CN113803587A - Photovoltaic power generation monitoring system and method based on data analysis - Google Patents

Abstract

The invention relates to the technical field of detection devices, in particular to a photovoltaic power generation monitoring system and a method based on data analysis, wherein a sliding block is connected with a sliding groove of a mounting frame, a support is connected with the sliding block, a first buffer spring is connected with the sliding block, the first buffer spring is connected with the mounting frame, a side plate is connected with the support, a transparent plate is connected with the side plate, a photovoltaic cell panel is connected with the side plate, an illumination sensor, a temperature sensor and a monitoring mechanism are connected with the photovoltaic cell panel, the photovoltaic cell panel is fixed through the mounting frame, when the foreign matter drops to the photovoltaic cell board that drops, the transparent plate during the foreign matter pounces, the direction of slider follow force passes through the first buffer spring of transparent plate sliding extrusion on the spout on the support drives the curb plate, and first buffer spring cushions the impact force, has solved photovoltaic cell board, light intensity sensor and temperature sensor and has directly exposed outside, causes the problem of damage in pounding by the foreign matter easily.

Description

Photovoltaic power generation monitoring system and method based on data analysis

Technical Field

The invention relates to the technical field of detection devices, in particular to a photovoltaic power generation monitoring system and method based on data analysis.

Background

The distributed photovoltaic power generation is used as an important component of new energy, has the characteristics of flexible power generation mode, environmental protection, economy and compatibility with the environment, has important significance for optimizing energy structure, promoting energy conservation and emission reduction and realizing economic sustainable development, and can prevent electricity stealing from users and units lacking integrity through a photovoltaic power generation monitoring system based on data analysis;

the monitoring mechanism of the existing photovoltaic power generation monitoring system based on data analysis calculates the output condition of generated energy based on the collected information of an illumination sensor and a temperature sensor on a photovoltaic cell panel and compares the calculated output condition with the predicted generated energy, and when the output electric quantity is compared to be abnormal, an abnormal prompt is sent to a worker;

however, the photovoltaic cell panel, the illumination sensor and the temperature sensor are directly exposed outside and are easily damaged by being hit by foreign matters, so that the monitoring condition of photovoltaic power generation is influenced.

Disclosure of Invention

The invention aims to provide a photovoltaic power generation monitoring system and method based on data analysis, and aims to solve the problem that a photovoltaic cell panel, an illumination sensor and a temperature sensor are directly exposed and are easily damaged by foreign matters.

In order to achieve the above object, in a first aspect, the present invention provides a photovoltaic power generation monitoring system based on data analysis, including a mounting mechanism, a collecting mechanism and a monitoring mechanism;

the mounting mechanism comprises a mounting frame, four sliding blocks, four brackets, four first buffer springs, a side plate, a transparent plate, two connecting plates and a plurality of second buffer springs; the mounting frame is provided with four sliding grooves, four sliding blocks are respectively connected with the mounting frame in a sliding manner and are all positioned in the sliding grooves, four supports are respectively fixedly connected with four sliding blocks and are all positioned at one side far away from the mounting frame, one side of four first buffer springs is respectively fixedly connected with four sliding blocks, the other side of four first buffer springs is respectively fixedly connected with the mounting frame and is all positioned in the sliding grooves, the side plate is fixedly connected with four supports and is all positioned at one side far away from the sliding blocks, the transparent plate is fixedly connected with the side plate and is all positioned at the inner side wall of the side plate, two connecting plates are respectively fixedly connected with the side plate and are respectively positioned at the outer side wall of the connecting plate, one side of a plurality of second buffer springs is respectively fixedly connected with the mounting frame, and the other side of a plurality of second buffer springs is respectively fixedly connected with two connecting plates, are positioned between the mounting rack and the connecting plate;

the collecting mechanism comprises a photovoltaic cell panel, an illumination sensor and a temperature sensor, the photovoltaic cell panel is fixedly connected with the side plate and is positioned on the inner side wall of the side plate, the illumination sensor is fixedly connected with the photovoltaic cell panel and is positioned close to one side of the transparent plate, the temperature sensor is fixedly connected with the photovoltaic cell panel and is positioned close to one side of the transparent plate, and the monitoring mechanism is fixedly connected with the photovoltaic cell panel and is positioned far away from one side of the illumination sensor.

When foreign matters drop to the photovoltaic cell panel, the foreign matters hit the transparent plate, the direction of the slider following force drives the transparent plate on the side plate to slide on the sliding groove through the support to extrude the first buffer spring, the first buffer spring buffers the impact force, and meanwhile the connecting plate on the side plate stretches the second buffer spring on the mounting frame to enable the second buffer spring to buffer the impact force for the second time.

Wherein, installation mechanism still includes two mounting panels, two the mounting panel respectively with mounting bracket fixed connection, and be located the both sides of mounting bracket.

The mounting frame is fixed on the mounting surface through the mounting plate.

The mounting mechanism further comprises a baffle, and the baffle is fixedly connected with the side plate and is positioned on the inner side wall of the side plate.

The baffle seals an outlet of the side plate close to the monitoring mechanism, so that foreign matters are prevented from influencing the work of the monitoring mechanism.

Wherein, installation mechanism still includes first dust screen, the curb plate has first air intake, first dust screen with curb plate fixed connection, and be located first air intake department.

The cold air is followed first air inlet department gets into the curb plate inside wall the transparent plate with between the photovoltaic cell board, it is right photovoltaic cell board illumination sensor with temperature sensor cools down.

The mounting mechanism further comprises a second dust screen and an air exhaust assembly, the side plate is provided with a second air inlet, the second dust screen is fixedly connected with the side plate and located at the second air inlet, and the air exhaust assembly is fixedly connected with the side plate and penetrates through the side plate.

The cold air enters the side plate inner side wall from the second air inlet, the baffle is arranged between the photovoltaic cell panel and the photovoltaic cell panel, the photovoltaic cell panel and the monitoring mechanism are cooled, the hot air of the side plate inner side wall is pumped out by the air exhaust assembly, the speed of the cold air entering the side plate inner side wall from the first air inlet and the second air inlet is increased, and therefore the heat dissipation efficiency is improved.

The monitoring mechanism comprises a calculation module, a comparison module and a transmission module, wherein the calculation module is fixedly connected with the baffle and is positioned close to one side of the photovoltaic cell panel, the illumination sensor is electrically connected with the temperature sensor, the comparison module is electrically connected with the calculation module and is positioned close to one side of the photovoltaic cell panel, and the transmission module is electrically connected with the comparison module and is positioned close to one side of the photovoltaic cell panel.

The calculation module calculates the output condition of the generated energy based on the collected information of the illumination sensor and the temperature sensor to obtain the actual generated energy, the comparison module compares the actual generated energy calculated by the calculation module with the predicted generated energy, and the transmission module transmits the comparison information of the comparison module to the user side.

In a second aspect, the present invention provides a photovoltaic power generation monitoring method based on data analysis, including:

the illumination sensor collects illumination conditions on the photovoltaic cell panel;

the temperature sensor collects the temperature condition on the photovoltaic cell panel;

the calculation module calculates the output condition of the generated energy based on the acquired information of the illumination sensor and the temperature sensor to obtain the actual generated energy;

the comparison module compares the actual power generation amount calculated by the calculation module with the predicted power generation amount;

the transmission module transmits the comparison information of the comparison module to the user side.

According to the photovoltaic power generation monitoring system based on data analysis, when foreign matters fall off the photovoltaic cell panel, the foreign matters hit the transparent plate, the direction of the slider following force drives the transparent plate on the side plate to slide on the sliding groove through the support to extrude the first buffer spring, the first buffer spring buffers the impact force, meanwhile, the connecting plate on the side plate stretches the second buffer spring on the mounting frame, so that the second buffer spring buffers the impact force for the second time, and the problem that the photovoltaic cell panel, the illumination sensor and the temperature sensor are directly exposed outside and are easily damaged by the foreign matters due to the fact that the photovoltaic cell panel, the illumination sensor and the temperature sensor are directly exposed outside is solved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a photovoltaic power generation monitoring system based on data analysis provided by the invention;

FIG. 2 is a side view of a photovoltaic power generation monitoring system based on data analysis provided by the present invention;

FIG. 3 is a cross-sectional view of a photovoltaic power generation monitoring system based on data analysis, taken along a first air inlet direction, according to the present invention;

FIG. 4 is a cross-sectional view of a photovoltaic power generation monitoring system based on data analysis, taken along the direction of an aspiration tube, according to the present invention;

fig. 5 is a flowchart of a photovoltaic power generation monitoring method based on data analysis according to the present invention.

1-an installation mechanism, 2-an acquisition mechanism, 3-a monitoring mechanism, 4-an installation rack, 5-a chute, 6-a slide block, 7-a support, 8-a first buffer spring, 9-a side plate, 10-a transparent plate, 11-a connecting plate, 12-a second buffer spring, 13-a photovoltaic cell panel, 14-a light sensor and 15-a temperature sensor, 16-mounting plate, 17-baffle, 18-first air inlet, 19-first dust screen, 20-second air inlet, 21-second dust screen, 22-air exhaust component, 23-calculation module, 24-comparison module, 25-transmission module, 26-air suction pipe, 27-suction fan, 28-exhaust pipe, 29-air suction hole and 30-expansion pipe.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention.

In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships illustrated in the drawings, and are used merely for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Further, in the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Referring to fig. 1 to 4, in a first aspect, the present invention provides a photovoltaic power generation monitoring system based on data analysis, including a mounting mechanism 1, a collecting mechanism 2 and a monitoring mechanism 3;

the mounting mechanism 1 comprises a mounting frame 4, four sliding blocks 6, four supports 7, four first buffer springs 8, a side plate 9, a transparent plate 10, two connecting plates 11 and a plurality of second buffer springs 12; the mounting frame 4 is provided with four sliding grooves 5, four sliding blocks 6 are respectively connected with the mounting frame 4 in a sliding manner and are all positioned in the sliding grooves 5, four supports 7 are respectively fixedly connected with the four sliding blocks 6 and are all positioned at one side far away from the mounting frame 4, one side of each of four first buffer springs 8 is respectively fixedly connected with the four sliding blocks 6, the other side of each of the four first buffer springs 8 is respectively fixedly connected with the mounting frame 4 and is all positioned in the sliding grooves 5, the side plate 9 is fixedly connected with the four supports 7 and is all positioned at one side far away from the sliding blocks 6, the transparent plate 10 is fixedly connected with the side plate 9 and is all positioned at the inner side wall 9 of the side plate, two connecting plates 11 are respectively fixedly connected with the side plate 9 and are all positioned at the outer side wall of the connecting plate 11, and one side of a plurality of second buffer springs 12 is respectively fixedly connected with the mounting frame 4, the other sides of the second buffer springs 12 are respectively fixedly connected with the two connecting plates 11 and are positioned between the mounting rack 4 and the connecting plates 11;

gather mechanism 2 and include photovoltaic cell board 13, light sensor 14 and temperature sensor 15, photovoltaic cell board 13 with curb plate 9 fixed connection, and be located 9 inside walls of curb plate, light sensor 14 and photovoltaic cell board 13 fixed connection, and be located and be close to one side of transparent plate 10, temperature sensor 15 with photovoltaic cell board 13 fixed connection, and be located and be close to one side of transparent plate 10, monitoring mechanism 3 with photovoltaic cell board 13 fixed connection, and be located and keep away from one side of light sensor 14.

In this embodiment, the collecting mechanism 2 and the monitoring mechanism 3 are fixed on a mounting surface through the mounting frame 4 of the mounting mechanism 1, and a movable space is reserved for the connecting plate 11, the photovoltaic cell panel 13 of the collecting mechanism 2 is fixed on the inner side wall of the side plate 9, the illumination sensor 14 and the temperature sensor 15 are fixed on the sunny side of the photovoltaic cell panel 13, and collect the illumination condition and the temperature condition of the photovoltaic cell panel 13, the monitoring mechanism 3 calculates the output condition of the generated energy based on the collected information of the illumination sensor 14 and the temperature sensor 15 and compares the calculated generated energy with the predicted generated energy, when the output energy is abnormal, an abnormal prompt is sent to a worker, when a foreign object falls off the photovoltaic cell panel 13, the transparent plate 10 is hit by the foreign object, the sliding block 6 drives the transparent plate 10 on the side plate 9 to slide on the sliding groove 5 to extrude the first buffer spring 8 through the support 7 in the direction of force, the first buffer spring 8 buffers the impact force, meanwhile, the connecting plate 11 on the side plate 9 stretches the second buffer spring 12 on the mounting frame 4, so that the second buffer spring 12 buffers the impact force for the second time, the photovoltaic cell panel 13 is prevented from being directly impacted by foreign matters, the side plate 9 and the transparent plate 10 are both high-light-transmission organic glass plates, the contact of sunlight on the photovoltaic cell panel 13 is not influenced, and the problem that the photovoltaic cell panel 13, the illumination sensor 14 and the temperature sensor 15 are directly exposed outside and are easily damaged by pounding the foreign matters is solved.

Further, the mounting mechanism 1 further comprises two mounting plates 16, and the two mounting plates 16 are respectively and fixedly connected with the mounting frame 4 and are located at two sides of the mounting frame 4; the mounting mechanism 1 further comprises a baffle 17, wherein the baffle 17 is fixedly connected with the side plate 9 and is positioned on the inner side wall of the side plate 9; the mounting mechanism 1 further comprises a first dust screen 19, the side plate 9 is provided with a first air inlet 18, and the first dust screen 19 is fixedly connected with the side plate 9 and is located at the first air inlet 18; the mounting mechanism 1 further comprises a second dust screen 21 and an air exhaust assembly 22, the side plate 9 is provided with a second air inlet 20, the second dust screen 21 is fixedly connected with the side plate 9 and located at the second air inlet 20, and the air exhaust assembly 22 is fixedly connected with the side plate 9 and penetrates through the side plate 9.

In this embodiment, the mounting frame 4 is fixed on the mounting surface through the mounting plate 16, the baffle 17 seals an outlet of the side plate 9 near the monitoring mechanism 3 to prevent foreign matters from affecting the operation of the monitoring mechanism 3, cold air enters between the transparent plate 10 and the photovoltaic cell panel 13 on the inner side wall of the side plate 9 from the first air inlet 18 to cool the photovoltaic cell panel 13, the illumination sensor 14 and the temperature sensor 15, cold air enters between the baffle 17 and the photovoltaic cell panel 13 on the inner side wall of the side plate 9 from the second air inlet 20 to cool the photovoltaic cell panel 13 and the monitoring mechanism 3, the exhaust assembly 22 extracts hot air on the inner side wall of the side plate 9 to accelerate the speed of the cold air entering the inner side wall of the side plate 9 from the first air inlet 18 and the second air inlet 20, thereby increasing heat dissipation efficiency.

Further, the monitoring mechanism 3 includes a calculating module 23, a comparing module 24 and a transmission module 25, the calculating module 23 is fixedly connected to the baffle 17 and is located near one side of the photovoltaic cell panel 13, the illumination sensor 14 and the temperature sensor 15 are electrically connected to the calculating module 23, the comparing module 24 is electrically connected to the calculating module 23 and is located near one side of the photovoltaic cell panel 13, and the transmission module 25 is electrically connected to the comparing module 24 and is located near one side of the photovoltaic cell panel 13.

In this embodiment, the calculation module 23 calculates an output condition of power generation based on the collected information of the illumination sensor 14 and the temperature sensor 15 to obtain an actual power generation amount, the comparison module 24 compares the actual power generation amount calculated by the calculation module 23 with a predicted power generation amount, the transmission module 25 transmits the comparison information of the comparison module 24 to a user side, the model of the illumination sensor 14 is BH1750FVI, and the model of the temperature sensor 15 is PT 100.

Further, the exhaust assembly 22 includes a suction fan 27, an air suction pipe 26 and an exhaust pipe 28, the suction fan 27 is fixedly connected to the side plate 9 and is located on the inner side wall of the side plate 9, the air suction pipe 26 is fixedly connected to the suction fan 27 and penetrates through the photovoltaic cell panel 13, the exhaust pipe 28 is fixedly connected to the suction fan 27 and penetrates through the side plate 9, and the air suction pipe 26 has two air suction holes 29.

In this embodiment, the suction fan 27 drives the suction pipe 26 to deliver the hot air on the inner side wall of the side plate 9 to the exhaust pipe 28 through the suction hole 29 for discharge.

Further, the exhaust assembly 22 further includes two expansion pipes 30, and the two expansion pipes 30 are respectively and fixedly connected to the air suction pipe 26 and are located at the air suction hole 29.

In the present embodiment, the expansion duct 30 increases the suction range of the suction duct 26, thereby increasing the speed of extracting the hot air from the inner side wall of the side plate 9.

Referring to fig. 5, in a second aspect, the present invention provides a photovoltaic power generation monitoring method based on data analysis, including:

s101, an illumination sensor 14 collects illumination conditions on a photovoltaic cell panel 13;

the illumination sensor 14 is mounted on the sunny side of the photovoltaic cell panel 13.

S102, collecting the temperature condition of the photovoltaic cell panel 13 by the temperature sensor 15;

the temperature sensor 15 and the illumination sensor 14 need to collect data at the same time.

S103, calculating the output condition of the generated energy by the calculating module 23 based on the collected information of the illumination sensor 14 and the temperature sensor 15 to obtain the actual generated energy;

the cold air enters the space between the baffle 17 on the inner side wall of the side plate 9 and the photovoltaic cell panel 13 from the second air inlet 20, and cools the photovoltaic cell panel 13 and the calculation module 23.

S104, the comparison module 24 compares the actual power generation amount calculated by the calculation module 23 with the predicted power generation amount;

when the actual generated energy is higher than the predicted generated energy, the power utilization abnormality is present.

And S105, the transmission module 25 transmits the comparison information of the comparison module 24 to the user side.

And if the comparison information transmitted by the transmission module 25 is received by the user staff at the user end to be abnormal, the user staff monitors the electricity stealing.

While the invention has been described with reference to a preferred embodiment of a data analysis-based photovoltaic power generation monitoring system and method, it will be understood by those skilled in the art that the invention is not limited thereto, and that all or a portion of the procedures for carrying out the disclosed embodiment may be equally varied, and still fall within the scope of the invention.

Claims (7)

1. A photovoltaic power generation monitoring system based on data analysis is characterized by comprising an installation mechanism, an acquisition mechanism and a monitoring mechanism;

the mounting mechanism comprises a mounting frame, four sliding blocks, four brackets, four first buffer springs, a side plate, a transparent plate, two connecting plates and a plurality of second buffer springs; the mounting frame is provided with four sliding grooves, four sliding blocks are respectively connected with the mounting frame in a sliding manner and are all positioned in the sliding grooves, four supports are respectively fixedly connected with four sliding blocks and are all positioned at one side far away from the mounting frame, one side of four first buffer springs is respectively fixedly connected with four sliding blocks, the other side of four first buffer springs is respectively fixedly connected with the mounting frame and is all positioned in the sliding grooves, the side plate is fixedly connected with four supports and is all positioned at one side far away from the sliding blocks, the transparent plate is fixedly connected with the side plate and is all positioned at the inner side wall of the side plate, two connecting plates are respectively fixedly connected with the side plate and are respectively positioned at the outer side wall of the connecting plate, one side of a plurality of second buffer springs is respectively fixedly connected with the mounting frame, and the other side of a plurality of second buffer springs is respectively fixedly connected with two connecting plates, are positioned between the mounting rack and the connecting plate;

the collecting mechanism comprises a photovoltaic cell panel, an illumination sensor and a temperature sensor, the photovoltaic cell panel is fixedly connected with the side plate and is positioned on the inner side wall of the side plate, the illumination sensor is fixedly connected with the photovoltaic cell panel and is positioned close to one side of the transparent plate, the temperature sensor is fixedly connected with the photovoltaic cell panel and is positioned close to one side of the transparent plate, and the monitoring mechanism is fixedly connected with the photovoltaic cell panel and is positioned far away from one side of the illumination sensor.

2. The data analysis based photovoltaic power generation monitoring system of claim 1,

the installation mechanism still includes two mounting panels, two the mounting panel respectively with mounting bracket fixed connection, and be located the both sides of mounting bracket.

3. The data analysis based photovoltaic power generation monitoring system of claim 1,

the mounting mechanism further comprises a baffle, and the baffle is fixedly connected with the side plate and is positioned on the inner side wall of the side plate.

4. The data analysis based photovoltaic power generation monitoring system of claim 1,

the installation mechanism further comprises a first dust screen, the side plate is provided with a first air inlet, and the first dust screen is fixedly connected with the side plate and located at the first air inlet.

5. The data analysis based photovoltaic power generation monitoring system of claim 1,

the mounting mechanism further comprises a second dust screen and an air exhaust assembly, the side plate is provided with a second air inlet, the second dust screen is fixedly connected with the side plate and located at the second air inlet, and the air exhaust assembly is fixedly connected with the side plate and penetrates through the side plate.

6. The data analysis based photovoltaic power generation monitoring system of claim 3,

the monitoring mechanism comprises a calculation module, a comparison module and a transmission module, wherein the calculation module is fixedly connected with the baffle and is positioned close to one side of the photovoltaic cell panel, the illumination sensor is electrically connected with the temperature sensor, the comparison module is electrically connected with the calculation module and is positioned close to one side of the photovoltaic cell panel, and the transmission module is electrically connected with the comparison module and is positioned close to one side of the photovoltaic cell panel.

7. A photovoltaic power generation monitoring method based on data analysis is applied to the photovoltaic power generation monitoring system based on data analysis of claim 6, and is characterized by comprising the following steps:

the illumination sensor collects illumination conditions on the photovoltaic cell panel;

the temperature sensor collects the temperature condition on the photovoltaic cell panel;

the calculation module calculates the output condition of the generated energy based on the acquired information of the illumination sensor and the temperature sensor to obtain the actual generated energy;

the comparison module compares the actual power generation amount calculated by the calculation module with the predicted power generation amount;

the transmission module transmits the comparison information of the comparison module to the user side.

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