CN218117385U - Photovoltaic energy storage bicycle shed - Google Patents

Abstract

The utility model discloses a photovoltaic energy storage bicycle shed, the supporting mechanism (5) include support column (5.1), base (5.2), servo motor (5.3), push rod (5.4) and energy storage battery (5.5) that are the V style of calligraphy, support column (5.1) fix on base (5.2), base (5.2) fix subaerial; the photovoltaic panel rotating mechanism overcomes the defects of low utilization rate and high cost of the photovoltaic panel at the same time in the prior art, and has the advantages that the photovoltaic panel on the ceiling can rotate in the east-west direction by matching the servo motor with the push rod, the direct irradiation of sunlight is kept all the time, and the power generation efficiency of the photovoltaic panel is improved.

Description

Photovoltaic energy storage bicycle shed

Technical Field

The utility model relates to the technical field of bicycle shed, more specifically a photovoltaic energy storage bicycle shed.

Background

At present, a photovoltaic car shed is generally used for generating electricity by arranging a photovoltaic panel on the roof of the car shed to supply power to nearby lighting equipment and the like. The photovoltaic panel is mainly fixed, the photovoltaic panel is arranged in a plane or in an arc shape, the problem of low power generation power caused by oblique sunlight is solved through the plane fixed arrangement of the photovoltaic panel, and the problems of low utilization rate, high cost and the like of the photovoltaic panel at the same time are still solved through the arc arrangement of the photovoltaic panel.

In addition, the photovoltaic panel's electricity generation has the condition of surplus daytime and night not enough, and the electricity generation is if there is not close on the power load can only surplus electricity online daytime, and needs municipal power grid to supply the power shortage night, and the mismatching of power consumption supply and demand leads to the photovoltaic panel electricity generation actual utilization low.

Therefore, there is a high necessity for a device to solve the above problems.

Disclosure of Invention

An object of the utility model is to overcome above-mentioned background art's weak point, and provide a photovoltaic energy storage bicycle shed.

The utility model aims at being implemented through the following technical scheme: a photovoltaic energy storage carport comprises a carport roof, photovoltaic panels, a reflecting layer, a rainwater diversion trench and a supporting mechanism, wherein the photovoltaic panels are paved on the carport roof, the reflecting layer is arranged below the photovoltaic panels, the reflecting layer is positioned between the carport roof and the photovoltaic panels,

the shed roof is provided with a rainwater diversion groove along the edge of the photovoltaic panel, and a supporting mechanism is arranged below the shed roof;

the supporting mechanism comprises a V-shaped supporting column, a base, a servo motor, a push rod and an energy storage battery, wherein the supporting column is fixed on the base, and the base is fixed on the ground.

In the above technical scheme: every the support column inside be cavity and all install a servo motor, servo motor below install energy storage battery, energy storage battery be located the support column inside.

In the above technical scheme: the servo motor top be provided with the push rod, servo motor pass through the push rod with shed roof bottom articulated.

In the above technical scheme: the servo motor can drive the push rod to do telescopic motion along the axial direction of the support column.

The utility model has the advantages of as follows: 1. the utility model discloses a servo motor and push rod cooperate, can make the photovoltaic board on the ceiling rotate in the east-west, keep the perpendicular incidence of sunlight constantly, increase the generating efficiency of photovoltaic board.

2. The utility model discloses utilize the inside hollow space of support column to set up energy storage battery, regard the outer wall of support column as waterproof layer and heat dissipation layer, can satisfy energy storage battery's waterproof and heat dissipation demand under the prerequisite that does not increase additional structure. Meanwhile, the maintenance operation can be carried out by only opening the outer wall of the supporting column during the later maintenance, and the operation is more convenient.

3. The utility model discloses be equipped with the reflector layer in the below of photovoltaic board, the sunlight that can reflect and pierce through photovoltaic board makes its secondary shine photovoltaic board, increases the generating efficiency.

4. The utility model discloses whole and outside electric wire netting networking can charge for energy storage battery when the trough electrovalence, charges for the electric motor car again when needing, and the low price can also stabilize electric wire netting crest trough. Or reversely transmitting power to the power grid at the peak power price to create extra income.

5. The utility model discloses an edge along photovoltaic board on the ceiling is equipped with the rainwater guiding gutter, can guide the rainwater to flow, avoids the rainwater to pile up and leads to the photovoltaic board to damage or influence the generating efficiency on the photovoltaic board.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a side view of the present invention.

Fig. 3 is a schematic diagram of the present invention.

Fig. 4 is an enlarged view of a portion a in fig. 2.

Fig. 5 is a sectional view of the support mechanism.

In the figure: shed roof 1, photovoltaic board 2, reflector layer 3, rainwater guiding gutter 4, supporting mechanism 5, support column 5.1, base 5.2, servo motor 5.3, push rod 5.4, energy storage battery 5.5.

Detailed Description

The embodiments of the present invention will be described in detail with reference to the accompanying drawings, but they are not to be construed as limiting the invention, and are presented by way of example only, and the advantages of the invention will become more apparent and can be easily understood by description.

Referring to FIGS. 1-5: a photovoltaic energy storage carport comprises a carport top 1, photovoltaic panels 2, a reflecting layer 3, a rainwater diversion trench 4 and a supporting mechanism 5, wherein the photovoltaic panels 2 are paved on the carport top 1, the reflecting layer 3 is arranged below the photovoltaic panels 2, the reflecting layer 3 is positioned between the carport top 1 and the photovoltaic panels 2,

the shed roof 1 is provided with a rainwater diversion trench 4 along the edge of the photovoltaic panel 2, and a supporting mechanism 5 is arranged below the shed roof 1;

the supporting mechanism 5 comprises a V-shaped supporting column 5.1, a base 5.2, a servo motor 5.3, a push rod 5.4 and an energy storage battery 5.5, the supporting column 5.1 is fixed on the base 5.2, and the base 5.2 is fixed on the ground.

Every support column 5.1 inside be cavity and all install a servo motor 5.3, servo motor 5.3 below install energy storage battery 5.5, energy storage battery 5.5 be located support column 5.1 inside.

A push rod 5.4 is arranged above the servo motor 5.3, and the servo motor 5.3 is hinged with the bottom of the shed roof 1 through the push rod 5.4.

The servo motor 5.3 can drive the push rod 5.4 to do telescopic motion along the axial direction of the support column 5.1.

The shed roof 1 of the shed adopts a plane rectangular structure, and a photovoltaic plate 2 is laid. The lower side of photovoltaic board 2 is equipped with reflector layer 3, and roof 1 has seted up rainwater guiding gutter 4 along the edge of photovoltaic board 2. The two ends of the shed roof 1 in the north and south are respectively provided with a group of supporting column mechanisms 5, each supporting column mechanism 5 is composed of two supporting columns 5.1 arranged in a V shape and a base 5.2, the bottom surfaces of the two supporting columns 5.1 are fixed on the base 5.2, and the base 5.2 is fixed on the ground.

Support column 5.1 is hollow structure, all is equipped with a servo motor 5.3 in every support column 5.1, is equipped with energy storage battery 5.5 in the support column 5.1 inner chamber of servo motor 5.3 below, and energy storage battery 5.5 both can store the electric energy that photovoltaic board 2 sent, also can charge for the electric motor car, also can drive servo motor 5.3, also can be for the power supply of bicycle shed lighting device, also can be networked with outside electric wire netting in order to stabilize electric wire netting wave peak and trough. A push rod connected with the servo motor 5.3 is arranged above the servo motor 5.3, and the servo motor 5.3 can drive the push rod to do telescopic motion along the axial direction of the support column 5.1. The upper end of the push rod 5.4 is hinged with the bottom of the ceiling 1.

According to the number of the parking spaces in each row, a plurality of groups of supporting mechanisms 5.1 can be arranged at intervals in the north-south direction. In daytime, the photovoltaic panel 2 ensures that sunlight irradiates the photovoltaic panel as far as possible through the movement of four servo devices 5.3, and high-efficiency power generation is ensured. The generated electric quantity is stored by the energy storage battery 5.5, and the extra electric quantity is reversely transmitted to an external power grid. At night, the photovoltaic panel 2 stops generating electricity, the energy storage battery 5.5 charges the electric vehicle through the electric quantity stored in the energy storage battery, supplies power to peripheral facilities (lighting equipment, a camera, a toll station and the like) of the shed, and the energy storage battery charges itself at night when the electricity price is lowered.

In the process of charging and discharging the energy storage battery 5.5, the outer wall of the support column 5.1 can be used as a heat dissipation layer of the energy storage battery, and the energy storage battery passively dissipates heat in a blowing mode. Compared with the ceiling 1, the V-shaped support column mechanism 5 is retracted inside, so that direct wind and rain can be avoided in rainy days, and the outer wall of the support column 5.1 can also be used as a waterproof layer.

The above-mentioned parts which are not described in detail are prior art.

Claims (4)

1. A photovoltaic energy storage carport comprises a carport top (1), photovoltaic panels (2), a reflecting layer (3), a rainwater diversion trench (4) and a supporting mechanism (5), wherein the photovoltaic panels (2) are paved on the carport top (1), the reflecting layer (3) is arranged below the photovoltaic panels (2), the reflecting layer (3) is positioned between the carport top (1) and the photovoltaic panels (2),

the greenhouse roof (1) is provided with a rainwater flow guide groove (4) along the edge of the photovoltaic panel (2), and a supporting mechanism (5) is arranged below the greenhouse roof (1);

the method is characterized in that: supporting mechanism (5) including support column (5.1), base (5.2), servo motor (5.3), push rod (5.4) and energy storage battery (5.5) that are the V style of calligraphy, support column (5.1) fix on base (5.2), base (5.2) fix subaerial.

2. The photovoltaic energy storage carport of claim 1, characterized in that: every support column (5.1) inside be cavity and all install a servo motor (5.3), servo motor (5.3) below install energy storage battery (5.5), energy storage battery (5.5) be located support column (5.1) inside.

3. A photovoltaic energy storage bicycle shed as claimed in claim 1 or 2, wherein: a push rod (5.4) is arranged above the servo motor (5.3), and the servo motor (5.3) is hinged with the bottom of the shed roof (1) through the push rod (5.4).

4. The photovoltaic energy storage carport of claim 3, characterized in that: the servo motor (5.3) can drive the push rod (5.4) to do telescopic motion along the axial direction of the support column (5.1).

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