WO2015143590A1 - Solar radiation energy heat engine - Google Patents
Solar radiation energy heat engine Download PDFInfo
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- WO2015143590A1 WO2015143590A1 PCT/CN2014/000798 CN2014000798W WO2015143590A1 WO 2015143590 A1 WO2015143590 A1 WO 2015143590A1 CN 2014000798 W CN2014000798 W CN 2014000798W WO 2015143590 A1 WO2015143590 A1 WO 2015143590A1
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
- F25B9/00—Compression machines, plants or systems, in which the refrigerant is air or other gas of low boiling point
- F25B9/002—Compression machines, plants or systems, in which the refrigerant is air or other gas of low boiling point characterised by the refrigerant
- F25B9/008—Compression machines, plants or systems, in which the refrigerant is air or other gas of low boiling point characterised by the refrigerant the refrigerant being carbon dioxide
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
- F25B9/00—Compression machines, plants or systems, in which the refrigerant is air or other gas of low boiling point
- F25B9/06—Compression machines, plants or systems, in which the refrigerant is air or other gas of low boiling point using expanders
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F03—MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
- F03G—SPRING, WEIGHT, INERTIA OR LIKE MOTORS; MECHANICAL-POWER PRODUCING DEVICES OR MECHANISMS, NOT OTHERWISE PROVIDED FOR OR USING ENERGY SOURCES NOT OTHERWISE PROVIDED FOR
- F03G6/00—Devices for producing mechanical power from solar energy
- F03G6/02—Devices for producing mechanical power from solar energy using a single state working fluid
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
- F25B27/00—Machines, plants or systems, using particular sources of energy
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F28—HEAT EXCHANGE IN GENERAL
- F28D—HEAT-EXCHANGE APPARATUS, NOT PROVIDED FOR IN ANOTHER SUBCLASS, IN WHICH THE HEAT-EXCHANGE MEDIA DO NOT COME INTO DIRECT CONTACT
- F28D15/00—Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies
- F28D15/02—Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies in which the medium condenses and evaporates, e.g. heat pipes
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F28—HEAT EXCHANGE IN GENERAL
- F28D—HEAT-EXCHANGE APPARATUS, NOT PROVIDED FOR IN ANOTHER SUBCLASS, IN WHICH THE HEAT-EXCHANGE MEDIA DO NOT COME INTO DIRECT CONTACT
- F28D7/00—Heat-exchange apparatus having stationary tubular conduit assemblies for both heat-exchange media, the media being in contact with different sides of a conduit wall
- F28D7/08—Heat-exchange apparatus having stationary tubular conduit assemblies for both heat-exchange media, the media being in contact with different sides of a conduit wall the conduits being otherwise bent, e.g. in a serpentine or zig-zag
- F28D7/082—Heat-exchange apparatus having stationary tubular conduit assemblies for both heat-exchange media, the media being in contact with different sides of a conduit wall the conduits being otherwise bent, e.g. in a serpentine or zig-zag with serpentine or zig-zag configuration
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F28—HEAT EXCHANGE IN GENERAL
- F28D—HEAT-EXCHANGE APPARATUS, NOT PROVIDED FOR IN ANOTHER SUBCLASS, IN WHICH THE HEAT-EXCHANGE MEDIA DO NOT COME INTO DIRECT CONTACT
- F28D7/00—Heat-exchange apparatus having stationary tubular conduit assemblies for both heat-exchange media, the media being in contact with different sides of a conduit wall
- F28D7/10—Heat-exchange apparatus having stationary tubular conduit assemblies for both heat-exchange media, the media being in contact with different sides of a conduit wall the conduits being arranged one within the other, e.g. concentrically
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
- F25B2309/00—Gas cycle refrigeration machines
- F25B2309/06—Compression machines, plants or systems characterised by the refrigerant being carbon dioxide
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/40—Solar thermal energy, e.g. solar towers
- Y02E10/46—Conversion of thermal power into mechanical power, e.g. Rankine, Stirling or solar thermal engines
Definitions
- the invention relates to a method for effectively utilizing solar radiation energy by using carbon dioxide as a working medium, expanding through an expander, and recovering expansion work, and the working fluid after work is replenished by internal heat exchange with the ambient temperature to enter the next cycle.
- solar energy is huge, and the total annual energy consumption of human beings is only equivalent to 60 minutes of solar energy that the sun shines on the earth.
- solar energy has two methods of photovoltaic, photothermal, and they all use sunlight.
- the former uses the photoelectric effect to directly convert part of the spectrum of sunlight into electricity.
- the high-temperature heat generated by focusing the sunlight by a heat engine is converted into mechanical motion, and the generator generates electricity.
- These two methods are limited by photoelectric conversion efficiency, illumination time, solar current density, etc., and there are insurmountable hard constraints, that is, it is necessary to increase the lighting area to obtain more solar energy.
- thermodynamics it is impossible to transfer heat from a low temperature object to a high temperature object without any other influence”. “It is impossible to take heat from a single heat source to completely convert it into useful work without other effects”.
- the heat engine must use the ambient temperature to do work and must have a low temperature environment to form an effective temperature difference with the ambient temperature. Under the effect of temperature difference, the ambient temperature spontaneously releases energy into the low temperature environment.
- Manufacturing low temperatures requires heat absorption from the object until its temperature is below ambient temperature.
- the phase change process of matter such as solid melting, liquid gasification, and solid sublimation, requires absorption of heat and low temperature.
- throttling, eddy current, thermoelectric effects, etc. can also produce low temperatures.
- Throttle expansion refers to the process of moving a fluid (gas, liquid or two phases) at a higher pressure to a lower pressure direction through a throttle valve, and causing a large pressure drop due to local resistance.
- the throttling expansion consumes the internal energy of the working medium and outputs the work externally, causing the working medium pressure, the temperature to decrease, and the enthalpy value to decrease.
- the heat absorption capacity of the working medium to reduce the energy increase is called the expansion cooling capacity.
- the amount of expansion refrigeration is equal to the enthalpy of the decrease in the expansion process of the working fluid.
- thermodynamics energy is required to produce low temperatures.
- a working fluid its critical point is in the ambient temperature range, the ambient temperature can be used as the working temperature, and the temperature difference and pressure difference before and after expansion are sufficiently large, then we can obtain the ambient temperature from the working temperature.
- Energy instead of artificially input compression work, achieves endothermic---exothermic---the thermodynamic cycle of endothermic.
- Carbon dioxide can meet the above requirements. Carbon dioxide is environmentally friendly and is the most environmentally friendly refrigerant in addition to water and air. Its ozone depletion potential is zero and its global warming potential is 1.
- the critical temperature is low, 31.1 ° C, and the critical pressure is high, 7.3 MPa.
- the three-phase point is -56.6 ° C, the pressure is 0.518 MPa, the boiling point is -78.5 ° C, and the melting point is -56.6 ° C.
- the temperature drops to -78.5 ° C, and the gas is not liquefied to form dry ice (the gaseous state is directly converted into a solid state).
- Temperature -78 ° C dry ice sublimation (solid state directly converted to gaseous).
- the expansion process of carbon dioxide is different from the usual high pressure gas expansion work.
- the high-pressure gas relies on the volume expansion to output the shaft work.
- the CO2 expansion ratio is small, only 2-4, which is 10% of the conventional working fluid.
- the expansion power is three times that of conventional working fluid.
- the evaporation pressure is 10 times that of the conventional working fluid, and the transcritical cycle efficiency is much higher than that of the conventional working fluid.
- the solar radiant heat engine cycle includes four processes of evaporation, expansion, condensation, and compression:
- Evaporation The low temperature, low pressure and high liquid pumped into the evaporator by the working fluid pump are compared with the two-phase working medium and the ambient temperature to evaporate and vaporize, increase the volume, increase the pressure, obtain and store the phase change energy, and become the normal temperature and high pressure. High gas compared to working fluid.
- the heat absorption of the working fluid is refrigeration for the external environment of the evaporator. Gasification of CO2 at one atmosphere can result in desublimation of the outer wall of the evaporator.
- Expansion The working fluid compared with the normal temperature, high pressure and high gas after heat exchange with the ambient temperature expands through the expander and performs work externally. Expansion of the expander is an adiabatic process. Since it cannot absorb heat from the outside, it can only consume the internal energy of the working medium, resulting in a decrease in the pressure and temperature of the working medium and a decrease in the enthalpy. After the work is done, the low temperature, low pressure and high gas are discharged from the expander outlet.
- Condensation low temperature, low pressure, high gas compared to the working medium entering the condenser and the low temperature heat exchange formed by the dry ice sublimation generated by the working medium evaporation process, condensing into low temperature, low pressure, high liquid compared to the working medium.
- the evaporator of the solar radiant heat engine is a three-casing heat exchanger with external insulation, and the heat exchanger is connected in series with the condenser.
- the casing can evaporate to form solid carbon dioxide between the outer wall of the inner casing and the inner wall of the intermediate casing, that is, dry ice, -78.5 °C.
- the outer casing of the built-in fan introduces an ambient heat source to exchange heat with the solid carbon dioxide in the intermediate casing, and the solid carbon dioxide is sublimated by heat (-78 ° C), and the low temperature generated by sublimation cools the heat source of the outer casing.
- the low temperature heat source of the outer casing is condensed by the heat exchange of the low temperature, low pressure and high gas which are discharged from the condenser and the expander is higher than the triple point.
- the heat engine can achieve the ambient temperature of T1, and the low temperature generated by the negative heat of the working medium to absorb heat is T2.
- the solar radiant heat engine simulates the operating conditions; the ambient temperature is set to 20 ° C for T1 (expander inlet), the expander outlet is -55 ° C (higher than the triple point), and the working fluid circulates in the two-phase region.
- the expander (two-stage) expansion ratio is 11, and the inlet-exhaust pressure difference is 5 MPa.
- the temperature rises from -55 °C to 20 °C, and the pressure rises from 0.52 MPa to 5.7 MPa.
- the energy that causes the temperature and pressure of the working fluid to rise back comes from the ambient heat source, which means that the compression work of the heat machine is mainly from the ambient temperature, not the compressor.
- the working fluid absorbs heat and cooling in the evaporation end, and expands with the expander and expands the expander. This means that the amount of refrigeration at the evaporation end is equal to the amount of expansion (latent heat) of the expander.
- the latent heat of CO2 solid sublimation is 540KJ/KG, which is greater than the latent heat of vaporization 350KJ/KG, and the solid-gas temperature is -78 °C, which is lower than -56 °C of gas-liquid phase change, which makes the cooling capacity of working fluid evaporative cooling possible as T2. Pressure and latent heat are negatively correlated.
- the steam can be properly pressurized, for example, from 0.52 MPa to 0.8 MPa, and the liquefaction temperature of carbon dioxide is -42 ° C. If pressurized to 1.6 MPa, carbon dioxide. The corresponding liquefaction temperature is -25 °C.
- the carbon dioxide expansion chiller for industrial applications can recover up to 40% of the work of compression (three times that of conventional work), exceeding the heat pump, fan and possible energy input for spent steam pressurization.
- Part of the energy comes from the ambient heat source.
- the efficiency of the heat engine is not important because the ambient heat source used by the heat engine - solar radiant energy resources is almost infinite and the cost is zero.
- the solar radiant heat engine is not limited by the lighting area and the illumination time, and can efficiently acquire and utilize solar energy at any time and place.
- FIG. 1 Schematic diagram of the solar radiant heat engine cycle
- FIG. 1 schematic diagram of a three-casing heat exchanger for solar radiant heat engine
- the solar radiant energy heat machine uses the ambient temperature as the high temperature heat source T1, adopts a low boiling point working fluid including carbon dioxide, and replaces the expansion valve with an expander in the circulation process to recover the expansion work.
- the heat exchanger is connected in series with a condenser to transfer the working medium at a low temperature generated by vaporization endotherm at the evaporation end to the condenser as a low temperature heat source T2.
- the heat engine adopts a volumetric, full-flow machine-screw expander and a screw compressor adapted to two-phase flow. In order to maintain the thermal and pressure balance in all aspects of the cycle, the heat engine is operated intermittently.
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Abstract
A solar radiation energy heat engine recovers, by means of expansion of an expander, expansion work by using carbon dioxide as a working medium. An evaporation end of the heat engine is serially connected to a condenser by means of a heat pipe sleeve type heat exchanger. A low temperature generated by the working medium on the evaporation end by absorbing heat from an environmental heat source is transferred to the condenser, and as a low-temperature heat source of the heat engine, is subjected to heat exchange with the expanded working medium, so that condensation latent heat of the expanded working medium is released. The condensed low-temperature and low-pressure working medium enters an evaporator through a working medium pump, is subjected to heat exchange with the environment to recover heat energy, and enters a next cycle.
Description
本发明涉及一种以二氧化碳为工质,通过膨胀机膨胀,回收膨胀功,做功后的工质通过与环境温度换热回补内能,进入下一循环,从而有效利用太阳辐射能的方法。The invention relates to a method for effectively utilizing solar radiation energy by using carbon dioxide as a working medium, expanding through an expander, and recovering expansion work, and the working fluid after work is replenished by internal heat exchange with the ambient temperature to enter the next cycle.
太阳辐射能量巨大,人类目前每年能源消费总和只相当于60分钟太阳照射到地球的能量。目前,利用太阳能有光伏、光热两种方法,它们都是利用太阳光照。前者利用光电效应直接将太阳光的部分光谱转换为电力。后者则是通过热机将太阳光聚焦后产生的高温热量转换为机械运动,由发电机发电。这两种方法受光电转换效率、光照时间、太阳能流密度等限制,并存在着不可克服的硬约束,即必须依靠增加采光面积才能获得更多太阳能量。The solar radiant energy is huge, and the total annual energy consumption of human beings is only equivalent to 60 minutes of solar energy that the sun shines on the earth. At present, solar energy has two methods of photovoltaic, photothermal, and they all use sunlight. The former uses the photoelectric effect to directly convert part of the spectrum of sunlight into electricity. In the latter case, the high-temperature heat generated by focusing the sunlight by a heat engine is converted into mechanical motion, and the generator generates electricity. These two methods are limited by photoelectric conversion efficiency, illumination time, solar current density, etc., and there are insurmountable hard constraints, that is, it is necessary to increase the lighting area to obtain more solar energy.
事实上,太阳辐射能除大气散射、空中云层吸收流失外,近70%被浅层土壤、水系、大气接收,蕴藏量巨大。没有太阳光照的时间里,这些储存的太阳能仍然以热的形式存在。不过太阳辐射能量-环境温度为低品位热,需要找到有效和经济的利用方法。In fact, in addition to atmospheric scattering and absorption of airborne clouds, nearly 70% of solar radiation is received by shallow soils, water systems, and the atmosphere, and the reserves are huge. In the absence of sunlight, these stored solar energy still exists in the form of heat. However, solar radiant energy - ambient temperature is low grade heat, and it is necessary to find effective and economical methods of utilization.
发明内容Summary of the invention
根据热力学第二定律“不可能把热从低温物体传到高温物体而不产生其他影响”。“不可能从单一热源取热使之完全转换为有用的功而不产生其他影响”。热机要利用环境温度做功必须有一个低温环境,与环境温度形成有效温差。在温差作用下,环境温度会自发的向低温环境释放能量。制造低温需要从物体中吸热直到其温度低于环境温度。物质的相变过程,如固体融化、液体气化、固体升华均需吸收热量,产生低温。此外,节流膨胀、涡流效应、热电效应等也能产生低温。According to the second law of thermodynamics "it is impossible to transfer heat from a low temperature object to a high temperature object without any other influence". “It is impossible to take heat from a single heat source to completely convert it into useful work without other effects”. The heat engine must use the ambient temperature to do work and must have a low temperature environment to form an effective temperature difference with the ambient temperature. Under the effect of temperature difference, the ambient temperature spontaneously releases energy into the low temperature environment. Manufacturing low temperatures requires heat absorption from the object until its temperature is below ambient temperature. The phase change process of matter, such as solid melting, liquid gasification, and solid sublimation, requires absorption of heat and low temperature. In addition, throttling, eddy current, thermoelectric effects, etc. can also produce low temperatures.
节流膨胀是指较高压力下的流体(气、液或两相)经节流阀向较低压力方向运动,遇到局部阻力造成较大压降的过程。节流膨胀消耗工质内能,对外输出功,造成工质压力、温度降低,焓值减小。工质减少能量增加的吸热能力称为膨胀制冷量。膨胀制冷量等于工质膨胀过程减小的焓值。Throttle expansion refers to the process of moving a fluid (gas, liquid or two phases) at a higher pressure to a lower pressure direction through a throttle valve, and causing a large pressure drop due to local resistance. The throttling expansion consumes the internal energy of the working medium and outputs the work externally, causing the working medium pressure, the temperature to decrease, and the enthalpy value to decrease. The heat absorption capacity of the working medium to reduce the energy increase is called the expansion cooling capacity. The amount of expansion refrigeration is equal to the enthalpy of the decrease in the expansion process of the working fluid.
根据热力学第一定律-能量守恒,制造低温需要投入能量。理论上,如果一种工质,它的临界点在环境温度区间,能够以环境温度为工作温度,膨胀前后它的温差、压差足够大,那么我们就可以借助这种工质从环境温度获得能量,替代人为投入的压缩功,实现吸热---放热---吸热的热力学循环。According to the first law of thermodynamics - energy conservation, energy is required to produce low temperatures. In theory, if a working fluid, its critical point is in the ambient temperature range, the ambient temperature can be used as the working temperature, and the temperature difference and pressure difference before and after expansion are sufficiently large, then we can obtain the ambient temperature from the working temperature. Energy, instead of artificially input compression work, achieves endothermic---exothermic---the thermodynamic cycle of endothermic.
二氧化碳可满足上述要求。二氧化碳环境友好,是除水和空气以外与环境最为友善的制冷工质,其臭氧层破坏潜能值为零,全球变暖潜能值为1。临界温度低,31.1℃,临界压力高,7.3兆帕。三相点-56.6℃,压力达0.518兆帕,沸点-78.5℃,低于熔点-56.6℃。在一个大气压下,温降到-78.5℃,气体不经液化凝华成干冰(气态直接转化为固态)。温度-78℃,干冰升华(固态直接转化为气态)。此外,二氧化碳的膨胀过程与通常的高压气体膨胀做功不同。高压气体靠体积膨胀输出轴功,CO2膨胀过程中尽管出现气液相变,但体积变化不大。CO2膨胀比小,只有2-4,是常规工质的10%。膨胀功大,为常规工质的3倍。蒸发压力是常规工质的10倍,跨临界循环效率远高于常规工质。Carbon dioxide can meet the above requirements. Carbon dioxide is environmentally friendly and is the most environmentally friendly refrigerant in addition to water and air. Its ozone depletion potential is zero and its global warming potential is 1. The critical temperature is low, 31.1 ° C, and the critical pressure is high, 7.3 MPa. The three-phase point is -56.6 ° C, the pressure is 0.518 MPa, the boiling point is -78.5 ° C, and the melting point is -56.6 ° C. At an atmospheric pressure, the temperature drops to -78.5 ° C, and the gas is not liquefied to form dry ice (the gaseous state is directly converted into a solid state). Temperature -78 ° C, dry ice sublimation (solid state directly converted to gaseous). In addition, the expansion process of carbon dioxide is different from the usual high pressure gas expansion work. The high-pressure gas relies on the volume expansion to output the shaft work. Although the gas-liquid phase change occurs during the CO2 expansion process, the volume change is not large. The CO2 expansion ratio is small, only 2-4, which is 10% of the conventional working fluid. The expansion power is three times that of conventional working fluid. The evaporation pressure is 10 times that of the conventional working fluid, and the transcritical cycle efficiency is much higher than that of the conventional working fluid.
太阳辐射能热机循环包括蒸发、膨胀、冷凝、压缩四个过程:
The solar radiant heat engine cycle includes four processes of evaporation, expansion, condensation, and compression:
蒸发:经工质泵泵入蒸发器的低温、低压、高液相比两相工质与环境温度换热蒸发气化,体积增加,压力上升,获得并储存相变能,成为常温、高压、高气相比工质。工质吸热对蒸发器外部环境而言则是制冷。CO2在一个大气压下气化可导致蒸发器外壁凝华。Evaporation: The low temperature, low pressure and high liquid pumped into the evaporator by the working fluid pump are compared with the two-phase working medium and the ambient temperature to evaporate and vaporize, increase the volume, increase the pressure, obtain and store the phase change energy, and become the normal temperature and high pressure. High gas compared to working fluid. The heat absorption of the working fluid is refrigeration for the external environment of the evaporator. Gasification of CO2 at one atmosphere can result in desublimation of the outer wall of the evaporator.
膨胀:与环境温度换热后的常温、高压、高气相比的工质经膨胀机膨胀,对外做功。膨胀机膨胀是绝热过程,由于无法从外界吸热,只能消耗工质自身内能,导致工质压力、温度下降,焓值减小。做功后,从膨胀机出口排出的为低温、低压、高气相比工质。Expansion: The working fluid compared with the normal temperature, high pressure and high gas after heat exchange with the ambient temperature expands through the expander and performs work externally. Expansion of the expander is an adiabatic process. Since it cannot absorb heat from the outside, it can only consume the internal energy of the working medium, resulting in a decrease in the pressure and temperature of the working medium and a decrease in the enthalpy. After the work is done, the low temperature, low pressure and high gas are discharged from the expander outlet.
冷凝:低温、低压、高气相比工质进入冷凝器与工质蒸发过程产生的干冰升华形成的低温换热,冷凝为低温、低压、高液相比工质。Condensation: low temperature, low pressure, high gas compared to the working medium entering the condenser and the low temperature heat exchange formed by the dry ice sublimation generated by the working medium evaporation process, condensing into low temperature, low pressure, high liquid compared to the working medium.
压缩:低温、低压、高液相比工质经螺杆泵送入换热器与环境换热,开始下一循环。Compression: low temperature, low pressure, high liquid compared to the working fluid through the screw pump into the heat exchanger and the environment heat exchange, start the next cycle.
太阳辐射能热机的蒸发器为带外保温的三套管式换热器,换热器与冷凝器串联。二氧化碳工质进入换热器内套管蒸发时可导致内套管外壁与中间套管内壁之间形成固体二氧化碳,即干冰,-78.5℃。内置风扇的外套管引入环境热源与中间套管内的固体二氧化碳换热,固体二氧化碳受热(-78℃)升华,升华产生的低温将外套管的热源冷却。外套管的低温热源至冷凝器与膨胀机排出的高于三相点的低温、低压、高气相比的工质换热,使之冷凝。这样热机可以实现以环境温度为T1,以工质吸热对环境做负功产生的低温为T2。The evaporator of the solar radiant heat engine is a three-casing heat exchanger with external insulation, and the heat exchanger is connected in series with the condenser. When the carbon dioxide working medium enters the heat exchanger, the casing can evaporate to form solid carbon dioxide between the outer wall of the inner casing and the inner wall of the intermediate casing, that is, dry ice, -78.5 °C. The outer casing of the built-in fan introduces an ambient heat source to exchange heat with the solid carbon dioxide in the intermediate casing, and the solid carbon dioxide is sublimated by heat (-78 ° C), and the low temperature generated by sublimation cools the heat source of the outer casing. The low temperature heat source of the outer casing is condensed by the heat exchange of the low temperature, low pressure and high gas which are discharged from the condenser and the expander is higher than the triple point. In this way, the heat engine can achieve the ambient temperature of T1, and the low temperature generated by the negative heat of the working medium to absorb heat is T2.
太阳辐射能热机模拟运行工况;设定环境温度20℃为T1(膨胀机入口),膨胀机出口-55℃(高于三相点),工质在两相区循环。膨胀机(两级)膨胀比为11,进排气压差5兆帕。低温、低压、高液相比工质在换热器内与20℃的环境热源换热蒸发气化,压力升至5.7兆帕。经膨胀机膨胀释放内能后,在膨胀机出口处压力下降至0.52兆帕,温度-55℃。经过冷凝、释放潜热的低温低压高液相比工质经工质泵回到换热器再度与环境换热,温度从-55℃回升到20℃,压力从0.52兆帕回升到5.7兆帕。导致工质温度和压力回升的能量来自环境热源,也就是说热机的压缩功主要来自环境温度,而非压缩机。The solar radiant heat engine simulates the operating conditions; the ambient temperature is set to 20 ° C for T1 (expander inlet), the expander outlet is -55 ° C (higher than the triple point), and the working fluid circulates in the two-phase region. The expander (two-stage) expansion ratio is 11, and the inlet-exhaust pressure difference is 5 MPa. The low-temperature, low-pressure, high-liquid compared with the working medium in the heat exchanger and the 20 ° C ambient heat source evaporation vaporization, the pressure rose to 5.7 MPa. After the expansion of the expander releases the internal energy, the pressure at the outlet of the expander drops to 0.52 MPa and the temperature is -55 °C. The low-temperature, low-pressure, high-liquid, which has been condensed and released latent heat, is returned to the heat exchanger via the working fluid pump and then exchanges heat with the environment. The temperature rises from -55 °C to 20 °C, and the pressure rises from 0.52 MPa to 5.7 MPa. The energy that causes the temperature and pressure of the working fluid to rise back comes from the ambient heat source, which means that the compression work of the heat machine is mainly from the ambient temperature, not the compressor.
工质在蒸发端吸热与制冷等量,与膨胀机膨胀功及膨胀机制冷量等量。这意味着蒸发端制冷量与膨胀机制冷量(潜热)等量。CO2固体升华潜热540KJ/KG,大于气化潜热350KJ/KG,固气相变温度为-78℃,低于气液相变的-56℃,这使得工质蒸发制冷的冷量作为T2成为可能。压力和潜热负相关,为实现有效冷凝,可对乏汽适当增压,例如从0.52兆帕增压到0.8兆帕,二氧化碳对应的液化温度为-42℃,若增压至1.6兆帕,二氧化碳对应的液化温度为-25℃。The working fluid absorbs heat and cooling in the evaporation end, and expands with the expander and expands the expander. This means that the amount of refrigeration at the evaporation end is equal to the amount of expansion (latent heat) of the expander. The latent heat of CO2 solid sublimation is 540KJ/KG, which is greater than the latent heat of vaporization 350KJ/KG, and the solid-gas temperature is -78 °C, which is lower than -56 °C of gas-liquid phase change, which makes the cooling capacity of working fluid evaporative cooling possible as T2. Pressure and latent heat are negatively correlated. In order to achieve effective condensation, the steam can be properly pressurized, for example, from 0.52 MPa to 0.8 MPa, and the liquefaction temperature of carbon dioxide is -42 ° C. If pressurized to 1.6 MPa, carbon dioxide. The corresponding liquefaction temperature is -25 °C.
目前,工业应用的二氧化碳膨胀制冷机可回收膨胀功最高为压缩功的40%(是常规工质的3倍),超出热机工质泵、风扇以及可能的对乏汽增压的能量投入,超出部分的能量来自环境热源。这一点不难理解,因为工质从环境热源吸热,自身压力净提高了近5兆帕,大于压缩机投入的0.28兆帕(0.8兆帕-0.52兆帕)以及工质泵及风扇的能量之和。热机效率的高低并不重要,因为热机利用的环境热源-太阳辐射能资源几乎无限大,且成本为零。获得更多的膨胀功(发电量)只要增加工质流量即可。太阳辐射能热机不受采光面积和光照时间限制,能够在任何时间、地点,高效率的获取和利用太阳能。At present, the carbon dioxide expansion chiller for industrial applications can recover up to 40% of the work of compression (three times that of conventional work), exceeding the heat pump, fan and possible energy input for spent steam pressurization. Part of the energy comes from the ambient heat source. This is not difficult to understand, because the working fluid absorbs heat from the ambient heat source, and the net pressure is increased by nearly 5 MPa, which is greater than the compressor input of 0.28 MPa (0.8 MPa-0.52 MPa) and the energy of the working pump and fan. Sum. The efficiency of the heat engine is not important because the ambient heat source used by the heat engine - solar radiant energy resources is almost infinite and the cost is zero. Obtain more expansion work (power generation) as long as the working fluid flow rate is increased. The solar radiant heat engine is not limited by the lighting area and the illumination time, and can efficiently acquire and utilize solar energy at any time and place.
图1,太阳辐射能热机循环过程示意图Figure 1. Schematic diagram of the solar radiant heat engine cycle
图2,太阳辐射能热机三套管式换热器示意图
Figure 2, schematic diagram of a three-casing heat exchanger for solar radiant heat engine
太阳辐射能热机以环境温度为高温热源T1,采用包括二氧化碳在内的低沸点工质,循环过程以膨胀机替代膨胀阀,回收膨胀功。换热器串联冷凝器,将工质在蒸发端气化吸热产生的低温传送到冷凝器作为低温热源T2。热机采用适应两相流的容积式、全流动力机-螺杆膨胀机和螺杆压缩机。为了保持循环过程各个环节的热力和压力平衡,热机为间歇式运行。
The solar radiant energy heat machine uses the ambient temperature as the high temperature heat source T1, adopts a low boiling point working fluid including carbon dioxide, and replaces the expansion valve with an expander in the circulation process to recover the expansion work. The heat exchanger is connected in series with a condenser to transfer the working medium at a low temperature generated by vaporization endotherm at the evaporation end to the condenser as a low temperature heat source T2. The heat engine adopts a volumetric, full-flow machine-screw expander and a screw compressor adapted to two-phase flow. In order to maintain the thermal and pressure balance in all aspects of the cycle, the heat engine is operated intermittently.
Claims (4)
- 一种以环境温度为高温热源,采用低沸点工质,通过膨胀机膨胀,回收膨胀功,做功后的低温、低压工质从环境温度吸热回补内能,进入下一循环的热机。The utility model relates to an environment temperature as a high temperature heat source, adopts a low boiling point working medium, expands through an expander, recovers expansion work, and the low temperature and low pressure working medium after work is absorbed from the ambient temperature to recover the internal energy, and enters the heat engine of the next cycle.
- 根据权利要求1所述,采用的低沸点工质包括但不限于二氧化碳。According to claim 1, the low boiling point working fluid used includes, but is not limited to, carbon dioxide.
- 根据权利要求2所述,蒸发器和冷凝器之间串联管套式换热器,将工质在蒸发端气化吸热产生的低温(对蒸发器外部而言)作为低温热源传送给冷凝器,使乏汽冷凝。According to claim 2, a tube-and-tube heat exchanger is connected between the evaporator and the condenser, and the low temperature generated by the gasification endothermic at the evaporation end (for the outside of the evaporator) is transmitted to the condenser as a low-temperature heat source. To make the steam condense.
- 根据权利要求3所述,膨胀和压缩均采用螺杆机。 According to claim 3, both the expansion and the compression are carried out by a screw machine.
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CN2284937Y (en) * | 1997-03-27 | 1998-06-24 | 黄清福 | Low dew-point device of refrigerating compressed-air dryer |
CN1222741C (en) * | 2001-12-06 | 2005-10-12 | 天津大学 | Rotor-type expander by CO2 cross-critical refrigerating cycle |
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CN1222741C (en) * | 2001-12-06 | 2005-10-12 | 天津大学 | Rotor-type expander by CO2 cross-critical refrigerating cycle |
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