阅读说明：本技术 一种集成的太阳能接收器-多级蓄热系统 (Integrated solar receiver-multistage heat storage system ) 是由 王军 李秀秀 杨嵩 于 2019-09-24 设计创作，主要内容包括：本发明公开了一种集成的太阳能接收器-多级蓄热系统,该系统应用于下射式CSP系统,将腔式接收器和多级蓄热填充床集成,避免了单独的蓄热器和接收器模块,减少了连接管道的使用,优化了系统整体设计,缩减了系统初投资成本。充放热过程中均利用循环空气管道加强填充床内的换热效果,更是采用填充床内多级蓄热的方法提高了系统换热效率。该系统所输出的热空气可供给用户使用,或者并入其他系统起辅助作用,具有经济、安全和稳定的多种优势。(The invention discloses an integrated solar receiver-multistage heat storage system, which is applied to a downward-emitting CSP system, integrates a cavity type receiver and a multistage heat storage packed bed, avoids a separate heat accumulator and a receiver module, reduces the use of connecting pipelines, optimizes the overall design of the system and reduces the initial investment cost of the system. In the heat charging and discharging process, the heat exchange effect in the packed bed is enhanced by utilizing the circulating air pipeline, and the heat exchange efficiency of the system is improved by adopting a multi-stage heat storage method in the packed bed. The hot air output by the system can be supplied to users or is combined with other systems for assistance, and the system has multiple advantages of economy, safety and stability.)

1. An integrated solar receiver-thermal storage system comprising a Compound Parabolic Concentrator (CPC), a multi-stage thermal storage packed bed and a cavity receiver, characterized in that: composite Parabolic Concentrator (CPC) sets up in the top toper aperture of cavate receiver, and the lower extreme is provided with multistage heat accumulation packed bed in the cavate receiver, cavate receiver side four air outlets of evenly distributed under the take the altitude, air outlet on install the valve, four circulating air business turn over pipelines of evenly distributed, wherein circulating air business turn over pipeline couples together the third level heat accumulation medium of cavate receiver and multistage heat accumulation packed bed, sets up valve and fan simultaneously, cavity receiver and multistage heat accumulation packed bed all adopt insulating material.

2. An integrated solar receiver-thermal storage system according to claim 1, wherein: the filling material of the multi-stage heat storage packed bed is divided into three stages, wherein the first stage is a PCM1 phase change material, the second stage is a PCM2 phase change material, and the third stage is a mixed rock material; the first stage is directly exposed in the chamber receiver, and the second stage and the third stage are arranged downwards in sequence.

3. An integrated solar receiver-thermal storage system according to claim 2, wherein: the proportion of the three-stage material in the multi-stage heat storage packed bed is that the third stage is larger than the second stage, and the second stage is larger than the first stage.

4. An integrated solar receiver-thermal storage system according to claim 1, wherein: the bottom of the multi-stage heat storage filling bed is provided with a metal grid which is connected with an air inlet and outlet pipeline and a fan.

5. An integrated solar receiver-thermal storage system according to claim 1, wherein: the cavity type receiver is positioned at the focus of the downward reflecting mirror, a cylinder device partially buried underground is adopted and divided by a ground horizontal line, the part above the ground is the cavity type receiver, and the part below the ground is filled with multi-stage heat storage.

6. An integrated solar receiver-thermal storage system according to claim 1, wherein: the composite parabolic condenser is provided with a cover with the size matched with that of the composite parabolic condenser.

Technical Field

The invention relates to a Centralized Solar Power (CSP) technology, in particular to an integrated solar receiver-multistage heat storage system applied to a downward-emitting CSP system.

Background

The centralized solar power generation (CSP) system with the heat storage unit can provide schedulable energy, and is a main direction of the future CSP system technology development. At present, relevant researchers have performed a great deal of research work on how to operate such a system with high efficiency and low cost, but research focuses on the structure, heat storage medium and the like of a heat storage system, and research on integration of a receiver and a heat accumulator is less.

In the earliest research on an integrated solar receiver-heat storage system, molten salt is used as a heat storage medium, concentrated sunlight irradiates the molten salt, and the molten salt directly absorbs heat and stores heat, so that the overall design of the system is simplified, the complexity of system operation is reduced, and the heat exchange efficiency of the system is effectively improved. The system also has an integrated solar receiver-heat storage system which uses a rock packed bed as a heat storage medium and air as a heat transfer fluid, and fully exerts the advantages of wide source and low cost of sensible heat storage raw materials, no corrosion or harmful components and a direct heat transfer mode. However, the single heat storage medium limits the heat exchange efficiency of the system, so that the research on an integrated solar receiver-multi-stage heat storage system adopting a multi-stage heat storage method has great significance for improving the heat exchange efficiency of the system.

Disclosure of Invention

The present invention is directed to overcoming the above-mentioned disadvantages of the prior art and providing a device for integrating a receiver and a heat accumulator, which is applied to a drop-off CSP system, and which can receive solar rays to convert solar energy into thermal energy and also store heat.

In order to achieve the above purpose, the integrated solar receiver-multistage heat storage system of the invention integrates a chamber heat absorber and a multistage heat storage packed bed. The system is positioned at the focus of the downward-reflecting mirror, a cylindrical device which is partially buried underground is adopted, the cylindrical device is divided by a ground horizontal line, the part above the ground is a cavity-type receiver, the part below the ground is a multi-stage heat storage packed bed, and the cylindrical device and the multi-stage heat storage packed bed are connected and directly contacted.

The chamber receiver has a tapered aperture at the top and mounts a Compound Parabolic Concentrator (CPC) and is fitted with a cover that covers the aperture. Four air outlets which are uniformly distributed are arranged at a certain height on the peripheral side surface of the receiver, and valves are arranged. The peripheral and top shells are coated with an insulating material.

The filling material of the multi-stage heat storage packed bed is divided into three stages, wherein the first stage is a porous medium material, the second stage is a PCM phase change material, and the third stage is a mixed rock material. The first stage is directly exposed to the chamber receiver and the second and third stages are arranged sequentially downward. Considering the problems of cost and later maintenance, the proportion of the three-stage material in the multi-stage heat storage packed bed is that the third stage is larger than the second stage, and the second stage is larger than the first stage. And laying heat insulating materials and concrete materials on the shell.

The bottom of the multi-stage heat accumulation packed bed is provided with a metal grid to reduce the non-uniformity of the air flow velocity of the same horizontal section, and the air inlet and outlet pipeline and the fan M1 are connected downwards. And a circulating air inlet and outlet pipeline is led out from the third-stage heat storage medium, part of hot air flows back to the cavity by using a fan M2, the heat exchange effect of the air in the bed is enhanced, and a valve is arranged. The power of M1 and M2 depends on the system size and the temperature of the heat transfer fluid.

This integrated solar receiver-multi-stage thermal storage system combines the receiver with the thermal storage system, and the concentrated solar rays directly irradiate the multi-stage thermal storage packed bed to store energy therein without the need to transfer heat to a separate thermal storage. Therefore, a heat exchanger and related connecting pipelines are not required to be installed, the cost can be greatly reduced, more importantly, the heat storage performance of the multi-stage heat storage medium is better than that of a single heat storage medium, and the system stability and the heat transfer efficiency are improved. The hot air obtained by the system can be supplied to users or sent to other equipment after being processed.

Drawings

Fig. 1 is a front view of the present invention.

Reference numerals: 1. a Compound Parabolic Concentrator (CPC); 2. a cavity receiver housing; 3. a circulating air inlet and outlet pipeline; 4. a fan M2; 5. a multi-stage regenerative packed bed housing; 6. a fan M1; 7. an air inlet and outlet pipe; 8. a metal grid; 9. a multi-stage thermal storage packed bed; 10. an air outlet; 11. a cavity receiver.

Detailed Description

The invention will be further explained with reference to the drawings.

Referring to fig. 1, the integrated solar receiver-multistage heat storage system according to the present invention comprises a Compound Parabolic Concentrator (CPC) 1, a multistage heat storage packed bed 9 and a cavity receiver 11, wherein the Compound Parabolic Concentrator (CPC) 1 is positioned at the top end of the conical aperture of the cavity receiver 11 and has a corresponding cover covering the aperture. The multistage heat-accumulating packed bed 9 is directly connected with the cavity type receiver 11, and the insulating layers of the multistage heat-accumulating packed bed 9 and the cavity type receiver are respectively a cavity type receiver shell 2 and a multistage heat-accumulating packed bed shell 5.

Four air outlets 11 (provided with valves) are uniformly distributed at a certain height on the side surface of the cavity type receiver 11, four circulating air inlet and outlet pipelines 3 are uniformly distributed, wherein the circulating air inlet and outlet pipelines 3 are used for communicating the cavity type receiver 11 with a third-stage heat storage medium of the multi-stage heat storage packed bed 9, and valves and a fan M2 (4) are arranged at the same time.

The multi-stage heat storage packed bed 9 is composed of three stages of heat storage media, the first stage is sequentially arranged downwards to the third stage, a metal grid is arranged in the center of the bottom, and an air inlet and outlet pipeline 7 and a fan M1 (6) are arranged at the lower end.

The working process is divided into two processes of heat storage and heat release. The specific process of heat storage is as follows: in the process, the valve of the air outlet 10 is closed and the valve of the circulating air inlet and outlet duct 3 is opened. The solar rays are reflected by the heliostat field and the downward reflecting reflector to directly irradiate the solar rays to enter the Compound Parabolic Condenser (CPC) 1 and the cavity heat absorber 11, the multistage heat storage packed bed 9 is gradually heated from the top end to the downward three-stage heat storage medium, and the air flow is heated by the heat storage medium when passing through the multistage heat storage packed bed 9. The hot air in the multi-stage heat storage packed bed 9 is continuously pumped out from the bottom of the bed by using a fan M1 (6), and the system is in a negative pressure state, so that cold air is continuously sucked into the aperture of the receiver to enter the multi-stage heat storage packed bed 9 for heating, and the hot air is continuously output by the system, thereby forming a circulation. The fan M2 (4) extracts a part of the air heated to a certain temperature from the third-stage heat storage medium through the circulating air inlet and outlet pipeline 3 and returns the part of the air to the cavity type heat absorber 11, so that the heat exchange effect in the multistage heat storage packed bed 9 is enhanced. By sunlight irradiation in daytime, the temperature in the bed is continuously raised, the heat storage quantity is saturated, and the hot air obtained by the air inlet and outlet pipeline 7 can be sent to a user side or other equipment.

The specific process of heat release is as follows: in the process, the top aperture of the chamber receiver 11 is covered with a lid, the valve of the circulating air inlet and outlet duct 3 is opened, and the valve of the air outlet 10 is opened. Since the multi-stage heat storage packed bed 9 has stored enough heat during the day, the fan M1 (6) sends cold air at night back to the multi-stage heat storage packed bed 9 through the air inlet and outlet pipe 7 in the opposite direction, and the cold air is effectively heated to a certain temperature in the multi-stage heat storage packed bed 9 and flows out through the four air outlets 10 around the side surface of the cavity receiver 11. Part of air at the cavity type receiver 11 can enter the circulating air inlet and outlet pipeline 3 to flow to the third-stage heat storage medium to be heated again, so that the air heat exchange effect in the bed is enhanced. The hot air from the air outlet 10 can be sent to the user side or other equipment.

An integrated solar receiver-multi-stage thermal storage system combines the receiver with a thermal storage system, where energy is stored by direct irradiation of concentrated sunlight onto the multi-stage thermal storage packed bed without the need to transfer heat to a separate thermal storage. Therefore, a heat exchanger and related connecting pipelines are not required to be installed, the cost can be greatly reduced, more importantly, the heat storage performance of the multi-stage heat storage medium is better than that of a single heat storage medium, and the system stability and the heat transfer efficiency are improved. The hot air obtained by the system can be supplied to users or sent to other equipment after being processed.