CN211508973U - Manual quick adjustment photovoltaic module support - Google Patents

Abstract

The utility model relates to a manual quick adjustment photovoltaic module support belongs to the photovoltaic technology field. The photovoltaic power generation device is characterized by comprising a stand column and an oblique beam, wherein a bottom plate is fixed at the bottom of the stand column, the top of the stand column is provided with the oblique beam, the stand column and the oblique beam are connected through a connecting piece, purlins are uniformly arranged on the oblique beam at intervals, photovoltaic modules are arranged on the purlins, pulleys are arranged on the stand column, steel wire ropes are wound on the pulleys, two ends of each steel wire rope are fixed with the oblique beam respectively, and a steel wire rope tightener is arranged on each steel wire rope and used. The method comprises the steps that an inner upright post is rotated to enable an indicating line to rotate to a measured angle to enable the indicating line to face the south; and loosening the bolts on the angle dial, manually rotating the oblique beam, observing the angle dial, rotating the oblique beam to the optimal inclination angle obtained by measurement, tightening the bolts, and adjusting the lengths of the steel wire ropes on two sides of the tightening upright post through the steel wire rope tightener. The azimuth orientation and the inclination angle of the photovoltaic module are adjusted, so that the photovoltaic module obtains the maximum daily radiant quantity to achieve the maximum power generation output.

Description

Manual quick adjustment photovoltaic module support

Technical Field

The utility model relates to a manual quick adjustment photovoltaic module support belongs to the photovoltaic technology field.

Background

The solar photovoltaic power generation technology is a novel power generation technology which directly converts solar radiation energy into electric energy by utilizing the photovoltaic effect of a solar cell semiconductor material. The solar photovoltaic power generation technology can be used in any occasions needing power supplies, such as spacecrafts, household power supplies, megawatt power stations, toys and the like. The power generation efficiency of the solar photovoltaic power generation technology depends on the irradiation angle between the solar rays and the solar cell panel to a great extent. In the prior art, the inclination angle of the photovoltaic support is fixed and unchanged, and the solar cell panel on the photovoltaic support cannot be in the best lighting angle, so that the power generation efficiency of the solar cell panel is low.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that a manual quick adjustment photovoltaic module support is provided to above-mentioned prior art, thereby can the position orientation and the best inclination of quick adjustment photovoltaic module, acquire the maximum solar radiation volume and reach the biggest power generation output.

The utility model provides a technical scheme that above-mentioned problem adopted does: the utility model provides a manual quick adjustment photovoltaic module support, includes stand and sloping, stand bottom PMKD, the stand top is equipped with the sloping, connects stand and sloping through the connecting piece, even interval is equipped with the purlin on the sloping, set up photovoltaic module on the purlin, be equipped with the pulley on the stand, around establishing wire rope on the pulley, the wire rope both ends are fixed with the sloping respectively, be equipped with wire rope tightener on the wire rope for tighten up wire rope.

The upright columns comprise outer upright columns and inner upright columns, the inner upright columns are arranged in the outer upright columns, and the inner upright columns are moved to extend or retract relative to the outer upright columns; rotating the inner post such that the inner post rotates relative to the outer post 360; a plurality of first mounting holes are formed in the outer stand column at uniform intervals, a plurality of second mounting holes are formed in the inner stand column at uniform intervals, the inner stand column is rotated or moved, the first mounting holes and the second mounting holes are overlapped and then fixed through bolts, and therefore the inner stand column and the outer stand column are fixed.

The outer stand column is marked with an exposed identification line, and the inner stand column is marked with an indicating line.

The top surface of the outer stand column is carved with an angle identification line, so that the rotation angle of the inner stand column can be observed conveniently.

The top end of the upright post is fixedly provided with a connecting piece, an angle dial is arranged on the connecting piece, and the connecting piece and the oblique beam are fixed through bolts.

Compared with the prior art, the utility model has the advantages of: a manual quick adjustment photovoltaic assembly support is provided, an inner upright post is lifted, and quick leveling of a photovoltaic assembly in a slight-gradient installation place is facilitated; the inner upright post is rotated, so that the orientation of the photovoltaic module can be conveniently adjusted; and loosening the bolts on the connecting pieces, manually rotating the oblique beams, observing the angle dial disc on the connecting pieces, rotating the oblique beams to the optimal inclination angle obtained by measurement, tightening the bolts, and adjusting the lengths of the steel wire ropes on two sides of the tightening stand by the steel wire rope tightener so as to realize the rapid adjustment of the optimal inclination angle of the photovoltaic module. The azimuth orientation and the inclination angle of the photovoltaic module are adjusted, so that the photovoltaic module obtains the maximum daily radiant quantity to achieve the maximum power generation output.

Drawings

Fig. 1 is a schematic view of a photovoltaic module bracket with manual quick adjustment according to an embodiment of the present invention;

fig. 2 is a schematic diagram of a middle column of a manual quick adjustment photovoltaic module bracket according to an embodiment of the present invention;

fig. 3 is a schematic diagram of an angle dial in a photovoltaic module bracket according to an embodiment of the present invention;

in the figure, 1 a bottom plate, 2 upright columns, 2.1 sun-facing identification lines, 2.2 outer upright columns, 2.3 angle identification lines, 2.4 inner upright columns, 2.5 indicating lines, 3 pulleys, 4 steel wire ropes, 5 steel wire rope tighteners, 6 oblique beams, 7 photovoltaic modules, 8 purlins and 9 connecting pieces are arranged.

Detailed Description

The present invention will be described in further detail with reference to the following embodiments.

As shown in fig. 1, the photovoltaic module support capable of being adjusted manually and quickly in the embodiment includes an upright post 2 and an oblique beam 6, a bottom plate 1 is fixed at the bottom of the upright post 2, and 4 threaded holes are formed in the bottom plate 1, so that the support is convenient to fix during installation. The upright post 2 comprises an outer upright post 2.2 made of a round pipe and an inner upright post 2.4 made of a round pipe, the inner upright post 2.4 is arranged in the outer upright post 2.2, and the inner upright post 2.4 is moved to enable the inner upright post 2.4 to extend or retract relative to the outer upright post 2.2; rotating the inner upright 2.4 to enable the inner upright 2.4 to rotate 360 degrees relative to the outer upright 2.2; a plurality of first mounting holes are formed in the outer stand column 2.2 at uniform intervals in the vertical direction, a plurality of second mounting holes are formed in the inner stand column 2.4 at uniform intervals in the vertical direction, the first mounting holes are matched with the second mounting holes in aperture, when the inner stand column 2.4 is rotated or moved to a required position, the first mounting holes and the second mounting holes are overlapped and penetrate through bolts, and the inner stand column 2.4 is fixed to the outer stand column 2.2. The top of the upright post 2 is provided with an oblique beam 6, the top end of the upright post 2 is fixedly provided with a connecting piece 9, and the connecting piece 9 and the oblique beam 6 are fixed through bolts. Purlins 8 are arranged on the oblique beams 6 at uniform intervals, and photovoltaic modules 7 are arranged on the purlins 8. The middle part of the upright post 2 is provided with a pulley 3, a steel wire rope 4 is wound on the pulley 3, two ends of the steel wire rope 4 are respectively fixed with the bottom of the oblique beam 6, the steel wire rope 4 is divided into a front steel wire rope and a rear steel wire rope by the upright post 2, and two steel wire rope tighteners 5 are respectively arranged on the two steel wire ropes 4 and used for respectively tightening the steel wire ropes 4.

When the inner upright post 2.4 is moved, the inner upright post 2.4 extends or retracts relative to the outer upright post 2.2, and the first mounting hole and the second mounting hole are overlapped and then fixed through bolts, so that the upright post 2 is lifted. The photovoltaic module 7 can be quickly leveled in a slightly-inclined installation place, and is simple and convenient.

The outer upright post 2.2 is marked with an exposed mark line 2.1, the inner upright post 2.4 is marked with an indicating line 2.5, and the top surface of the outer upright post 2.2 is carved with an angle mark line 2.3. The sun-facing sign line 2.1 is arranged in the direction approximately facing south of the installation place, and the outer upright post 2.2 is fixedly connected with the installation place through the base. The contained angle of sunward sign line 2.1 and the positive south direction is surveyed through the guide instrument, observes the scale on the outer column 2.2 top surface, and rotatory inner column 2.4 makes the angle that the indicator line 2.5 is rotatory to the guide instrument and is surveyed for photovoltaic module is towards the positive south, is convenient for adjust photovoltaic module's positive south orientation, makes photovoltaic module can obtain the maximum illumination volume, is fit for the installation place in different positions.

When the inclination angle of the oblique beam 6 needs to be adjusted, the bolt on the connecting piece 9 is loosened, the oblique beam 6 can rotate, the angle dial on the connecting piece 9 is observed, the oblique beam 6 is rotated to the optimal inclination angle obtained by measurement, and the bolt is screwed down. The length of the steel wire ropes 4 on two sides of the tightening upright post 2 is adjusted through the steel wire rope tightener 5, and whether the angle of the inclined beam 6 on the angle dial deviates or not is observed, so that the optimal inclination angle of the photovoltaic module 7 can be adjusted rapidly.

The orientation and the inclination angle of the photovoltaic module are adjusted, so that the photovoltaic module obtains the maximum daily radiant quantity to achieve the maximum power generation output.

In addition to the above embodiments, the present invention also includes other embodiments, and all technical solutions formed by equivalent transformation or equivalent replacement should fall within the protection scope of the claims of the present invention.

Claims (5)

1. The utility model provides a manual quick adjustment photovoltaic module support which characterized in that: the photovoltaic power generation device is characterized by comprising a stand column and an oblique beam, wherein a bottom plate is fixed at the bottom of the stand column, the top of the stand column is provided with the oblique beam, the stand column and the oblique beam are connected through a connecting piece, purlins are uniformly arranged on the oblique beam at intervals, photovoltaic modules are arranged on the purlins, pulleys are arranged on the stand column, steel wire ropes are wound on the pulleys, two ends of each steel wire rope are fixed with the oblique beam respectively, and a steel wire rope tightener is arranged on each steel wire rope and used.

2. The manual quick adjustment photovoltaic module rack of claim 1, wherein: the upright columns comprise outer upright columns and inner upright columns, the inner upright columns are arranged in the outer upright columns, and the inner upright columns are moved to extend or retract relative to the outer upright columns; rotating the inner upright column to enable the inner upright column to rotate 360 degrees relative to the outer upright column; a plurality of first mounting holes are formed in the outer stand column at uniform intervals, a plurality of second mounting holes are formed in the inner stand column at uniform intervals, the inner stand column is rotated or moved, the first mounting holes and the second mounting holes are fixed through bolts after being overlapped, and the inner stand column and the outer stand column are fixed.

3. The manual quick adjustment photovoltaic module rack of claim 2, wherein: the outer stand column is marked with an exposed identification line, and the inner stand column is marked with an indicating line.

4. The manual quick adjustment photovoltaic module rack of claim 2, wherein: the top surface of the outer stand column is carved with an angle identification line, so that the rotation angle of the inner stand column can be observed conveniently.

5. The manual quick adjustment photovoltaic module rack of claim 1, wherein: the top end of the upright post is fixedly provided with a connecting piece, an angle dial is arranged on the connecting piece, and the connecting piece and the oblique beam are fixed through bolts.

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