CN212454556U - Double-turbine gas suspension ORC power generation system - Google Patents
Double-turbine gas suspension ORC power generation system Download PDFInfo
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- CN212454556U CN212454556U CN202021181402.3U CN202021181402U CN212454556U CN 212454556 U CN212454556 U CN 212454556U CN 202021181402 U CN202021181402 U CN 202021181402U CN 212454556 U CN212454556 U CN 212454556U
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- 239000000725 suspension Substances 0.000 title claims abstract description 35
- 238000010248 power generation Methods 0.000 title claims abstract description 22
- 239000007788 liquid Substances 0.000 claims abstract description 57
- 238000001816 cooling Methods 0.000 claims abstract description 34
- 238000001704 evaporation Methods 0.000 claims abstract description 14
- 230000008020 evaporation Effects 0.000 claims abstract description 14
- 230000000087 stabilizing effect Effects 0.000 claims description 39
- 238000000034 method Methods 0.000 claims description 7
- 239000002826 coolant Substances 0.000 claims description 4
- 238000005192 partition Methods 0.000 claims description 3
- 230000009977 dual effect Effects 0.000 claims 1
- 239000007789 gas Substances 0.000 description 18
- 239000003507 refrigerant Substances 0.000 description 5
- 230000003068 static effect Effects 0.000 description 5
- 238000010586 diagram Methods 0.000 description 3
- 239000002918 waste heat Substances 0.000 description 3
- 238000005516 engineering process Methods 0.000 description 2
- 238000006243 chemical reaction Methods 0.000 description 1
- 238000010276 construction Methods 0.000 description 1
- 230000005611 electricity Effects 0.000 description 1
- 239000002440 industrial waste Substances 0.000 description 1
- 238000009434 installation Methods 0.000 description 1
- 230000001050 lubricating effect Effects 0.000 description 1
- 239000010687 lubricating oil Substances 0.000 description 1
- 238000012423 maintenance Methods 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000011084 recovery Methods 0.000 description 1
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Abstract
The invention relates to a double-turbine gas suspension ORC power generation system.A power generation expansion unit comprises a left turbine, a gas suspension bearing generator and a right turbine; the gas inlet of the left turbine is communicated with the gas inlet of the right turbine; the air outlet of the left turbine is communicated with the air outlet of the right turbine. The evaporator is a combined full liquid evaporator; the outlet of the preheating section of the evaporator is connected with a generator of the expansion generator set through a liquid supply cooling pipeline; an air inlet pipeline and a bypass thereof are arranged between the outlet of the evaporation section of the evaporator and the expansion generator set. The expansion machine adopted in the invention is a symmetrical double-turbine gas suspension expansion machine, and the ORC system realizes oil-free operation and has simple structure and high power generation efficiency; the expander is provided with the bypass pipeline and the control valve, so that the expander can be effectively protected, the air input is larger, and compared with a screw and a turbine ORC generator set with the same generating capacity, the expander is small in size and high in system efficiency.
Description
Technical Field
The invention relates to the technical field of industrial waste heat recovery and clean energy, in particular to a double-turbine gas suspension ORC power generation system.
Background
The Organic Rankine Cycle (ORC) is a technology for realizing Rankine cycle power generation by adopting a low-boiling-point organic working medium (such as a refrigerant) and completing the phase change of the organic working medium by utilizing a heat source with a lower temperature. The liquid organic working medium is heated by low-temperature waste heat in an evaporator (sometimes called a waste heat exchanger) to generate high-temperature high-pressure gas, the high-temperature high-pressure gas is expanded by an expander to drive a generator to generate electric energy, the low-temperature low-pressure gaseous working medium after passing through the expander is cooled into liquid in a condenser, and the liquid is pressurized by a refrigerant pump and sent back to the evaporator to complete a cycle. The ORC waste heat power generation technology has the problems of low cycle efficiency, less generated energy, high operation and maintenance cost and long investment return period. The expansion generator is a key device for restricting the performance of an ORC unit, and the expansion generator mainly comprises two types, namely a screw machine and a centripetal turbine expander. The screw machine can run at low speed to directly drive the power frequency generator to generate power, and the centripetal turbine rotates at high speed and drives the power frequency motor to generate power after being decelerated by the gear box.
The invention discloses a radial expansion generator set based on an ORC (organic Rankine cycle) circulating system of a static pressure air bearing, which belongs to the prior art, has the application number of 2019108354914, and is named as an ORC circulating system based on the static pressure air bearing, a two-way center turbine is adopted in the expansion generator set and symmetrically arranged on two sides of a motor, the static pressure air bearing is adopted for supporting a rotating shaft of a generator of the expansion generator set, a lubricating liquid of the static pressure air bearing adopts a refrigerant in the system, no lubricating oil pollution is caused, and the; the cooling refrigerant of the expansion generator set enters from the bottom of the motor and is discharged into the condenser from the discharge port. The above-described prior art has the following problems: (1) the screw and the turbine generator set with the same generating capacity have larger size and limited installation, the generating efficiency is not high (2), a coolant needs to be input into a cooling loop of the motor through a refrigerant pump, the structure is complicated, and the popularization and the utilization are not facilitated. (3) The prior art discloses only the construction of two stages of turbines to participate in power generation. Therefore, a liquid supply cooling pipeline which can be switched into a power generation state or a shutdown state and a pressure stabilizing pump according to the operation parameters of the expansion generator is needed, so that accidents are effectively prevented, and the energy conversion efficiency is improved.
Disclosure of Invention
1. The technical problem to be solved is as follows:
aiming at the technical problem, the invention provides a double-turbine gas suspension ORC power generation system, wherein an expansion power generation unit adopts a static pressure air bearing, so that the friction loss is lower and the power generation efficiency is high; by adopting a double-turbine structure, the working condition of high expansion ratio is practical, and the system efficiency is higher; the air inlet structure adopts a bypass loop to realize the protection of the expansion machine; the liquid supply cooling pipeline is provided with a pressure stabilizing pump with a bypass, and the on-off is controlled by an electromagnetic valve to ensure the stable pressure supply of the gas suspension bearing.
2. The technical scheme is as follows:
a double-turbine gas suspension ORC power generation system comprises an evaporator, an expansion generator set, a condenser, a working medium pump and an evaporator which are connected in a circulating manner; the method is characterized in that: the expansion generator set comprises a left turbine, a gas suspension bearing generator and a right turbine; the gas inlet of the left turbine is communicated with the gas inlet of the right turbine; and the air outlet of the left side turbine is communicated with the air outlet of the right side turbine.
The evaporator is a combined flooded evaporator, an internal partition plate with liquid equalizing holes is arranged in an inner cavity of the combined flooded evaporator to divide the evaporator into an upper part and a lower part which are communicated, the upper part is a flooded evaporation section, and the lower part is a working medium preheating section.
An outlet of the preheating section of the evaporator is connected with a generator of the expansion generator set through a liquid supply cooling pipeline; the liquid supply cooling pipeline comprises an evaporator preheating section outlet, a pressure stabilizing pump electromagnetic valve, a pressure stabilizing pump and a coolant inlet of the air suspension bearing generator which are connected in sequence; the liquid supply cooling pipeline also comprises a bypass liquid supply cooling pipeline which is connected with the pressure stabilizing pump electromagnetic valve and a pipeline where the pressure stabilizing pump is arranged in parallel; the bypass liquid supply cooling pipeline comprises a bypass pressure stabilizing pump electromagnetic valve; the pressure stabilizing pump electromagnetic valve and the bypass pressure stabilizing pump electromagnetic valve are in an interlocking state.
An air inlet pipeline is arranged between an outlet of an evaporation section of the evaporator and the expansion generator set; the air inlet pipeline comprises an evaporation section outlet, an air inlet valve, a left turbine air inlet and a right turbine air inlet of the evaporator which are connected in sequence; the air inlet pipeline also comprises a bypass pipeline of the air inlet pipeline; and the bypass path of the air inlet pipeline comprises an evaporation section outlet of the evaporator, a bypass valve and air outlets of the two turbines which are connected in sequence.
Further, the expansion generator set is an integrated generator set; wherein the air suspension bearing generator is a variable-speed permanent magnet generator; the rotor in the variable-speed permanent magnet generator rotates along with the rotating shaft; two ends of the rotating shaft are respectively provided with impellers to form two turbines; the air inlet pipe of one turbine is connected with the air inlet pipe of the other turbine, and a left turbine and a right turbine are correspondingly formed.
A control method of a dual-turbine gas suspension ORC power generation system comprises the following steps:
the method comprises the following steps: the system starts to operate, the air inlet valve is closed, the bypass valve is opened, the organic working medium steam enters the condenser through the bypass passage, is cooled by an external cold source in the condenser and condensed into liquid working medium, and then the liquid working medium is pumped into the preheating section of the combined type full liquid evaporator through the operation of the working medium pump; the high-pressure working medium is conveyed to the generator cavity and the air suspension bearing through a liquid supply cooling pipeline and is used for cooling the generator and supplying air to the air suspension bearing; detecting the air pressure of the organic working medium of the air inlet valve, and if the air pressure of the organic working medium of the air inlet valve is within the preset normal working air pressure, opening the air inlet valve and closing the bypass valve; organic working media simultaneously enter the left turbine and the right turbine to drive the generator to do work and generate power, exhaust gas after doing work enters the condenser to be condensed into liquid working media, and the liquid working media are pumped into the evaporator through the working media pump to complete the whole cycle.
Step two: detecting the air pressure at the outlet of the preheating section of the evaporator, and if the air pressure is higher than the preset air pressure of the cooling pipeline, opening the electromagnetic valve of the pressure stabilizing pump and closing the electromagnetic valve of the bypass pressure stabilizing pump; if the air pressure is lower than the preset air pressure of the liquid supply cooling pipeline, the electromagnetic valve of the pressure stabilizing pump is closed, the electromagnetic valve of the bypass pressure stabilizing pump is opened, and the pressure obtained by the air suspension bearing of the air suspension bearing generator is kept stable through the pressure stabilizing pump.
Step three: when the engine is stopped, the bypass valve is opened from a closed state, and the air inlet valve is closed from an open state; gaseous organic working medium enters a condenser through a bypass valve; and (4) stopping the working medium pump until the external heat source is closed and the evaporator does not exchange heat any more.
3. Has the advantages that:
(1) the expansion machine adopted in the invention is a symmetrical double-turbine gas suspension expansion machine, and the ORC system realizes oil-free operation and has simple structure and high power generation efficiency; the air inflow is larger, and compared with a screw and a turbine ORC generator set with the same generating capacity, the size is small, and the system efficiency is high.
(2) The expander bypass pipeline is arranged to realize the protection of the expander in the starting and stopping state; and a combined full-liquid evaporator with a liquid storage function is used for simultaneously supplying liquid to a liquid cooling pipeline to cool the motor and supply pressure to the air suspension bearing. And the combined evaporator with preheating and liquid storage functions can effectively reduce the size of the unit and reduce the equipment cost.
(3) The liquid supply cooling pipeline is provided with a pressure stabilizing pump with a bypass, so that the system can stably run under the working condition of large heat source fluctuation.
Drawings
FIG. 1 is a connection diagram of the overall structure of the present invention;
FIG. 2 is a schematic diagram of the modular flooded evaporator of the present invention.
Detailed Description
The present invention will be described in detail with reference to the accompanying drawings.
As shown in fig. 1 to fig. 2, a double-turbine gas suspension ORC power generation system comprises an evaporator 1, an expansion generator set, a condenser 7, a working medium pump 8 and the evaporator 1 which are connected in a circulating manner; the method is characterized in that: the expansion generator set comprises a left turbine 4, a gas suspension bearing generator 6 and a right turbine 5; the air inlet of the left turbine 4 is communicated with the air inlet of the right turbine 5; the outlet of the left turbine 4 is communicated with the outlet of the right turbine 5.
The evaporator 1 is a combined flooded evaporator 1, an internal partition plate with liquid equalizing holes is arranged in an inner cavity of the combined flooded evaporator 1 to divide the evaporator 1 into an upper part and a lower part which are communicated, the upper part is a flooded evaporation section 18, and the lower part is a working medium preheating section 19.
An outlet of the preheating section of the evaporator is connected with a generator of the expansion generator set through a liquid supply cooling pipeline; the liquid supply cooling pipeline comprises an evaporator preheating section outlet, a pressure stabilizing pump electromagnetic valve 12, a pressure stabilizing pump 11 and a coolant inlet of the air suspension bearing generator 6 which are connected in sequence; the liquid supply cooling pipeline also comprises a bypass liquid supply cooling pipeline which is connected with the pressure stabilizing pump electromagnetic valve 12 and a pipeline where the pressure stabilizing pump is arranged in parallel; the bypass liquid supply cooling pipeline comprises a bypass pressure stabilizing pump electromagnetic valve 13; the pressure stabilizing pump electromagnetic valve 12 and the bypass pressure stabilizing pump electromagnetic valve 13 are in an interlocking state.
An air inlet pipeline is arranged between an outlet of the evaporation section of the evaporator 1 and the expansion generator set; the air inlet pipeline comprises an evaporation section outlet of the evaporator 1, an air inlet valve 2, a left turbine air inlet and a right turbine air inlet which are connected in sequence; the air inlet pipeline also comprises a bypass pipeline of the air inlet pipeline; and the bypass path of the air inlet pipeline comprises an evaporation section outlet of the evaporator 1, a bypass valve 3 and air outlets of two turbines which are connected in sequence.
Further, the expansion generator set is an integrated generator set; wherein the air suspension bearing generator is a variable-speed permanent magnet generator; the rotor in the variable-speed permanent magnet generator rotates along with the rotating shaft; two ends of the rotating shaft are respectively provided with impellers to form two turbines; the air inlet pipe of one turbine is connected with the air inlet pipe of the other turbine, and a left turbine and a right turbine are correspondingly formed.
A control method of a dual-turbine gas suspension ORC power generation system comprises the following steps:
the method comprises the following steps: the system starts to operate, the air inlet valve is closed, the bypass valve is opened, the organic working medium steam enters the condenser through the bypass passage, is cooled by an external cold source in the condenser and condensed into liquid working medium, and then the liquid working medium is pumped into the preheating section of the combined type full liquid evaporator through the operation of the working medium pump; the high-pressure working medium is conveyed to the generator cavity and the air suspension bearing through a liquid supply cooling pipeline and is used for cooling the generator and supplying air to the air suspension bearing; detecting the air pressure of the organic working medium of the air inlet valve, and if the air pressure of the organic working medium of the air inlet valve is within the preset normal working air pressure, opening the air inlet valve and closing the bypass valve; organic working media simultaneously enter the left turbine and the right turbine to drive the generator to do work and generate power, exhaust gas after doing work enters the condenser to be condensed into liquid working media, and the liquid working media are pumped into the evaporator through the working media pump to complete the whole cycle.
Step two: detecting the air pressure at the outlet of the preheating section of the evaporator, and if the air pressure is higher than the preset air pressure of the cooling pipeline, opening the electromagnetic valve of the pressure stabilizing pump and closing the electromagnetic valve of the bypass pressure stabilizing pump; if the air pressure is lower than the preset air pressure of the liquid supply cooling pipeline, the electromagnetic valve of the pressure stabilizing pump is closed, the electromagnetic valve of the bypass pressure stabilizing pump is opened, and the pressure obtained by the air suspension bearing of the air suspension bearing generator is kept stable through the pressure stabilizing pump.
Step three: when the engine is stopped, the bypass valve is opened from a closed state, and the air inlet valve is closed from an open state; gaseous organic working medium enters a condenser through a bypass valve; and (4) stopping the working medium pump until the external heat source is closed and the evaporator does not exchange heat any more.
The specific embodiment is as follows:
the power generation principle of the ORC system is as follows: the heat source is communicated with the evaporator 1 to transfer heat energy to the organic working medium through heat exchange, the organic working medium absorbs heat to evaporate, and the organic working medium enters the expansion machine to do work to push the turbine to rotate so as to drive the generator to generate electricity.
When the system is started, liquid organic working medium in the evaporator 1 absorbs heat of a heat source and is evaporated into gaseous working medium, the bypass valve 3 of the system is opened, the air inlet valve 2 is closed, organic working medium steam enters the condenser 7 through a bypass pipeline, is cooled by an external cold source in the condenser 7 and is condensed into liquid working medium, then the liquid working medium is pumped into a preheating section of the combined type full liquid evaporator 1 through the working medium pump 7, and high-pressure working medium is conveyed to a cavity of the generator 6 and the air suspension bearing through a liquid supply cooling pipeline and is used for cooling the generator and the air suspension bearing for air supply.
When the normal operation condition of the expansion machine is met, the air inlet valve 2 is opened, the bypass valve 3 is closed, the organic working medium enters the left turbine 4 and the right turbine 5 at the same time to drive the generator 6 to do work for power generation, the exhaust gas after doing work enters the condenser 7 to be condensed into liquid working medium, and the liquid working medium is pumped into the evaporator 1 through the working medium pump 8 to complete the whole cycle.
When the system needs to be stopped, the bypass valve 3 is opened from a closed state, the air inlet valve 2 is closed from an open state, and the gaseous organic working medium enters the condenser 7 through the bypass valve 3. And (4) until the external heat source is closed, the evaporator 1 does not exchange heat any more, and the working medium pump 8 is stopped.
In the system, the liquid supply cooling pipeline is provided with a pressure stabilizing pump 11, and the pressure of the liquid supply cooling pipeline is ensured to be stable through the pressure stabilizing pump 11 aiming at the working condition of large flow and pressure fluctuation of a heat source, so that the pressure obtained by the air suspension bearing is kept stable. Wherein the pressure stabilizing pump electromagnetic valve 12 and the bypass pressure stabilizing pump electromagnetic valve 13 are in an interlocking state and are kept to be turned on and off. And the start and stop of the pressure stabilizing pump are controlled by switching the electromagnetic valves.
Fig. 2 is a schematic diagram of the internal structure of the combined flooded evaporator, and the lower part of the heat exchanger is a preheating section with a liquid storage function. The inside of the heat exchanger is divided into an upper part and a lower part by an internal clapboard with liquid equalizing holes, the upper part is a flooded evaporation section, and the lower part is a working medium preheating section. In the figure, the solid line is the running direction of the organic working medium, and the dotted line is the flow direction of the heat source. In the figure, a heat source inlet 14 is provided, a heat source outlet 15 is provided, a working medium inlet 16 is provided, and a working medium outlet 17 is provided.
Although the present invention has been described with reference to the preferred embodiments, it should be understood that various changes and modifications can be made therein by those skilled in the art without departing from the spirit and scope of the invention as defined by the appended claims.
Claims (2)
1. A double-turbine gas suspension ORC power generation system comprises an evaporator (1), an expansion generator set, a condenser (7), a working medium pump (8) and the evaporator (1) which are connected in a circulating mode; the method is characterized in that: the expansion generator set comprises a left turbine (4), a gas suspension bearing generator (6) and a right turbine (5); the air inlet of the left side turbine (4) is communicated with the air inlet of the right side turbine (5); the air outlet of the left side turbine (4) is communicated with the air outlet of the right side turbine (5);
the evaporator (1) is a combined flooded evaporator (1), an internal partition plate with liquid equalizing holes is arranged in an inner cavity of the combined flooded evaporator (1) to divide the evaporator (1) into an upper part and a lower part which are communicated, the upper part is a flooded evaporation section (18), and the lower part is a working medium preheating section (19);
an outlet of the preheating section of the evaporator is connected with a generator of the expansion generator set through a liquid supply cooling pipeline; the liquid supply cooling pipeline comprises an evaporator preheating section outlet, a pressure stabilizing pump electromagnetic valve (12), a pressure stabilizing pump (11) and a coolant inlet of the air suspension bearing generator (6) which are connected in sequence; the liquid supply cooling pipeline also comprises a bypass liquid supply cooling pipeline which is connected with a pressure stabilizing pump electromagnetic valve (12) and a pipeline where the pressure stabilizing pump is arranged in parallel; the bypass liquid supply cooling pipeline comprises a bypass pressure stabilizing pump electromagnetic valve (13); the pressure stabilizing pump electromagnetic valve (12) and the bypass pressure stabilizing pump electromagnetic valve (13) are in an interlocking state;
an air inlet pipeline is arranged between an outlet of an evaporation section of the evaporator (1) and the expansion generator set; the air inlet pipeline comprises an evaporation section outlet of the evaporator (1), an air inlet valve (2), a left turbine air inlet and a right turbine air inlet which are connected in sequence; the air inlet pipeline also comprises a bypass pipeline of the air inlet pipeline; and the bypass path of the air inlet pipeline comprises an evaporation section outlet of the evaporator (1), a bypass valve (3) and air outlets of two turbines which are sequentially connected.
2. A dual turbine gas suspended ORC power generation system according to claim 1, wherein: the expansion generator set is an integrated generator set; wherein the air suspension bearing generator is a variable-speed permanent magnet generator; the rotor in the variable-speed permanent magnet generator rotates along with the rotating shaft; two ends of the rotating shaft are respectively provided with impellers to form two turbines; the air inlet pipe of one turbine is connected with the air inlet pipe of the other turbine, and a left turbine and a right turbine are correspondingly formed.
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CN111594280A (en) * | 2020-06-23 | 2020-08-28 | 南京天加热能技术有限公司 | Double-turbine gas suspension ORC power generation system and control method |
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CN111594280A (en) * | 2020-06-23 | 2020-08-28 | 南京天加热能技术有限公司 | Double-turbine gas suspension ORC power generation system and control method |
CN111594280B (en) * | 2020-06-23 | 2023-09-19 | 南京天加能源科技有限公司 | Dual-turbine gas suspension ORC power generation system and control method |
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Address after: No. 2 Hengxiang Road, Nanjing Economic and Technological Development Zone, Nanjing, Jiangsu Province, 210000 Patentee after: Nanjing Tianjia Energy Technology Co.,Ltd. Address before: 210046 No.6 Hengye Road, economic and Technological Development Zone, Qixia District, Nanjing City, Jiangsu Province Patentee before: Nanjing tianheating Technology Co.,Ltd. |
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Inventor after: Yang Chenhui Inventor before: Li Jian Inventor before: Yang Chenhui |