WO2019080742A1

WO2019080742A1 - Multi-coupling power generation system and power generation method

Info

Publication number: WO2019080742A1
Application number: PCT/CN2018/110340
Authority: WO
Inventors: 俞李斌; 徐红波; 吴猛
Original assignee: 中国能源建设集团浙江省电力设计院有限公司
Priority date: 2017-10-24
Filing date: 2018-10-16
Publication date: 2019-05-02
Also published as: CN107975787A; CN107975787B

Abstract

A multi-coupling power generation system and a power generation method, comprising: a heating apparatus (1); a deaerator (2); a high pressure heater (3); a boiler (4); a power generation assembly; a heating supply assembly (6); a condensation assembly. The power generation system uses photothermal technology to pre-heat demineralised water, which is then fed into the deaerator (2) for heating and deaeration, and provided to the boiler (4), thereby solving technical problems relating to solar energy high temperature industrial heat utilisation, and combining the fields of solar energy heat utilisation and industrial heat energy utilisation. The present invention reduces the consumption of traditional energy sources such as coal, has a high power generation efficiency, and significantly reduces pollutant emissions during power generation.

Description

Multi-coupling power generation system and power generation method

Technical field

The invention relates to the field of energy utilization, and in particular to a multi-coupling power generation system and a power generation method.

Background technique

With the rapid development of China's economy, the traditional energy supply, such as the way of generating electricity through the combustion of coal, can no longer meet the needs of environmental protection, and China has a vast territory, and its existence has a huge amount of resources, such as biomass, sludge, etc. These materials can be used to provide electricity.

However, in the prior art, there is no power generation mode in which solar energy is combined with materials such as biomass and sludge to generate electricity, and power generation efficiency is high and economic benefits are considerable.

Summary of the invention

In view of the above problems in the prior art, the present invention provides a multi-coupling power generation system and a power generation method, which use a photothermal technology to preheat a demineralized water, and then send it to a deaerator for heating and deaeration to provide a solution to the boiler. The technical problem of solar high-temperature industrial heat utilization realizes the perfect combination of solar heat utilization field and industrial heat energy field, which has high power generation efficiency, considerable economic benefits, and can greatly reduce pollutant emissions during power generation.

The solution provided by the present invention to solve the above technical problems is as follows:

In one aspect, a multi-coupling power generation system is provided that includes:

a heating device for preheating the body of water;

a deaerator connected to the heating device for further heating and deoxidizing the preheated body of water;

a high pressure heater connected to the deaerator for further heating the water body heated and deaerated by the deaerator;

a boiler connected to the high-pressure heater for receiving water body and fuel heated by the high-pressure heater, and heating the water body by combustion of the fuel to generate steam;

a power generation assembly connected to the boiler for receiving the steam and generating electricity by the steam;

a heating assembly connected to the power generating component for conveying a portion of the exhausted steam after work by the power generating component to a heat demanding unit;

And a condensing unit connected to the power generating unit for condensing a portion of the exhaust steam that has been subjected to work by the power generating unit to generate condensed water, and heating the condensed water to be re-delivered to the deaerator.

Preferably, the heating device is a solar heater; the water body is demineralized water.

Preferably, the deaerator is a built-in deaerator, a rotary membrane deaerator, a spray-filled deaerator, an atmospheric deaerator, a thermal deaerator, a water membrane deaerator, and a vacuum removal. One or several of the oxygenators.

Preferably, the fuel comprises one or more of biomass fuel, sludge, and coal combustion.

Preferably, the high-pressure heater is further configured to receive a portion of the exhausted steam after work by the power generating component, and further heat the water body heated and deaerated by the deaerator by the exhaust steam.

Preferably, the deaerator is further configured to receive a portion of the exhausted steam after work by the power generating component, and further heat the preheated water body by using the exhaust steam.

Preferably, the multi-coupling power generation system further includes: a low pressure heater; the condensing assembly includes: a condenser, and a steam seal cooler;

The condenser is configured to receive a portion of the exhausted steam after work by the power generating component, and condense the partially exhausted steam to generate condensed water;

The steam seal cooler is connected to the condenser and the power generating assembly for receiving a portion of the steam leaking from the power generating component and the condensed water, and heating the condensed water by using the leaked partial steam;

The low pressure heater is connected to the steam seal cooler and the power generation assembly for receiving condensed water heated by the steam seal cooler and a part of the exhaust steam after work by the power generation component, and utilizing the partially exhausted steam The condensed water is reheated, and the reheated condensed water is re-delivered to the deaerator.

Preferably, the power generation assembly includes a steam turbine and a generator.

In another aspect, there is also provided a method of generating power using the multi-coupling power generation system described above, comprising the steps of:

S1, preheating the water body by a heating device;

S2, conveying the preheated water body to the deaerator, and further heating and deoxidizing the preheated water body through the deaerator;

S3. The water body and the fuel after being heated and deaerated by the deaerator are sent to the boiler, and the water body is heated by the combustion of the fuel to generate steam;

And S4, connecting the power generation component to the boiler such that the power generation component receives the steam and generates electricity by the steam.

Preferably, the method further includes:

S5, using a heating component to transport a part of the exhausted steam after the work of the power generating component to the heat demanding unit;

S6. The partially exhausted steam after being worked by the power generating component is respectively sent back to the high pressure heater, the deaerator, the low pressure heater, and the steam seal cooler;

And S7, condensing a portion of the exhaust steam that has been worked by the power generating component by using a condensing unit to generate condensed water, and sequentially heating the condensed water through the steam seal cooler and the low pressure heater to be Deaerator.

The effect brought by the technical solution of the invention:

The invention uses the photothermal technology to preheat the demineralized water, and then sends it to the deaerator to heat and deoxidize and then supplies it to the boiler, solves the technical problem of solar high temperature industrial heat utilization, and realizes the perfect combination of the solar heat utilization field and the industrial heat energy field. It can reduce traditional energy sources, such as coal consumption, high power generation efficiency, considerable economic benefits, and can greatly reduce pollutant emissions during power generation.

DRAWINGS

1 is a schematic structural view of a multi-coupling power generation system in Embodiment 1;

2 is a flow chart showing the steps of power generation by the multi-coupling power generation system in the first embodiment in the second embodiment.

Detailed ways

The present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It is understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Embodiment 1:

As shown in FIG. 1, the multi-coupling power generation system in this embodiment includes:

a heating device 1 for preheating a water body; the heating device 1 may preferably be a solar heater, more particularly preferably a solar heater having a superconducting heat collecting module, which has a better heating effect, and at the same time The water body is demineralized water;

The deaerator 2 is connected to the heating device 1 for further heating and deoxidizing the preheated water body to prevent the oxygen in the water body from causing corrosion and damage to the equipment, thereby causing economic loss; in this embodiment, The deaerator 1 is a built-in deaerator, a rotary membrane deaerator, a spray-filled deaerator, an atmospheric deaerator, a thermal deaerator, a water membrane deaerator, and a vacuum deaerator. One or several of them;

a high-pressure heater 3 connected to the deaerator 2 for further heating the water body heated and deaerated by the deaerator 2; meanwhile, the deaerator 2 and the high-pressure heater 3 are disposed between a first pump body 100 for conveying water passing through the deaerator 2 to the boiler 4, and the first pump body 100 can also be used to adjust parameters such as flow rate and flow rate;

a boiler 4 connected to the high-pressure heater 3 for receiving water body heated by the high-pressure heater 3 and fuel, which is heated by combustion of the fuel to generate steam; the fuel includes biomass One or more of fuel, sludge and coal combustion; biomass fuel mainly refers to agricultural and forestry waste (tree branches, rice straw, wheat straw, etc.) and waste wood materials (construction waste template, waste wood furniture, decorative waste wood materials) Etc.), its low calorific value is between 2,500 kcal/kg and 3,500 kcal/kg. In this embodiment, 5 tons of combustible biomass fuel per hour, calculated by operating 6000 hours per year, consumes the biomass fuel annually. 30,000 tons, can replace and save 12,000 tons of standard coal, more than 40 million degrees of power supply, and reduce CO2 emissions by about 5,280 tons per year. The annual emission reduction of SO2 is about 240 tons, the annual emission reduction of NOX is about 80 tons, and the annual emission reduction of smoke and dust is about 180 tons. While making full use of the biomass fuel and creating huge economic benefits, it can greatly improve the efficiency and effectiveness of energy conservation and emission reduction, and help improve environmental quality. At the same time, the national sewage treatment plant (station) is currently producing annually. Sludge The water rate is 80%) 100 million tons or more. In the present embodiment, sludge is used as a combustion raw material, and the sludge of the power plant is mixed, so that the sludge can be reduced, harmless, stabilized, and resourced. Disposal targets, reduce secondary pollution caused by sludge stacking, and effectively save land resources. Further, ash and slag produced by sludge incineration after high temperature can also be used as resource for building materials, which is good for building ecological environment. Have an important role;

a power generation assembly connected to the boiler 4 for receiving the steam and generating electricity by the steam; specifically, the power generation assembly includes a steam turbine 5 and a generator 10, wherein the steam turbine 5 is driven by the steam The generator 10 is operated to generate electric power, and the generated electric power is subsequently connected to the grid;

a heating assembly 6, which is connected to the power generating component (such as connected to the steam turbine 5), for transporting a part of the steam (ie, the exhaust steam) after the work of the power generating component to the heat demanding unit;

Further, in order to increase the utilization efficiency of the steam, and strive to achieve the best energy saving and emission reducing effect, the high pressure heater 3 is further configured to receive a part of the exhausted steam (ie, the spent steam 2) after the work is performed by the power generating component, and The water body heated and deaerated by the deaerator 2 is further heated by the exhaust steam; at the same time, the deaerator 2 is further configured to receive a part of the steam (ie, the exhaust steam 3) after the power generation component is operated. The preheated water body is further heated by the spent steam.

Further, the multi-coupling power generation system further includes: a low pressure heater 7; the condensing assembly includes: a condenser 8, and a steam seal cooler 9;

The condenser 8 is configured to receive a portion of the exhausted steam (ie, the spent steam four) after the work of the power generating component, and condense the partially exhausted steam to generate condensed water;

The steam seal cooler 9 is connected to the condenser 8 and a power generating component (such as connected to the steam turbine 5) for receiving a part of the steam leaked from the power generating component (such as a part of steam generated by steam leakage of the steam turbine 5 shaft seal) And the condensed water, and heating the condensed water by using the leaked partial steam; similarly, the second pump body 101 is disposed between the steam seal cooler 9 and the condenser 8 The condensed water generated by the condenser 8 is sent to the steam seal cooler 9, and the second pump body 101 can also be used to adjust parameters such as flow rate and flow rate;

Further, the low-pressure heater 7 is connected to the steam seal cooler 9 and a power generation assembly (e.g., connected to the steam turbine 5) for receiving condensed water heated by the steam seal cooler 9 and passing through the power generation assembly. A part of the exhausted steam (i.e., the spent steam five) after the work is performed, and the condensed water is reheated by the partially exhausted steam, and the reheated condensed water is re-delivered to the deaerator 2.

It can be seen that in the present embodiment, in the power generation component, the exhaust steam that has undergone work by the steam turbine 5 can be fully utilized. Specifically, it can be divided into five paths, respectively entering the deaerator 2 and the high pressure heater 3, The heat supply unit 6, the low pressure heater 7, and the condenser 8 are reused, and at the same time, part of the steam leaking out, such as steam generated by the steam seal of the steam turbine 5, can be recovered into the steam seal cooler 9 Reuse, in this way, the steam utilization efficiency can be greatly improved.

For example, in this embodiment, a 220t/h boiler is equipped with a 25MW back pressure turbine generator set with a water supply capacity of about 165t/h. The solar heating device can increase the hydration temperature by an average of 8°C and operate at 6000 per year. The hourly calculation will save about 1,250 tons of standard coal, more than 4 million kWh of electricity, reduce CO2 by about 550 tons per year, reduce SO2 by about 25 tons per year, reduce NOX by about 10 tons per year, and reduce emissions by about 18 tons per year. The energy saving effect is remarkable.

Embodiment 2:

As shown in FIG. 2, the embodiment further provides a method for generating power by using the above multi-coupling power generation system, which includes the following steps:

S1, preheating the water body by a heating device;

Further, in order to increase steam utilization efficiency, the above power generation method further includes:

It should be noted that the technical features in the first embodiment and the second embodiment can be combined arbitrarily, and the combined technical solutions are all within the protection scope of the present invention.

In summary, the present invention uses photothermal technology to pre-heat the demineralized water, and then sends it to the deaerator for heating and deaeration to provide the boiler, which solves the technical problem of solar high-temperature industrial heat utilization, and realizes the field of solar thermal utilization and industrial thermal energy. The perfect combination of the fields, the new energy directly applied to the field of thermal power generation, the replacement of traditional energy by new energy sources, the reduction of traditional energy sources such as coal consumption, high power generation efficiency, considerable economic benefits, and greatly reduced power generation. Pollutant emissions.

The above are only the preferred embodiments of the present invention, and are not intended to limit the present invention. Any modifications, equivalents, improvements, etc., which are within the spirit and scope of the present invention, should be included in the protection of the present invention. Within the scope.

Claims

A multi-coupling power generation system, comprising:

a heating device for preheating the body of water;

a deaerator connected to the heating device for further heating and deoxidizing the preheated body of water;

a high pressure heater connected to the deaerator for further heating the water body heated and deaerated by the deaerator;

a boiler connected to the high-pressure heater for receiving water body and fuel heated by the high-pressure heater, and heating the water body by combustion of the fuel to generate steam;

a power generation assembly connected to the boiler for receiving the steam and generating electricity by the steam;

a heating assembly connected to the power generating component for conveying a portion of the exhausted steam after work by the power generating component to a heat demanding unit;

And a condensing unit connected to the power generating unit for condensing a portion of the exhaust steam that has been subjected to work by the power generating unit to generate condensed water, and heating the condensed water to be re-delivered to the deaerator.
The multi-coupling power generation system according to claim 1, wherein said heating means is a solar heater; and said water body is demineralized water.
The multi-coupling power generation system according to claim 1, wherein the deaerator is a built-in deaerator, a rotary membrane deaerator, a spray-filled deaerator, an atmospheric deaerator, and a thermal type. One or more of a deaerator, a water membrane deaerator, and a vacuum deaerator.
The multi-coupling power generation system of claim 1 wherein said fuel comprises one or more of biomass fuel, sludge, and coal.
A multi-coupling power generation system according to claim 1, wherein said high-pressure heater is further configured to receive a portion of the exhausted steam after the power generation by said power generating component, and to use the exhaust steam to heat and remove the deaerator The water of oxygen is further heated.
The multi-coupling power generation system according to claim 1, wherein the deaerator is further configured to receive a portion of the exhausted steam after work by the power generating component, and further utilize the exhausted steam to further preheat the water body. heating.
The multi-coupling power generation system according to claim 1, wherein said multi-coupling power generation system further comprises: a low pressure heater; said condensing assembly comprising: a condenser, and a steam seal cooler;

The condenser is configured to receive a portion of the exhausted steam after work by the power generating component, and condense the partially exhausted steam to generate condensed water;

The steam seal cooler is connected to the condenser and the power generating assembly for receiving a portion of the steam leaking from the power generating component and the condensed water, and heating the condensed water by using the leaked partial steam;

The low pressure heater is connected to the steam seal cooler and the power generation assembly for receiving condensed water heated by the steam seal cooler and a part of the exhaust steam after work by the power generation component, and utilizing the partially exhausted steam The condensed water is reheated, and the reheated condensed water is re-delivered to the deaerator.
A multi-coupling power generation system according to any one of claims 1 to 7, wherein the power generation assembly comprises a steam turbine and a generator.
A method for generating power using the multi-coupling power generation system of claim 7, comprising the steps of:

S1, preheating the water body by a heating device;

S2, conveying the preheated water body to the deaerator, and further heating and deoxidizing the preheated water body through the deaerator;

S3. The water body and the fuel after being heated and deaerated by the deaerator are sent to the boiler, and the water body is heated by the combustion of the fuel to generate steam;

And S4, connecting the power generation component to the boiler such that the power generation component receives the steam and generates electricity by the steam.
The method of claim 9 further comprising:

S5, using a heating component to transport a part of the exhausted steam after the work of the power generating component to the heat demanding unit;

S6. The partially exhausted steam after being worked by the power generating component is respectively sent back to the high pressure heater, the deaerator, the low pressure heater, and the steam seal cooler;

And S7, condensing a portion of the exhaust steam that has been worked by the power generating component by using a condensing unit to generate condensed water, and sequentially heating the condensed water through the steam seal cooler and the low pressure heater to be Deaerator.