WO2020239067A1 - Orc magnetic suspension power generation system using medium-low temperature geothermal excess-pressure gradient - Google Patents

Abstract

Disclosed is an ORC magnetic suspension power generation system using a medium-low temperature geothermal excess-pressure gradient. The system comprises: an evaporator (10) used for evaporating a working medium; a condenser (20) used for condensing the working medium; a cooling device (30) used for cooling the condenser (20); and a generator (40) comprising a primary turbine (401) and a secondary turbine (402). The cooling device (30) is connected to the secondary turbine (402), a working medium steam outlet of the evaporator (10) is connected to an inlet of the generator (40), an outlet of the generator (40) is connected to the condenser (20), and an outlet of the condenser (20) is connected to a liquid working medium inlet of the evaporator (10).

Description

Medium and low temperature geothermal residual pressure cascade utilization ORC maglev power generation system Technical field

The invention relates to the technical field of geothermal energy power generation, in particular to an ORC magnetic levitation power generation system using a cascade of medium and low temperature geothermal residual pressure.

Background technique

With the depletion of fossil energy, renewable energy is in the ascendant, and geothermal energy, as a safe, clean, and huge resource, has become a hot spot in scientific research. In general, the geographical distribution of geothermal resources in my country is uneven. my country's high-temperature geotropics are mainly distributed in plateau areas such as Tibet and Yunnan; medium and low temperature (temperature below 150 degrees Celsius) geothermal fields are widely distributed in the southeast coast, plain areas, hilly areas and inland sedimentary basins. Although the high-temperature geothermal development technology is mature, it is not suitable for large-scale development due to its distribution. The medium-to-low temperature geothermal is widely distributed and distributed in most urban areas, which has the potential for large-scale development and supplement of clean energy. At present, high-temperature geothermal power generation technology is relatively mature and has been commercialized. However, the low power generation efficiency (less than 10%) of medium and low temperature geothermal resources restricts the promotion of its power generation utilization.

Therefore, the existing technology needs to be improved and developed.

Summary of the invention

In view of the above-mentioned shortcomings of the prior art, the purpose of the present invention is to provide a cascaded ORC magnetic levitation power generation system using medium and low temperature geothermal waste pressure, aiming to solve the problem of low efficiency of existing medium and low temperature geothermal power generation.

The technical solutions adopted by the present invention to solve the above technical problems are as follows:

The ORC magnetic levitation power generation system using the medium and low temperature geothermal residual pressure cascade, including:

ORC generator set, including evaporator used to evaporate working fluid; and

A condenser used for condensing working fluid, a cooling device used for cooling the condenser; and

The generator includes a primary turbine and a secondary turbine; the cooling device is connected to the secondary turbine;

The working fluid vapor outlet of the evaporator is connected to the inlet of the generator; the outlet of the generator is connected to the condenser inlet, and the condenser outlet is connected to the liquid working fluid of the evaporator through a working fluid pump Entrance connection.

In the ORC magnetic levitation power generation system for cascade utilization of the medium and low temperature geothermal residual pressure, the generator is a magnetic levitation turbine generator.

In the ORC magnetic levitation power generation system for cascade utilization of medium and low temperature geothermal waste pressure, the ORC generator set further includes a working fluid pump arranged between the condenser and the evaporator.

In the ORC magnetic levitation power generation system for cascade utilization of the medium and low temperature geothermal residual pressure, wherein the cooling device is an impeller.

In the ORC magnetic levitation power generation system for cascade utilization of medium and low temperature geothermal waste pressure, the condenser includes a first condenser and a second condenser.

The ORC magnetic levitation power generation system for cascade utilization of medium and low temperature geothermal waste pressure further includes a refrigeration device that provides cold energy for the second condenser.

In the ORC magnetic levitation power generation system for cascade utilization of medium and low temperature geothermal waste pressure, wherein the refrigeration device includes:

A generator connected to the evaporator, a third condenser, a second condenser and an absorber connected to the generator.

In the ORC magnetic levitation power generation system for cascade utilization of medium and low temperature geothermal waste pressure, a throttle valve is provided between the third condenser and the second condenser.

In the ORC magnetic levitation power generation system for cascade utilization of medium and low temperature geothermal waste pressure, the second condenser is a spray evaporative condenser.

In the ORC magnetic levitation power generation system for cascade utilization of the medium and low temperature geothermal waste pressure, the working medium can be an organic working medium such as R245fa, R227ea or R600.

Beneficial effects: The steam turbine part of the magnetic levitation generator of the present invention has two-stage turbines, and the gaseous working fluid is expanded once in the two-stage turbines to perform work. Among them, the first-stage turbine drives the generator to generate electricity through the coupling; The coupling drives the impeller to rotate, accelerates the air flow on the surface of the condenser, strengthens the heat exchange capacity of the condenser, reduces the condensation temperature and the condensation pressure, thereby increasing the pressure difference and temperature difference between the inlet and outlet of the maglev generator and improving the power generation of the maglev generator Efficiency, which in turn increases the power generation and the utilization efficiency of medium and low temperature geothermal energy.

Description of the drawings

Fig. 1 is a schematic structural block diagram of ORC magnetic levitation power generation by cascade utilization of medium and low temperature geothermal waste pressure provided by an embodiment of the present invention.

Fig. 2 is a system block diagram of ORC magnetic levitation power generation by cascade utilization of medium and low temperature geothermal waste pressure provided by an implementation example of the present invention.

Fig. 3 is a system block diagram of another ORC magnetic levitation power generation system provided by the embodiment provided in the present invention for the cascade utilization of medium and low temperature geothermal residual pressure.

Detailed ways

In order to make the objectives, technical solutions and advantages of the present invention clearer and clearer, the present invention will be further described in detail below with reference to the drawings and embodiments. It should be understood that the specific embodiments described here are only used to explain the present invention, but not to limit the present invention.

As shown in Figures 1-2, the ORC magnetic levitation power generation system for cascade utilization of medium and low temperature geothermal waste pressure disclosed in the present invention includes an ORC generator set, including an evaporator 10 for evaporating working fluid; and condensation for condensing working fluid A device 20, a cooling device 30 for cooling the condenser 20; and a generator 40, which includes a primary turbine 401 and a secondary turbine 402 connected to the primary turbine 401; The equipment 30 is connected to the secondary turbine 402; the working fluid vapor outlet of the evaporator 10 is connected to the inlet of the generator 40; the outlet of the generator 40 is connected to the condenser 20, the condenser 20 The working medium pump 50 is connected to the liquid working medium inlet of the evaporator 10. The generator is a magnetic levitation turbine generator.

Specifically, in the ORC magnetic levitation power generation system for cascade utilization of medium and low temperature geothermal waste pressure provided by the present invention, two pipelines are provided in the evaporator 10, one of which is used to pass hot water (such as medium and low temperature geothermal Water), which forms a heat source, and another pipeline is used for the passage of working fluid. The working fluid in the second pipeline absorbs the heat in the first pipeline to form working fluid steam, and the working fluid steam is sent to the magnetic levitation turbine generator 40. The magnetic levitation turbine generator 40 has a two-stage turbine. The gaseous working fluid performs work in the first-stage turbine 401, and the generator is driven by the coupling to generate electricity. The gaseous working fluid after power generation enters the second-stage turbine 402 and expands to perform work. The coupling drives the cooling equipment to move, forcing the surrounding air to accelerate and strengthen Heat exchange of the condenser.

Please refer to FIG. 3, in one or more embodiments, the cooling device 30 is an impeller, and the ORC generator set further includes a working fluid pump 50 arranged between the condenser and the evaporator.

In some embodiments, the condenser 20 includes a first condenser 201 and a second condenser 202. In this embodiment, the first condenser 201 is a pre-cooling device for the exhaust steam of a magnetic levitation turbine generator. Under the action of the cooling device 30, the exhaust steam in the first condenser 201 radiates heat The second condenser 202 is a spray-type evaporative condenser, and the second condenser is provided with a condenser tube 203, passing through the first condenser. The low-temperature gaseous working fluid after cooling in 201 flows through the condenser tube to be condensed, and the liquid flowing in from the third condenser 70 is sprayed onto the condenser tube by the second solution pump 204, and the working fluid passes through the first condenser 201. The cooled working fluid is cooled down again. The steam generated during the cooling process is sent to the absorber 80.

In some embodiments, the power generation system further includes a refrigeration device that provides cold energy for the second condenser 202.

Specifically, the refrigeration device includes a generator 60 connected to the evaporator 10, a third condenser 70 connected to the generator 60, a throttle valve 701, a second condenser 202, and The absorber 80 to which the generator 60 is connected.

The power generation system includes two closed cycles: an organic Rankine cycle and an absorption refrigeration cycle. The second condenser of the organic Rankine cycle is provided with a condenser tube 203 as an evaporator of the absorption refrigeration cycle, thereby connecting the organic Rankine cycle and the absorption refrigeration cycle.

Cycle 1 (Organic Rankine Cycle): The organic working fluid absorbs the heat in the 90℃ medium and low temperature geothermal water in the evaporator 10, and evaporates into a high temperature and high pressure gaseous organic working fluid. The high temperature and high pressure gaseous organic working fluid vapor enters the magnetic levitation turbine steam The turbine generator 40 expands to perform work, in which the gaseous organic working medium performs work in the first-stage turbine 401, and the generator is driven to generate electricity through a coupling. The generated gaseous working medium enters the second-stage turbine 402 to expand and perform work through the coupling The cooling device is driven to force the surrounding air to flow faster, and the heat exchange of the first condenser 201 is enhanced. The working fluid pre-cooled by the first condenser 201 is passed into the second condenser 202, cooled again and condensed into a liquid working fluid, and then returned to the evaporator 10 through the working fluid pump 50 to complete the organic working fluid power generation cycle.

Cycle 2 (absorption refrigeration cycle): Taking lithium bromide absorption refrigeration as an example, the lithium bromide solution absorbs the heat in the 70°C geothermal water discharged from the evaporator 10 in the generator 60, and the water in the lithium bromide solution evaporates to make it high The concentration of lithium bromide solution enters the spray absorber 80 through the first solution pump 90; the vapor evaporated from the generator 60 enters the third condenser 70 and is heated by normal temperature water (such as river water) at 25°C to 30°C. It is cooled into liquid water, and then depressurized by the throttle valve 701, enters the second condenser 202, and is sprayed and evaporated by the second solution pump 204 to absorb the organic Rankine cycle. After the first condenser 201 is pre-cooled, the heat in the working fluid becomes The water vapor then enters the spray absorber 80 and is absorbed by the lithium bromide concentrated solution. The two are mixed to form a lithium bromide dilute solution. The lithium bromide dilute solution flows back to the generator 60 through the third solution pump 901 to complete the absorption refrigeration cycle.

It should be noted that cycle 1 can be all forms of thermal power generation processes with condensers, such as organic Rankine cycle and flash geothermal power generation. The heat source can be geothermal water or industrial waste heat, waste heat, etc. The working fluid can be an organic working fluid or an inorganic working fluid, etc. The expander can be a steam turbine, a screw engine or a magnetic levitation type (the magnetic levitation expander has no friction, high speed, and relatively Compared with other types of expanders, it has higher power generation efficiency), and the condenser can be indirect condensation or direct condensation.

Cycle 2 can be any form of waste heat refrigeration cycle, including adsorption refrigeration, absorption refrigeration and so on.

The mechanical energy obtained after the secondary turbine recovers the residual pressure can be distributed to multiple components, not necessarily used to drive the impeller or the water pump. In the case of insufficient power of the second-stage turbine, it may also consume part of the first-stage turbine's mechanical energy or electric power to assist the impeller or water pump to strengthen chemical condensation.

In summary, the present invention provides an ORC magnetic levitation power generation system for cascade utilization of medium and low temperature geothermal waste pressure. The medium and low temperature geothermal ORC magnetic levitation power generation system includes: an ORC generator set, including an evaporator for evaporating working fluid And a condenser for condensing the working fluid, a cooling device for cooling the condenser; and a generator, including a primary turbine and a secondary turbine connected to the primary turbine; the cooling device and The two-stage turbine is connected; the working fluid vapor outlet of the evaporator is connected to the inlet of the generator; the outlet of the generator is connected to the condenser, and the liquid working fluid of the evaporator is connected through a working fluid pump Entrance connection. The steam turbine part of the magnetic levitation generator of the present invention has two-stage turbines, and the gaseous working medium is expanded to perform work respectively in the two-stage turbines. Among them, the first-stage turbine drives the generator through a coupling to generate electricity; the second-stage turbine uses a coupling Drive the impeller to rotate, accelerate the air flow on the surface of the condenser, and strengthen the heat exchange capacity of the condenser. The system is equipped with a spray evaporative condenser, which is to use the air condenser and the spray evaporative condenser in series to strengthen the condensation effect again . Further reduce the condensing temperature and condensing pressure, thereby increasing the pressure difference and temperature difference between the inlet and outlet of the maglev generator, improving the power generation efficiency of the maglev generator, thereby increasing the power generation and improving the utilization efficiency of medium and low temperature geothermal energy.

It should be understood that the application of the present invention is not limited to the above examples. For those of ordinary skill in the art, improvements or changes can be made based on the above description, and all these improvements and changes should fall within the protection scope of the appended claims of the present invention.

Claims (10)

1. The ORC magnetic levitation power generation system with medium and low temperature geothermal waste pressure cascade utilization is characterized in that it includes:

   ORC generator set, including evaporator used to evaporate working fluid; and

   A condenser used for condensing working fluid, a cooling device used for cooling the condenser; and

   The generator includes a primary turbine and a secondary turbine; the cooling device is connected to the secondary turbine;

   The working fluid vapor outlet of the evaporator is connected with the inlet of the generator; the outlet of the generator is connected with the condenser inlet, and the condenser outlet is connected with the liquid working fluid inlet of the evaporator.
2. The medium and low temperature geothermal residual pressure cascade utilization ORC magnetic levitation power generation system of claim 1, wherein the generator is a magnetic levitation turbine generator.
3. The medium and low temperature geothermal residual pressure cascade utilization ORC magnetic levitation power generation system according to claim 1, wherein the ORC generator set further comprises a working fluid pump arranged between the condenser and the evaporator.
4. The medium and low temperature geothermal residual pressure cascade utilization ORC magnetic levitation power generation system according to claim 1, wherein the cooling device is an impeller.
5. The medium and low temperature geothermal residual pressure cascade utilization ORC magnetic levitation power generation system according to any one of claims 1 to 4, wherein the condenser includes a first condenser and a second condenser.
6. The medium and low temperature geothermal residual pressure cascade utilization ORC magnetic levitation power generation system according to claim 5, characterized in that it further comprises a refrigeration device that provides cold energy for the second condenser.
7. The medium and low temperature geothermal waste pressure cascade utilization ORC magnetic levitation power generation system according to claim 6, wherein the refrigeration device comprises:

   A generator connected to the evaporator, a third condenser, a second condenser and an absorber connected to the generator.
8. The medium and low temperature geothermal residual pressure cascade utilization ORC magnetic levitation power generation system according to claim 7, wherein a throttle valve is provided between the third condenser and the second condenser.
9. The medium and low temperature geothermal waste pressure cascade utilization ORC magnetic levitation power generation system of claim 5, wherein the second condenser is a spray evaporative condenser.
10. The medium and low temperature geothermal waste pressure cascade utilization ORC magnetic levitation power generation system of claim 1, wherein the working fluid is any one of R245fa, R227ea and R600.

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