CN221652566U - Portable photovoltaic power generation monitoring device - Google Patents

Abstract

The application provides a portable photovoltaic power generation monitoring device, which relates to the technical field of photovoltaic module monitoring and comprises an inclination sensor and a display, wherein the bottom of the inclination sensor is connected with a sliding cover in an assembling manner, the bottom of the sliding cover is connected with a supporting seat in a sliding manner, and the tops of two sides of the supporting seat are respectively provided with a limiting slide bar; the bottom of the sliding cover is provided with a second wire slot, and the top of the supporting seat is provided with a first wire slot; the technical key points are as follows: through utilizing the spacing draw runner at supporting seat both sides top to provide movable track for the sliding closure at the top of supporting seat, make the sliding closure slide to one side in the supporting seat top, make the display expose in the field of vision from the top of supporting seat one end, make things convenient for the supporting seat to lean on in one side of photovoltaic module, make the bottom of sliding closure laminate mutually with photovoltaic module's surface, be favorable to carrying out the monitoring work of photovoltaic module inclination condition with the help of inclination sensor to with the detection data display on the display, be observed by the staff.

Description

Portable photovoltaic power generation monitoring device

Technical Field

The utility model relates to the technical field of photovoltaic module monitoring, in particular to a portable photovoltaic power generation monitoring device.

Background

Photovoltaic power generation is a technology that uses the photovoltaic effect of a semiconductor interface to directly convert light energy into electrical energy. The solar energy power generation system mainly comprises three parts of a solar panel (assembly), a controller and an inverter, wherein the main parts are composed of electronic components. The solar cells are packaged and protected after being connected in series to form a large-area solar cell module, and then the solar cell module is matched with components such as a power controller and the like to form the photovoltaic power generation device.

According to the portable photovoltaic power generation and power station operation and maintenance monitoring simulation device disclosed by the patent document No. CN217904359U, the supporting rod is hinged on the photovoltaic module, the hinged axis of the photovoltaic module and the supporting rod is parallel to the hinged axis of the photovoltaic module and the supporting plate, the other end of the supporting rod is hinged with the sliding block nut, the sliding block nut is movably supported on the supporting plate, the screw rod which is rotatably connected with the sliding block nut is rotatably supported on the supporting plate, the axial space of the screw rod vertically crosses the hinged axis of the photovoltaic module and the supporting plate, the position of the sliding block nut in the axial direction of the screw rod can be changed through rotating the screw rod, the supporting rod with the two ends respectively hinged with the sliding block nut and the photovoltaic module is equivalent to a connecting rod, after the position of the sliding block nut in the axial direction of the screw rod is changed, the high and low positions of one ends hinged with the photovoltaic module on the supporting rod can be changed, so that the photovoltaic module rotates around the hinged axis of the supporting rod, the high and low angles of the photovoltaic module are changed, the light receiving surface of the photovoltaic module and the solar light are vertical to the supporting plate in the high and low directions, or the high angles of the photovoltaic module and the low angles of the photovoltaic module are adjusted to the photovoltaic module are distributed in the high and low angles, and the photovoltaic module is conveniently monitored.

However, in the process of implementing the above technical solution, the following technical problems are found in the above technical solution:

The installation angle of the photovoltaic module can be changed in the installation process of the photovoltaic module by the existing photovoltaic power generation and power station operation and maintenance monitoring simulation device, so that the controllability is improved, but in the conventional inspection process, the use of the device is not beneficial to improving the detection efficiency, so that the efficient photovoltaic module installation angle adjustment work is performed.

Disclosure of utility model

In order to overcome the defects that the use of the device is not beneficial to improving the detection efficiency in the conventional inspection process of the existing photovoltaic power generation and power station operation and maintenance monitoring simulation device, and therefore the efficient photovoltaic module installation angle adjustment work is carried out, the portable photovoltaic power generation monitoring device is provided by the embodiment of the application, the limiting sliding strips at the tops of the two sides of the supporting seat are utilized to provide the sliding cover with the movable track at the top of the supporting seat, when the sliding cover slides to one side at the top of the supporting seat, the supporting spring between one side of the supporting strip and the inner wall at one end of the second wire slot is compressed, the display is exposed in the visual field from the top of one end of the supporting seat, the supporting seat is conveniently leaned against one side of the photovoltaic module through the anti-sliding strip, the bottom end of the sliding cover is attached to the surface of the photovoltaic module, the monitoring work of the inclination angle condition of the photovoltaic module can be carried out by means of the inclination sensor, and the detection data is displayed on the display, and the portable photovoltaic power generation monitoring device is simple and convenient.

The technical scheme adopted by the embodiment of the application for solving the technical problems is as follows:

The portable photovoltaic power generation monitoring device comprises an inclination sensor and a display, wherein the display is arranged on one side of the inclination sensor;

The bottom of the inclination sensor is connected with a sliding cover in an assembling mode, the bottom of the sliding cover is connected with a supporting seat in a sliding mode, and the display is connected inside one side of the supporting seat in an embedded mode.

In one possible implementation manner, the top parts of two sides of the supporting seat are respectively provided with a limiting sliding strip, and the two limiting sliding strips are respectively connected inside two sides of the sliding cover in a sliding mode.

In one possible implementation manner, a second wire slot is formed in the bottom of the sliding cover, a first wire slot is formed in the top of the supporting seat, the inside of the second wire slot is communicated with the inside of the first wire slot, and a wire on the inclination sensor penetrates through the inside of the sliding cover and is connected with a circuit inside the display through the inside of the first wire slot and the inside of the second wire slot.

In one possible implementation manner, a supporting board strip is machined at the top of one end of the supporting seat, two supporting rods are machined on one side of the supporting board strip, supporting springs are connected to the outer parts of the two supporting rods in a sleeved mode, two ends of each supporting spring are respectively supported between one side of the supporting board strip and the inner wall of one end of the second wire slot, and the sliding cover is connected to the outer parts of the two supporting springs in a sliding mode.

In one possible implementation manner, the magnets are embedded in the two sides of one end of the supporting seat, the metal strips are embedded in the two sides of one end of the sliding cover, and the two magnets are respectively adsorbed with the two metal strips.

In one possible implementation manner, an anti-slip strip is connected to the inside of one end of the supporting seat in an embedded manner, the anti-slip strip is made of rubber materials, and the anti-slip strip is located on one side of the sliding cover upper inclination sensor.

In one possible implementation manner, a detection notch is machined at the bottom of one end of the sliding cover, the inner angle of the detection notch is a right angle, and the inner part of the detection notch is communicated with the inner part of the second wire slot.

In summary, the present utility model includes at least one of the following beneficial technical effects:

1. The limiting sliding strips at the tops of the two sides of the supporting seat are utilized to provide a movable track for the sliding cover at the top of the supporting seat, when the sliding cover slides to one side at the top of the supporting seat, the supporting spring between one side of the supporting strip and the inner wall of one end of the second wire slot is compressed, the display is exposed in the visual field from the top of one end of the supporting seat, the supporting seat can lean against one side of the photovoltaic module through the anti-sliding strips, the bottom end of the sliding cover is attached to the surface of the photovoltaic module, the monitoring work of the inclination angle condition of the photovoltaic module is conveniently carried out by means of the inclination angle sensor, and detection data are displayed on the display;

2. The support spring is supported between the inner wall of one end of the second wire slot and one side of the support lath, and two magnets are respectively adsorbed with the two metal strips, so that the sliding cover can form stable protection on the display at the top of the support seat;

3. through processing the detection notch in the bottom of sliding closure one end, when making the sliding closure detain on the angle bar through detecting the notch, can detect whether the sliding closure keeps parallel with the angle bar base to approve the detection precision of the inclination sensor on the sliding closure.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic diagram of a connection structure of a support base and a sliding cover according to the present utility model;

FIG. 3 is a second schematic diagram of the connection structure of the support base and the sliding cover of the present utility model;

FIG. 4 is a schematic view of a support base according to the present utility model;

Fig. 5 is a schematic view of the diagonal bracing member structure of the present utility model.

Description of the drawings: 1. an inclination sensor; 2. a sliding cover; 3. a support base; 4. a support rod; 5. a first wire chase; 6. a display; 7. a magnet; 8. detecting a notch; 9. a second wire slot; 10. an anti-slip strip; 11. a support slat; 12. a limit slide bar; 13. a support spring; 14. a metal strip.

Detailed Description

The technical scheme in the embodiment of the application aims to solve the problems of the background technology, and the general thought is as follows:

Example 1:

The embodiment introduces a specific structure of a portable photovoltaic power generation monitoring device, and particularly referring to fig. 1-5, the portable photovoltaic power generation monitoring device comprises an inclination sensor 1 and a display 6 arranged on one side of the inclination sensor 1, wherein the bottom of the inclination sensor 1 is connected with a sliding cover 2 in an assembling manner, the bottom of the sliding cover 2 is connected with a supporting seat 3 in a sliding manner, and the display 6 is connected inside one side of the supporting seat 3 in an embedded manner;

In order to make the sliding cover 2 slide stably on the top of the supporting seat 3, as shown in fig. 3 and fig. 4, the top of two sides of the supporting seat 3 is processed with a limiting sliding strip 12, and by making two limiting sliding strips 12 respectively slide-connected in two sides of the sliding cover 2, a movable track can be provided for the sliding cover 2 to move on the top of the supporting seat 3;

meanwhile, when the sliding cover 2 slides on the top of the supporting seat 3, the display 6 is exposed from the inside of the supporting seat 3, one end of the supporting seat 3 is supported on one side of the photovoltaic module, the bottom end of the sliding cover 2 is attached to the surface of the photovoltaic module, and the inclination angle data can be displayed on the display 6 by monitoring through the inclination angle sensor 1;

Secondly, in order to enable the lead between the tilt sensor 1 and the display 6 to adapt to the movement of the sliding cover 2 at the top of the supporting seat 3, as shown in fig. 3 and 4, a second wire groove 9 is processed at the bottom of the sliding cover 2, a first wire groove 5 is processed at the top of the supporting seat 3, the interior of the second wire groove 9 is communicated with the interior of the first wire groove 5, the lead on the tilt sensor 1 passes through the interior of the sliding cover 2 and is connected with the circuit in the display 6 through the interiors of the first wire groove 5 and the second wire groove 9, and when the sliding cover 2 moves at the top of the supporting seat 3, the lead can be stretched and retracted;

In order to prevent the sliding cover 2 from slipping off the top of the supporting seat 3, as shown in fig. 3 and 4, a supporting slat 11 is formed on the top of one end of the supporting seat 3, two supporting rods 4 are formed on one side of the supporting slat 11, supporting springs 13 are connected to the outer parts of the two supporting rods 4 in a sleeved mode, and by supporting the two ends of the supporting springs 13 between one side of the supporting slat 11 and the inner wall of one end of the second wire slot 9, when the sliding cover 2 slides on the top of the supporting seat 3, the sliding cover 2 can be connected to the outer parts of the two supporting springs 13 in a sliding manner, so that the supporting springs 13 are compressed, and after the sliding cover 2 is released, the sliding cover 2 can be reset on the top of the supporting seat 3 by means of elastic relaxation of the supporting springs 13;

in some examples, the magnet 7 is connected in an embedded manner to the inner parts of two sides of one end of the supporting seat 3, and the metal strip 14 is connected in an embedded manner to the inner parts of two sides of one end of the sliding cover 2;

The two magnets 7 are respectively adsorbed with the two metal strips 14, so that the sliding cover 2 is stably connected with the supporting seat 3 under the action of no external force, and the sliding cover 2 forms protection on the display 6 at the top of the supporting seat 3;

Secondly, in order to prevent the support seat 3 from sliding relative to the photovoltaic module when one end of the support seat 3 leans against the surface of the photovoltaic module, as shown in fig. 3, the inside of one end of the support seat 3 is embedded with the anti-slip strip 10, and the anti-slip strip 10 is made of rubber material by using the rubber material, so that the anti-slip strip 10 is positioned on one side of the tilt sensor 1 on the sliding cover 2, and the stable leaning of one end of the support seat 3 on the photovoltaic module can be ensured by means of the friction force between the surface of the anti-slip strip 10 and the surface of the photovoltaic module.

By adopting the technical scheme:

According to the design, the limiting sliding strips 12 on the tops of the two sides of the supporting seat 3 are utilized to provide a movable track for the sliding cover 2 on the top of the supporting seat 3, when the sliding cover 2 slides to one side on the top of the supporting seat 3, the supporting springs 13 between one side of the supporting strip 11 and the inner wall of one end of the second wire slot 9 are compressed, the display 6 is exposed in the visual field from the top of one end of the supporting seat 3, the supporting seat 3 is convenient to lean against one side of the photovoltaic module through the anti-sliding strip 10, the bottom end of the sliding cover 2 is attached to the surface of the photovoltaic module, so that the monitoring work of the inclination angle condition of the photovoltaic module is carried out by means of the inclination angle sensor 1, detection data are displayed on the display 6, and the monitoring work is simple and convenient;

Meanwhile, when the compressed supporting spring 13 is reset outside the supporting rod 4, the sliding cover 2 is pushed to move to the top of the supporting seat 3, and the two magnets 7 are respectively adsorbed with the two metal strips 14, so that the sliding cover 2 is stably connected with the supporting seat 3 under the action of no external force, and the sliding cover 2 can form protection on the display 6 at the top of the supporting seat 3.

Example 2:

Based on embodiment 1, this embodiment describes a specific structure of the sliding cover 2, and a detection notch 8 is machined at the bottom of one end of the sliding cover 2;

Wherein, the interior angle of detecting notch 8 is the right angle, through making the inside that detects notch 8 be linked together with the inside of second wire casing 9, when the sliding closure 2 of being convenient for detains on the angle bar through detecting notch 8, detects whether sliding closure 2 keeps parallel with the angle bar base to approve the detection precision of sliding closure 2 tilt angle sensor 1.

By adopting the technical scheme:

according to the design, the detection notch 8 is processed at the bottom of one end of the sliding cover 2, the inside of the detection notch 8 is communicated with the inside of the second wire slot 9, and when the sliding cover 2 is buckled on angle irons through the detection notch 8, the angle irons can be extended to the inside of the second wire slot 9, so that whether the sliding cover 2 is parallel to an angle iron base or not is detected, and the detection precision of the inclination sensor 1 on the sliding cover 2 is approved.

Finally, it should be noted that: it is apparent that the above examples are only illustrative of the present utility model 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. And obvious variations or modifications thereof are contemplated as falling within the scope of the present utility model.

Claims (7)

1. Portable photovoltaic power generation monitoring devices, its characterized in that includes:

an inclination sensor (1);

a display (6) provided on one side of the tilt sensor (1);

The bottom of the inclination sensor (1) is connected with a sliding cover (2) in an assembling mode, the bottom of the sliding cover (2) is connected with a supporting seat (3) in a sliding mode, and the display (6) is connected inside one side of the supporting seat (3) in an embedded mode.

2. The portable photovoltaic power generation monitoring device of claim 1, wherein: the top of supporting seat (3) both sides all is processed spacing draw runner (12), and two spacing draw runner (12) are respectively sliding connection in the inside of sliding closure (2) both sides.

3. The portable photovoltaic power generation monitoring device of claim 1, wherein: the bottom of the sliding cover (2) is provided with a second wire groove (9), and the top of the supporting seat (3) is provided with a first wire groove (5);

The inside of the second wire slot (9) is communicated with the inside of the first wire slot (5), and a wire on the inclination sensor (1) passes through the inside of the sliding cover (2) and is connected with a circuit inside the display (6) through the inside of the first wire slot (5) and the inside of the second wire slot (9).

4. A portable photovoltaic power generation monitoring device according to claim 3, wherein: the top of one end of the supporting seat (3) is provided with a supporting lath (11), one side of the supporting lath (11) is provided with two supporting rods (4), and the outer parts of the two supporting rods (4) are respectively connected with a supporting spring (13) in a sleeved mode;

The two ends of the supporting springs (13) are respectively supported between one side of the supporting lath (11) and the inner wall of one end of the second wire slot (9), and the sliding cover (2) is connected to the outer parts of the two supporting springs (13) in a sliding mode.

5. The portable photovoltaic power generation monitoring device of claim 1, wherein: the magnet (7) is embedded and connected in the inner parts of two sides of one end of the supporting seat (3), and the metal strip (14) is embedded and connected in the inner parts of two sides of one end of the sliding cover (2);

Wherein the two magnets (7) are respectively attracted with the two metal strips (14).

6. The portable photovoltaic power generation monitoring device of claim 1, wherein: the anti-slip strip (10) is connected to the inside of supporting seat (3) one end in an embedded mode, the anti-slip strip (10) is made of rubber materials, and the anti-slip strip (10) is located on one side of the inclination sensor (1) on the sliding cover (2).

7. A portable photovoltaic power generation monitoring device according to claim 3, wherein: the bottom of sliding closure (2) one end is processed has detection notch (8), the interior angle of detection notch (8) is the right angle, the inside of detection notch (8) is linked together with the inside of second wire casing (9).