal state to mark the horizontal adjustment stay wire serving as a reference, and the horizontal adjustment stay wire is fixedly arranged on angle steel beam supports of the brackets at two ends; the cross rod is fixed on the angle steel beam supports of the brackets at the two ends. Because the horizontal pole is fixed on the support of both ends side earlier and is in the horizontality and parallel the back with both ends, the support that the later stage rethread is located the middle part promotes and fixes two horizontal poles middle parts for the horizontal pole can not incline in the great mountain region stable displacement of wind-force appears, has solved and can receive spring displacement to appear inclining and can not horizontally problem at the great mountain region top frame both ends of wind-force.

Description

Horizontal pole leveling system of photovoltaic support

Technical Field

The utility model relates to a cross rod leveling system of a photovoltaic bracket, and belongs to the technical field of photovoltaic power generation construction.

Background

In the construction environment of the uneven mountain slope, a plurality of photovoltaic plates are required to be installed between the cross bars parallel to the support body, as shown in fig. 5, in order to cope with the construction top surface of the uneven mountain slope, a liftable support is required to be made to ensure that the photovoltaic plates are positioned on a horizontal plane.

The existing liftable photovoltaic module support which is available on a mountain slope and can adjust lighting angles is disclosed as a Chinese patent publication No. CN2021110432270, and the disclosed technology is as follows: the upper end of a left support thin rod sleeved with a left support rod spring passes through the top frame through a left movable hole, the upper end of a right support thin rod sleeved with a right support rod spring passes through the top frame through a right movable hole, and the upper end of a lower support fixing frame is fixedly connected with the top frame; although a plurality of photovoltaic panels can obtain installation space on the top frame, the two ends of the top frame of the mountain area with large wind force can be inclined by spring displacement and cannot be horizontal.

Disclosure of Invention

In order to solve the technical problems, the utility model provides a cross rod leveling system of a photovoltaic bracket.

The utility model is realized by the following technical scheme.

The utility model provides a leveling system for a cross rod of a photovoltaic bracket, which comprises an upright C steel ridge in a fixed state;

the support is installed on the vertical C steel rib in a lifting controllable way, and a plurality of longitudinal through holes which are collinear and distributed at intervals are arranged on a longitudinal rod of the support;

the brackets positioned in the middle are lower than the brackets at the two end sides;

the angle steel beam support is provided with two through holes, and is fixed on the longitudinal rod through nuts after penetrating through the longitudinal through holes by two longitudinal bolts;

the horizontal adjustment stay wire is adjusted to a horizontal state to mark the horizontal adjustment stay wire serving as a reference, and the horizontal adjustment stay wire is fixedly arranged on angle steel beam supports of the brackets at two ends;

the cross rod is fixed on the angle steel beam supports of the brackets at the two ends by taking the horizontal adjustment stay wire in a marked horizontal state as a horizontal installation standard.

The foundation pile is characterized by further comprising a mountain slope body with uneven surface, and four foundation piles which are collinearly and at intervals are poured and fixed in the mountain slope body.

The vertical C steel ribs are four collinearly and alternately distributed.

The four upright C steel ribs which are arranged in a collinear way at intervals are correspondingly embedded in the four foundation piles which are arranged in a collinear way at intervals.

The support and the vertical C steel rib are respectively provided with a plurality of through holes, and the vertical C steel rib and the support can be controllably lifted and installed through screwing and detachable fixation of bolts and nuts after a group of through holes correspond to each other.

The transverse rod is provided with a plurality of transverse waist-shaped holes at intervals, and the transverse rod transverse waist-shaped holes are fixed by bolts and nuts corresponding to the vertical waist-shaped holes of the angle steel arranged on the angle steel beam supports at the two end supports.

The utility model has the beneficial effects that: because the horizontal pole is fixed on the support of both ends side earlier and is in the horizontality and parallel the back with both ends, the support that the later stage rethread is located the middle part promotes and fixes two horizontal poles middle parts for the horizontal pole can not incline in the great mountain region stable displacement of wind-force appears, has solved and can receive spring displacement to appear inclining and can not horizontally problem at the great mountain region top frame both ends of wind-force.

Drawings

FIG. 1 is a schematic view showing the structure of the middle bracket of the present utility model lower than the brackets at both end sides;

FIG. 2 is a schematic view of the structure of the bracket of the present utility model with the bracket at the flush end sides of the middle part;

FIG. 3 is a schematic view of a cross bar leveling connection structure formed by a cross bar mounted on a vertical bar through an angle steel beam bracket;

FIG. 4 is a schematic view of the structure of the photovoltaic panel of the present utility model when mounted on two parallel rails;

FIG. 5 is a schematic front view of a photovoltaic panel of the present utility model mounted on two parallel rails;

in the figure: 1-mountain slope body; 2-foundation piles; 3-erecting C steel ribs; 4-a bracket; 41-a vertical rod; 42-longitudinal through holes; 5-angle steel beam brackets; 51-angle steel vertical kidney holes; 52-a longitudinal bolt; 6-horizontally adjusting the pull wire; 7-a cross bar; 71-transverse cross bar kidney-shaped holes; 8-photovoltaic panel.

Detailed Description

The technical solution of the present utility model is further described below, but the scope of the claimed utility model is not limited to the above.

As shown in fig. 1 to 5.

The application discloses a photovoltaic support horizontal pole leveling method includes:

providing a construction environment for the mountain slope 1 with uneven surface, wherein the mountain slope 1 is provided with a plurality of concave-convex surface;

at least four foundation piles 2 which are collinear and distributed at intervals are fixedly cast by reinforced concrete construction along the left and right transverse directions of the mountain slope body 1, and upright C steel ribs 3 are pre-buried and fixedly arranged in the foundation piles 2;

the support 4 is arranged on the vertical C steel ridge 3 in a controllable lifting manner, specifically, a plurality of through holes are formed in the support 4 and the vertical C steel ridge 3, and a group of through holes are screwed and detachably fixed through bolts and nuts after corresponding to each other to realize the controllable lifting and mounting of the vertical C steel ridge 3 and the support 4;

the angle steel beam supports 5 are fixedly arranged on the longitudinal rods 41 of the brackets 4 at the two ends through longitudinal bolts 52 and nuts, the horizontal adjustment stay wires 6 are fixedly arranged between the angle steel beam supports 5 of the brackets 4 at the two ends in a binding mode, the brackets 4 at the two ends are adjusted by using a level meter to test the horizontal adjustment stay wires 6, the horizontal adjustment stay wires 6 are marked to be in a horizontal state to serve as a standard for horizontal installation of the cross rod 7, and the brackets 4 at the middle are lower than the brackets 4 at the two ends at the moment, so that a required horizontal rod leveling system of the photovoltaic bracket is constructed.

After the photovoltaic support cross rod leveling system is constructed and obtained through the photovoltaic support cross rod leveling method, the horizontal adjustment stay wire in a marked horizontal state is used as a 6 horizontal installation standard, the cross rod 7 is installed on the angle steel beam supports 5 which are fixed on the two end supports 4, cross rod transverse kidney-shaped holes 71 at two ends of the cross rod 7 are fixedly installed with angle steel vertical kidney-shaped holes 51 which are arranged on the angle steel beam supports 5 of the two end supports 4 through bolts and nuts (not shown), the cross rod transverse kidney-shaped holes 71 and the angle steel vertical kidney-shaped holes 51 can be transversely and vertically adjusted in place and then are fixedly installed through bolts and nuts, at the moment, the angle steel beam supports 5 are fixed with the longitudinal rods 41 through two longitudinal bolts 52 and nuts, and two ends of the two cross rods 7 are fixed on the two end supports 4 through the two horizontal adjustment stay wires 6 serving as standard.

After the support 4 positioned in the middle is adjusted and lifted up by the upright C steel bar 3, the position of the cross rod 7 is preferentially ensured, the angle steel beam support 5 is adjusted to correspond to the longitudinal through holes 42 formed in the longitudinal bars 41 on the support 4, two longitudinal bolts 52 and nuts are installed for fixing, the angle steel beam support 5 is provided with two through holes and a plurality of longitudinal through holes 42 which are arranged on the longitudinal bars 41 in a collinear and spaced mode for correspondingly allowing the two longitudinal bolts 52 to penetrate, the angle steel beam support 5 is adjusted on the support 4 in the middle to adapt to the position of the cross rod 7 which is preferentially ensured and is fixed, and a cross rod leveling connecting structure is formed at the moment, so that the problem that the position of the cross rod cannot be preferentially ensured due to the fact that the angle steel beam support is welded on an end sealing plate and cannot be displaced is solved. At this time, the brackets 4 in the middle are flush with the brackets 4 on both end sides.

After the two cross bars 7 are firstly fixed on the supports 4 at the two end sides in a horizontal state and parallel, the middle parts of the two cross bars 7 are fixed through the supports 4 at the middle parts, so that the cross bars 7 cannot incline when stably displacing in a mountain area with large wind force, and the problem that the two ends of the top frame of the mountain area with large wind force cannot be horizontal due to the inclination caused by the spring displacement is solved. And then a plurality of photovoltaic panels 8 are sequentially arranged in two parallel cross bars 7 to form a power generation unit.

The horizontal adjustment stay wire 6 can be detached when the two cross bars 7 are installed, or the horizontal adjustment stay wire 6 can be detached after a plurality of photovoltaic panels 8 are sequentially installed in the two parallel cross bars 7.

Claims (6)

1. The leveling system for the cross bar of the photovoltaic bracket is characterized by comprising an upright C steel ridge (3) in a fixed state;

the support (4) is arranged on the vertical C steel rib (3) in a lifting controllable way, and a plurality of longitudinal through holes (42) which are collinear and distributed at intervals are arranged on a longitudinal rod (41) of the support (4);

the brackets (4) positioned in the middle are lower than the brackets (4) at the two end sides;

the angle steel beam support (5) is provided with two through holes, and the angle steel beam support (5) is fixed on the longitudinal rod (41) through two longitudinal bolts (52) penetrating through the longitudinal through holes (42) and then screwed with nuts;

the horizontal adjustment pull wire (6) is adjusted to a horizontal state to mark the horizontal adjustment pull wire (6) serving as a reference, and the horizontal adjustment pull wire (6) is fixedly arranged on the angle steel beam supports (5) of the brackets (4) at the two ends;

the cross rod (7), the horizontal rod (7) is fixed on the angle steel beam supports (5) of the brackets (4) at the two ends by taking the horizontal adjustment pull wire (6) in a marked horizontal state as a horizontal installation reference.

2. The photovoltaic bracket rail leveling system of claim 1 wherein: also comprises a mountain slope body (1) with uneven surface, four foundation piles (2) which are collinearly and at intervals are fixedly poured in the mountain slope body (1).

3. The photovoltaic bracket rail leveling system of claim 1 wherein: the vertical C steel ribs (3) are four collinearly and alternately distributed.

4. The photovoltaic bracket rail leveling system of claim 3 wherein: the four upright C steel ribs (3) which are arranged in a collinear way at intervals are correspondingly embedded in the four foundation piles (2) which are arranged in a collinear way at intervals.

5. The photovoltaic bracket rail leveling system of claim 1 wherein: the support (4) and the upright C steel rib (3) are respectively provided with a plurality of through holes, and the upright C steel rib (3) and the support (4) can be installed in a controllable lifting manner through screwing and fixing of bolts and nuts after a group of through holes correspond to each other.

6. The photovoltaic bracket rail leveling system of claim 1 wherein: the transverse rod (7) is provided with a plurality of transverse rod kidney-shaped holes (71) which are spaced, and the transverse rod kidney-shaped holes (51) which are arranged on the angle steel beam supports (5) of the two-end brackets (4) are correspondingly fixed through bolts and nuts.