CN203394601U - PV/T (photovoltaic/thermal) collector and gas-steam combined cycle unit united energy supply system - Google Patents

Abstract

A combined energy supply system of a photovoltaic photothermal collector and a gas-steam combined cycle unit, which includes a gas-steam combined cycle unit, a PVT heat collection system and a water diversion pump, and the partial condensate discharged from the condensate pump of the gas-steam combined cycle unit The water enters the PVT heat collection system through the diversion pump for heating, and the condensed water heated by the PVT heat collection system merges with the remaining condensed water discharged from the condensate pump, and then enters the water inlet of the low-pressure economizer of the waste heat boiler of the gas-steam combined cycle unit , the power output end of the PVT heat collection system is connected to the load or the grid. The utility model organically combines the PVT heat collection system with the gas-steam combined cycle unit, which solves the problems of heat dissipation and waste heat utilization of photovoltaic cells, greatly improves the comprehensive utilization rate of energy, reduces the consumption of natural gas, and has Conducive to the energy saving and emission reduction of gas-steam combined power plant.

Description

Combined energy supply system of photovoltaic photothermal collector and gas-steam combined cycle unit

technical field

The utility model relates to a heat supply and power supply system combining a PVT photovoltaic photothermal heat collecting device and a gas-steam combined cycle unit, which belongs to the technical field of solar energy.

Background technique

Photovoltaic power generation technology is based on photovoltaic cells, and uses the photovoltaic effect generated by the semiconductor P-N junction to directly convert light energy into electrical energy. During the power generation process of photovoltaic cells, the proportion of incident solar energy converted into electrical energy is about 15%, and most of the remaining energy is converted into heat, which increases the temperature of photovoltaic cells, and a large increase in the temperature of photovoltaic cells will lead to a decrease in its photoelectric conversion efficiency. Studies have shown that the photoelectric conversion efficiency decreases by 0.5% when the temperature of photovoltaic cells increases by 1 °C. Therefore, solar photovoltaic power generation systems have problems such as low photoelectric conversion efficiency, discontinuous power generation, and high power generation costs.

The gas-steam combined cycle unit enters the heated natural gas into the combustion chamber of the gas turbine, mixes it with the high-pressure air compressed by the compressor, and uses the generated high-temperature and high-pressure air to drive the gas turbine to rotate and do work. The temperature of the gas discharged from the gas turbine is as high as 600 degrees Celsius High temperature, still has high energy, these high-temperature gases are sent to the boiler, the water is heated into steam to drive the steam turbine, and drive the generator to generate electricity. The power generation efficiency of gas-steam combined cycle unit is higher than that of coal-fired unit, and it does not require desulfurization and denitrification, and the emission of carbon dioxide is small, and the degree of air pollution is small. However, natural gas is facing the problem of scarcity of resources, and it is difficult to meet the power supply requirements by relying on natural gas for power generation.

In short, the above energy supply systems are not ideal in terms of energy utilization rate, power generation cost, energy saving and emission reduction, etc. It is necessary to further study the comprehensive utilization technology of new energy.

Utility model content

The purpose of this utility model is to provide a combined energy supply system of photovoltaic photothermal collectors and gas-steam combined cycle units to improve the comprehensive utilization rate of energy, reduce power generation costs, and achieve energy saving and emission reduction in view of the disadvantages of the existing technology. the goal of.

Problem described in the utility model is realized with following technical scheme:

A combined energy supply system of a photovoltaic thermal collector and a gas-steam combined cycle unit, which includes a gas-steam combined cycle unit, a PVT heat collection system, a water diversion pump, and the part discharged from the condensate pump of the gas-steam combined cycle unit The condensed water enters the PVT heat collection system through the diversion pump for heating, and the condensed water heated by the PVT heat collection system is combined with the remaining condensed water discharged from the condensate pump to enter the low-pressure economizer of the waste heat boiler of the gas-steam combined cycle unit. The inlet, the power output end of the PVT heat collection system is connected to the load or the grid.

The combined energy supply system of the above-mentioned photovoltaic thermal collector and gas-steam combined cycle unit, the PVT heat collection system is formed by connecting multiple photovoltaic thermal collectors in series and parallel, and the photovoltaic thermal collector includes PVT Frame, CPC condenser, photovoltaic cell assembly, heat conduction plate and two tempered glass plates, the CPC condenser is installed on the PVT frame, the photovoltaic cell assembly is located at the bottom of the CPC condenser, and its backlight surface is bonded to the heat conduction plate through an adhesive layer On the plate, a lower fluid channel is arranged in the heat conduction plate, one end of the lower fluid channel is connected to the water inlet, and the other end is connected to the heat preservation water storage tank; two tempered glass plates are located above the light-facing surface of the photovoltaic cell module, One end of the upper fluid channel surrounded by them and the side wall of the CPC condenser is connected to the drain port of the condensate pump, and the other end is connected to the hydraulic fluid inlet of the low-pressure economizer of the waste heat boiler.

In the combined energy supply system of the above-mentioned photovoltaic thermal collector and gas-steam combined cycle unit, the backlight surface of the heat conduction plate is provided with a heat insulating layer, and a windproof glass cover is provided above the two tempered glass panels.

In the combined energy supply system of the photovoltaic thermal collector and the gas-steam combined cycle unit, the inner wall of the upper fluid channel is provided with a transparent heat insulating layer.

In the combined energy supply system of the above-mentioned photovoltaic photothermal collector and gas-steam combined cycle unit, the direction of water flow in the lower fluid channel and the upper fluid channel is opposite.

The utility model uses the low-temperature condensed water and domestic water of the gas-steam combined power plant to cool the photovoltaic cell components in the photovoltaic photothermal heat collector, and obtains domestic hot water and higher temperature while reducing the working temperature of the cell components. Condensed water, which improves the photoelectric conversion rate of photovoltaic cell modules and boiler efficiency of waste heat boilers, reduces power generation costs, and also facilitates people's lives.

The utility model organically combines the PVT heat collection system with the gas-steam combined cycle unit, which well solves the problems of heat dissipation and waste heat utilization of photovoltaic cells. It uses forced circulation fluid (water or air) to remove the battery components. The heat that has not been converted into electric energy is absorbed by low-temperature water or cold air, which solves the problem of low photoelectric conversion rate of photovoltaic cells, greatly improves the comprehensive utilization of energy, and reduces the consumption of natural gas. Conducive to the energy saving and emission reduction of gas-steam combined power plant.

Description of drawings

Below in conjunction with accompanying drawing, the utility model is further described.

Fig. 1 is a sectional view of a photovoltaic thermal collector;

Fig. 2 is a structural schematic diagram of a combined energy supply system of a photovoltaic thermal collector and a gas-steam combined cycle unit.

The list of labels in the figure is: 1. Chimney, 2. High-pressure feed water pump, 3. Medium-pressure feed water pump, 4. Low-pressure steam drum, 5. Medium-pressure steam drum, 6. High-pressure steam drum, 7. Low-pressure economizer, 8. High and medium pressure cylinder, 9. Turbine low pressure cylinder, 10. Condenser, 11. Circulating water pump, 12. Condensate water pump, 13. Waste heat boiler, 14. Water diversion pump, 15. Generator, 17. Gas turbine, 18. Heater, 19. Photovoltaic solar heat collector, 20. Tempered glass plate; 21. Insulation layer; 22. PVT frame; 23. CPC condenser mirror; 24. Glass cover plate; 25. Interlayer air; 26. Photovoltaic cell module; 27. Adhesive layer; 28. Lower fluid channel; 29. Heat conduction plate; 30. Upper fluid channel; 31. Transparent heat insulating layer.

Detailed ways

The utility model proposes a combined energy supply system of an improved PVT photovoltaic photothermal collector and a gas-steam combined cycle unit. Solar energy supplements the power generation of the gas-steam combined power plant, and heats the inlet water of the low-pressure economizer of the waste heat boiler of the gas-steam combined power plant, which improves boiler efficiency and power generation efficiency, and reduces power generation costs.

Figure 1 is a cross-sectional view of a photovoltaic thermal collector, its main structure includes: a glass cover plate 24, an interlayer air 25, a photovoltaic cell module 26, an adhesive layer 27, a lower fluid channel 28, a heat conducting plate 29, and an insulating layer 21 , PVT frame 22, CPC condenser lens 23, tempered glass plate 20, upper fluid channel 30. Its working principle: after the sunlight is collected by the CPC condenser 23, it passes through the glass cover plate 24 and the tempered glass plate 20 (the distance between the two tempered glass plates 20 is 5cm, which should not be too large or too small), and part of the infrared light is captured by the tempered glass plate 20 And the power plant condensate absorption in the upper fluid channel 30, most of the visible light is irradiated on the photovoltaic cell module 26 (the condensate in the upper fluid channel 30 and the tempered glass plate 20 mainly absorb infrared light, and the heat absorbed by the tempered glass plate 20 can be transferred For the condensed water, because the condensed water and the tempered glass plate 20 have a low absorption rate of visible light, most of the visible light can reach the surface of the photovoltaic cell module 26 through the tempered glass plate 20 and the condensed water, generating photovoltaic effect), according to the photovoltaic effect In principle, photovoltaic cells convert 15% of solar energy directly into electrical energy, and most of the remaining energy is converted into heat. A small part of this part of heat is lost in the interlayer air 25 through convection and radiation heat exchange, and a large part is transferred to Adhesive layer 27, adhesive layer (heat conduction material) is delivered to heat conduction plate 29 again, and water enters through lower fluid channel 28 (embedded among heat conduction plate 29, and its height is 2cm, and width is 4cm, each lower fluid The distance between the channels 28 is 2 cm, and there are 8 lower fluid channels in total. The length of the lower fluid channel 28 is 200 cm, the width of the heat conducting plate 29 is 48 cm, and the thickness is 4 cm. The lower fluid channel 28 is located in the middle of the heat conducting plate) to conduct heat on the backlight side of the absorption battery The heat in the plate and the temperature of the water can be increased, and the photovoltaic thermal collector (PVT) is equipped with fluid channels on both the light-facing side and the backlight side, so that the temperature of the photovoltaic cell is greatly reduced, not only the photoelectric conversion efficiency is improved, but also the photovoltaic Most of the heat generated by the battery is effectively used. Both the heat insulating layer 21 and the PVT frame 22 are heat insulating materials, which prevent heat from being transferred to the outside and causing loss.

There is an adhesive layer 27 between the backlight surface of the photovoltaic cell assembly 26 and the outer surface of the heat conduction plate 29, and the adhesive layer is coated with opaque TPT material and heat-conducting insulating glue to fill the contact gap to improve the heat conduction effect and make the photovoltaic cell assembly fully Use sunlight to generate electricity and reduce reflections.

In order to ensure the working efficiency of each photovoltaic cell assembly 26 and avoid unnecessary heat loss and heat conduction between the heat conduction plate 29 and the environment and between the photovoltaic cell assembly 26 and the environment, a layer of heat insulation is installed at the bottom of the heat conduction plate 29 Materials, add a layer of glass cover plate 24 on the light-facing surface of the photovoltaic cell module, and install a heat-insulating PVT frame 22 on both sides and bottom of the module.

How the system works

Referring to Fig. 2, the temperature of the water working medium coming out of the condenser 10 is about 30°C, and a stream of water is led out by the water pump 14 into the entrance of the upper fluid passage 30 of the PVT photovoltaic thermal collector, and the heated water working medium in the upper layer At the inlet of the low-pressure economizer 7 introduced into the waste heat boiler 13, after being heated by the low-pressure economizer 7, it enters the low-pressure evaporator and then enters the low-pressure steam drum 4. A part of it becomes low-pressure steam and enters the low-pressure superheater for superheating, and directly enters the The low-pressure cylinder 9 of the steam turbine works, and the rest of the water in the low-pressure steam drum 4 is led out by the medium-high pressure feed water pump 2 to the medium-high pressure economizer for heating, and then enters the medium-high pressure evaporator to be heated, then enters the medium-high pressure steam drum, and the generated steam enters again The medium-high pressure superheater is heated, the medium-pressure superheater is reheated by the reheater, and then enters the medium-pressure steam turbine to do work. The high-pressure superheated steam directly enters the high-pressure cylinder to do work, drives the generator 15 to generate electricity, and the steam after the work of the high-pressure cylinder enters the waste heat boiler The reheater 18 of 13 performs reheating, the steam of the medium pressure cylinder enters the low pressure cylinder, and the steam of the low pressure cylinder discharges to the condenser 10 to exchange heat with the circulating cooling water pumped out by the circulating water pump, and the low pressure cylinder exhausts After the steam is condensed, it turns into condensed water, and part of the condensed water is introduced into the PVT photovoltaic solar thermal collector 19 through the water diversion pump 14, which is equivalent to heating the main feed water in advance, speeding up the steam-water circulation process, and improving the boiler efficiency of the waste heat boiler 13, and through The solar radiation intensity measured by the pyranometer roughly adjusts the flow rate of the water working medium in the upper fluid channel 30 to ensure that the temperature of the water working medium at the outlet is stable within an appropriate range. The efficiency of photovoltaic power generation is reduced, and a simple single-axis sun tracking system placed in the north and south is used. According to the law of sunrise and sunset, the rotating shaft is rotated from east to west at a speed of 15 degrees per hour to track the sun with low precision and reduce the tracking system. The cost is low, but it can achieve a good tracking effect. The flow paths of the upper and lower layers are independent and not connected to each other. The use of serpentine pipes helps reduce the resistance of the fluid in the pipes, and the hydraulic fluid and domestic water flow in opposite directions, avoiding the gap between the hydraulic fluid and domestic water in the upper and lower layers of photovoltaic cells. The final stage of heating is heated at the same time, which ensures the efficiency of photovoltaic power generation. The direct current generated by the photovoltaic cell module is connected to the grid through the inverter to supplement the power generation of the gas-steam combined power plant.

In Figure 2, 6 CPC concentrators are combined together to form a photovoltaic photothermal module as a photovoltaic photothermal unit. The concentration ratio of a single CPC concentrator is 8, the length is 2m, and the temperature rise of the fluid in the upper fluid channel 30 of a single CPC is the smallest. If the temperature is 10°C, the temperature rise of the upper fluid will reach 50°C after passing through 6 CPCs in series. Assuming that the condensed water fluid is 30°C, the final temperature of the condensed water at the outlet of the upper fluid channel 30 will reach at least 80°C after passing through the upper fluid channel 30; If it is 25° C., after being heated by the lower fluid channel 28 , the final temperature of the outlet water of the lower fluid channel 28 will reach at least 70° C. Through the series and distributed arrangement of multiple photovoltaic thermal units, the DC voltage generated by the PVT photovoltaic thermal collector 19 is directly transmitted to the local power grid through the controller and inverter, and used as part of the power generation to supplement the gas- The power generation of steam combined power plants reduces the cost of power generation to a certain extent. For the upper and lower flow channels of each photovoltaic thermal unit, the parallel water supply method is used to lead to each photovoltaic thermal unit. The waste heat generated by the photovoltaic cells is transferred to the lower fluid channel 28 through the thermally conductive silica gel with good thermal conductivity. The domestic water passing through the lower fluid channel 28 absorbs heat, and the heated domestic water is directly sent into the heat preservation reservoir.

A pyranometer is set near the PVT photovoltaic thermal collector 19 to measure the intensity of solar radiation, and according to the intensity of solar radiation, the flow of hydraulic fluid flowing into the fluid channel 30 on the PVT photovoltaic thermal collector 19 passes through the water pump 14 Rough adjustment is made to keep the outlet temperature of the fluid channel 30 on the PVT device within a certain range, and a simple sun tracking system is used to track sunlight, which can achieve effective control while reducing investment costs. When the PVT device stops working at night or on a rainy day, the water diversion pump 14 is turned off, and the introduction of water working medium to the upper fluid channel 30 of the PVT device is stopped, but the boiler efficiency of the waste heat boiler 13 is not affected.

The utility model can realize the purpose of joint energy supply. The PVT photovoltaic photothermal heat collector 19 adopts a CPC compound parabolic concentrator, through the principle of heat absorption of far-infrared light by the hydraulic fluid in the upper fluid channel 30 and the glass cover plate, and the heat dissipation and waste heat recovery technology of the lower fluid channel 28, Make full use of solar energy and improve the efficiency of photovoltaic power generation. The upper and lower layers of water flow channels inside the PVT photovoltaic thermal collector 19 adopt serpentine pipes. The upper and lower surfaces are simultaneously affected by the maximum temperature of the hydraulic medium heated by the upper and lower flow channels, thereby maintaining a high photovoltaic power generation efficiency. The heating medium is directly sent to the main feedwater inlet of the waste heat boiler 13 of the gas-steam combined power plant, and then passes through the low-pressure economizer 7 to speed up the steam-water circulation process, improve the boiler efficiency of the waste heat boiler 13, and indirectly increase the work efficiency of the steam turbine. efficiency. Facing the fact that photovoltaic power generation technology and solar thermal power generation technology are not yet mature and popular, compared with coal-fired power plants, an improved PVT photovoltaic solar thermal collector and gas-steam combined cycle unit energy supply system is adopted to reduce the It reduces the cost of power generation, and has a high degree of environmental friendliness, higher power supply efficiency, and better development prospects.

Claims (5)

1. a photovoltaic and photothermal heat collector is combined energy supplying system with Gas-steam Combined Cycle unit, it is characterized in that, it comprises Gas-steam Combined Cycle unit, PVT collecting system and priming pump (14), the part water of condensation that the condensate pump of Gas-steam Combined Cycle unit (12) is discharged enters the heating of PVT collecting system through priming pump (14), enters the device of working medium entrance of low-pressure coal saver (7) of the exhaust heat boiler (13) of Gas-steam Combined Cycle unit after the water of condensation of PVT collecting system heating and all the other water of condensation of condensate pump (12) discharge are converged; The electric energy output end of PVT collecting system is connected with load or electrical network.

2. a kind of photovoltaic and photothermal heat collector according to claim 1 is combined energy supplying system with Gas-steam Combined Cycle unit, it is characterized in that, described PVT collecting system is formed by connecting by a plurality of photovoltaic and photothermal heat collectors (19) series parallel connection, described photovoltaic and photothermal heat collector (19) comprises PVT framework (22), CPC condenser (23), photovoltaic cell component (26), heat conduction board (29) and two armorplate glasses (20), described CPC condenser (23) is arranged on PVT framework (22), described photovoltaic cell component (26) is positioned at the bottom of CPC condenser (23), its shady face is bonded on heat conduction board (29) by adhesive layer (27), in described heat conduction board (29), be provided with lower fluid conduit (28), one end of described lower fluid conduit (28) taps into water, another termination insulation water storage box, two armorplate glasses (20) are positioned at the side to light top of photovoltaic cell component (26), the drain opening of upper fluid passage (30) the one termination condensate pumps (12) that the sidewall of they and CPC condenser (23) surrounds, the device of working medium entrance of the low-pressure coal saver (7) of a termination exhaust heat boiler (13).

3. a kind of photovoltaic and photothermal heat collector according to claim 2 is combined energy supplying system with Gas-steam Combined Cycle unit, it is characterized in that, the shady face of described heat conduction board (29) is provided with heat insulation layer (21), and the top of two armorplate glasses (20) is provided with perspex cover plate (24).

4. a kind of photovoltaic and photothermal heat collector according to claim 3 is combined energy supplying system with Gas-steam Combined Cycle unit, it is characterized in that, is provided with transparent thermal insulation layer (31) on the inwall of described upper fluid passage (30).

5. a kind of photovoltaic and photothermal heat collector according to claim 4 is combined energy supplying system with Gas-steam Combined Cycle unit, it is characterized in that, the water (flow) direction in described lower fluid conduit (28) He Shang fluid passage (30) is contrary.

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