CN203980665U - A kind of distributed multiple-supplying device based on solar energy auxiliary gas turbine - Google Patents

Abstract

The utility model discloses a kind of distributed multiple-supplying device based on solar energy auxiliary gas turbine.The utility model device comprises moisturizing pond, small pump, filling pipe, the first valve ~ nine valve, moisturizing branch road, flat panel solar heat collecting system, moisturizing bypass, vulcanize again water pipe, hot water delivery pipe, mixed hot water water storage tank, hot water user terminal, heat-exchanger pump, flue, flue gas after-treatment device, storage heater, double-effect lithium bromide heat pump, pipes system, air conditioner user end, steam bypass duct, the first steam pump, main steam header road, solar steam pipe, steam user side, the second steam pump, light-concentrating solar heat-collection system, gas tank, gas pipeline, Gas Turbine Generating Units, transformer station, electricity consumption end, Photospot solar filling pipe.The heliotechnics that the utility model utilization and building adapt, overcomes the restriction of solar energy system to cost of land, realizes the effective of gas turbine multi-generation system heat capacity supplemented, and has improved efficiency and the economy of system.

Description

A kind of distributed multiple-supplying device based on solar energy auxiliary gas turbine

Technical field

The utility model relates to solar energy and gas turbine multiple-supplying technology, relates in particular to a kind of distributed multiple-supplying device and method based on solar energy auxiliary gas turbine.

Background technology

The application of having succeeded in distributing-supplying-energy system at present of gas turbine multiple-supplying technology.For gas turbine multiple-supplying technology, its problem is mainly that heat between supply and demand, electricity, the how Optimized Matching between cold realize the optimum matching problem of energy.In this simultaneously, in order further to improve efficiency and the economic benefit of multi-generation system, tend to the form of utilizing of auxiliary other energy, as solar energy, biomass energy, wind energy etc.Meanwhile, new forms of energy add as supplementary energy situation, and cost of investment how to control new forms of energy becomes multi-generation system economic benefit key.

In addition, in China developed area, have a large amount of labor-intensive handicraft industries, these industries, when electric energy is had to vigorous demand, also have very large demand to heat energy (hot water and steam).And the heat energy ratio that traditional gas turbine preheating flue gas provides cannot reach demand, need to heat the coupling that the hot water and steam of generation reaches energy supply by consuming electric energy.In this simultaneously, there is abundant solar energy resources on the roof, delivery room of these industries, how to utilize solar energy resources to realize and optimizes the key that energy supply becomes this type of distributed function system.

Summary of the invention

The purpose of this utility model is to overcome the problems referred to above, and the distributed multiple-supplying device and method based on solar energy auxiliary gas turbine is provided.

For achieving the above object, the utility model is by the following technical solutions:

Distributed multiple-supplying device based on solar energy auxiliary gas turbine comprises moisturizing pond, small pump, filling pipe, the first valve, moisturizing branch road, the second valve, the 3rd valve, the 4th valve, the 5th valve, flat panel solar heat collecting system, moisturizing bypass, vulcanize again water pipe, hot water delivery pipe, the 6th valve, mixed hot water water storage tank, hot water user terminal, heat-exchanger pump, flue, flue gas after-treatment device, storage heater, double-effect lithium bromide heat pump, pipes system, air conditioner user end, steam bypass duct, the first steam pump, the 7th valve, the 8th valve, main steam header road, the 9th valve, solar steam pipe, steam user side, the second steam pump, light-concentrating solar heat-collection system, gas tank, gas pipeline, Gas Turbine Generating Units, transformer station, electricity consumption end, Photospot solar filling pipe.Gas tank is connected by gas pipeline with Gas Turbine Generating Units, and Gas Turbine Generating Units is connected by flue in turn with storage heater, double-effect lithium bromide heat pump and flue gas after-treatment device; Gas Turbine Generating Units is connected by transformer station with electricity consumption end; Double-effect lithium bromide heat pump is connected by pipes system with air conditioner user end; Moisturizing pond is connected with flat panel solar heat collecting system entry end by filling pipe, flat panel solar heat collecting system outlet end is connected with the moisturizing arrival end of storage heater by vulcanizing water pipe again, and the steam (vapor) outlet end of storage heater is connected with steam user side by main steam header road; Small pump is housed on filling pipe, and the entrance point of flat panel solar heat collecting system is equipped with the second valve, then vulcanizes pipe inlet end the 3rd valve is housed; The two ends of moisturizing bypass respectively with filling pipe with vulcanize again water pipe and be connected and form the bypass of flat panel solar heat collecting system, the arrival end of moisturizing bypass is equipped with the 5th valve; Main steam header road is equipped with the first steam pump and the 7th valve successively; The port of export of flat panel solar heat collecting system is connected with hot water user terminal with mixed hot water water storage tank in turn by hot water delivery pipe; Heat-exchanger pump and the 6th valve are housed on hot water delivery pipe successively; The two ends of moisturizing branch road are connected with the arrival end of mixed hot water water storage tank with filling pipe respectively, and the first valve is housed on moisturizing branch road; The two ends of steam bypass duct are connected with the arrival end of mixed hot water water storage tank with main steam header road respectively, and the 8th valve is housed in steam bypass duct; Light-concentrating solar heat-collection system outlet is connected with main steam header road by solar steam pipe, solar steam pipe is equipped with the second steam pump and the 9th valve successively, the two ends of Photospot solar filling pipe are connected with light-concentrating solar heat-collection system entry with filling pipe respectively, and the 4th valve is housed on Photospot solar filling pipe.

Described flat panel solar heat collecting system is arranged in building roof realization with light-concentrating solar heat-collection system and merges mutually with building, and wherein the optically focused form of light-concentrating solar heat-collection system can be flat linear Fresnel secondary reflection concentrating or plate compounding parabolic concentration.The exhanst gas outlet temperature of described storage heater is 200 ~ 220 ℃.

Compared with prior art, the utlity model has following advantage:

1, the utility model is on existing gas turbine multiple-supplying basis, introduce the flat panel solar heat collecting system and the Photospot solar technology that adapt with building, do not increasing on the basis of land resources utilization, utilize building roof to increase the heat capacity of system, improved the solar energy utilization ratio of system.

2, the utility model has been realized the step of gas turbine flue gas has efficiently been utilized by storage heater and lithium bromide heat pump, and storage heater has guaranteed the intermittent function of solar thermal collection system to supplement to guarantee continous-stable supply simultaneously.

Accompanying drawing explanation

Fig. 1 is the structural representation of the distributed multiple-supplying device based on solar energy auxiliary gas turbine;

In figure: moisturizing pond 1, small pump 2, filling pipe 3, the first valve 4, moisturizing branch road 5, the second valve 6, the 3rd valve 7, the 4th valve 8, the 5th valve 9, flat panel solar heat collecting system 10, moisturizing bypass 11, vulcanize again water pipe 12, hot water delivery pipe 13, the 6th valve 14, mixed hot water water storage tank 15, hot water user terminal 16, heat-exchanger pump 17, flue 18, flue gas after-treatment device 19, storage heater 20, double-effect lithium bromide heat pump 21, pipes system 22, air conditioner user end 23, steam bypass duct 24, the first steam pump 25, the 7th valve 26, the 8th valve 27, main steam header road 28, the 9th valve 29, solar steam pipe 30, steam user side 31, the second steam pump 32, light-concentrating solar heat-collection device 33, gas tank 34, gas pipeline 35, Gas Turbine Generating Units 36, transformer station 37, electricity consumption end 38, Photospot solar filling pipe 39.

The specific embodiment

As shown in Figure 1, distributed multiple-supplying device based on solar energy auxiliary gas turbine comprises moisturizing pond 1, small pump 2, filling pipe 3, the first valve 4, moisturizing branch road 5, the second valve 6, the 3rd valve 7, the 4th valve 8, the 5th valve 9, flat panel solar heat collecting system 10, moisturizing bypass 11, vulcanize again water pipe 12, hot water delivery pipe 13, the 6th valve 14, mixed hot water water storage tank 15, hot water user terminal 16, heat-exchanger pump 17, flue 18, flue gas after-treatment device 19, storage heater 20, double-effect lithium bromide heat pump 21, pipes system 22, air conditioner user end 23, steam bypass duct 24, the first steam pump 25, the 7th valve 26, the 8th valve 27, main steam header road 28, the 9th valve 29, solar steam pipe 30, steam user side 31, the second steam pump 32, light-concentrating solar heat-collection system 33, gas tank 34, gas pipeline 35, Gas Turbine Generating Units 36, transformer station 37, electricity consumption end 38, Photospot solar filling pipe 39.Gas tank 34 is connected by gas pipeline 35 with Gas Turbine Generating Units 36, and Gas Turbine Generating Units 36 is connected by flue 18 in turn with storage heater 20, double-effect lithium bromide heat pump 21 and flue gas after-treatment device 19; Gas Turbine Generating Units 36 is connected by transformer station 37 with electricity consumption end 38; Double-effect lithium bromide heat pump 21 is connected by pipes system 22 with air conditioner user end 23; Moisturizing pond 1 is connected with flat panel solar heat collecting system 10 arrival ends by filling pipe 3, flat panel solar heat collecting system 10 ports of export are connected with the moisturizing arrival end of storage heater 20 by vulcanizing water pipe 12 again, and the steam (vapor) outlet end of storage heater 20 is connected with steam user side 31 by main steam header road 28; Small pump 2 is housed on filling pipe 3, and the entrance point of flat panel solar heat collecting system 10 is equipped with the second valve 6, then vulcanizes water pipe 12 arrival ends the 3rd valve 7 is housed; The two ends of moisturizing bypass 11 respectively with filling pipe 3 with vulcanize again water pipe 12 and be connected and form the bypass of flat panel solar heat collecting system 10, the arrival end of moisturizing bypass 11 is equipped with the 5th valve 9; Main steam header road 28 is equipped with the first steam pump 25 and the 7th valve 26 successively; The port of export of flat panel solar heat collecting system 10 is connected with hot water user terminal 16 with mixed hot water water storage tank 15 in turn by hot water delivery pipe 13; Heat-exchanger pump 17 and the 6th valve 14 are housed on hot water delivery pipe 13 successively; The two ends of moisturizing branch road 5 are connected with the arrival end of mixed hot water water storage tank 15 with filling pipe 3 respectively, and the first valve 4 is housed on moisturizing branch road 5; The two ends of steam bypass duct 24 are connected with the arrival end of mixed hot water water storage tank 15 with main steam header road 28 respectively, and the 8th valve 27 is housed in steam bypass duct 24; 33 outlets of light-concentrating solar heat-collection system are connected with main steam header road 28 by solar steam pipe 30, solar steam pipe 30 is equipped with the second steam pump 32 and the 9th valve 29 successively, the two ends of Photospot solar filling pipe 39 are connected with light-concentrating solar heat-collection system 33 entrances with filling pipe 3 respectively, and the 4th valve 8 is housed on Photospot solar filling pipe 39.

Described flat panel solar heat collecting system 10 is arranged in building roof realization with light-concentrating solar heat-collection system 33 and merges mutually with building, and wherein the optically focused form of light-concentrating solar heat-collection system 33 can be flat linear Fresnel secondary reflection concentrating or plate compounding parabolic concentration.The exhanst gas outlet temperature of described storage heater 20 is 200 ~ 220 ℃.

Distributed multiple-supplying method based on solar energy auxiliary gas turbine: the hot water that utilizes flat panel solar heat collecting system 10 to produce offers hot water user terminal 16 as domestic hot-water by mixed hot water water storage tank 15, and unnecessary delivery is again heated into middle high-temperature steam to storage heater 20 and supplements to steam user side 31 through main steam header road 28; Light-concentrating solar heat-collection system 33 heats high-temperature steam in the moisturizing generation flowing into through Photospot solar filling pipe 39 and directly offers steam user side 31 through solar steam pipe 30 inflow main steam header roads 28 by optically focused.Gas Turbine Generating Units 36 directly produces on the one hand electric energy and meets electricity consumption end 38 demands, utilizes on the other hand the high-temperature residual heat flue gas of its generation to realize efficient cascade utilization by storage heater 20 and double-effect lithium bromide heat pump 21; Storage heater 20 is realized high-grade heat energy is stored and supplied in solar energy deficiency and without stable the continuing that guarantees steam user side 31 and hot water user terminal 16 under illumination condition; 21 of double-effect lithium bromide heat pumps directly utilize compared with low-grade flue gas and carry out cooling or heat supply as thermal source for air conditioner user end 23.By opening the 5th valve 9 and the 7th valve 26, realize under the not enough condition of solar steam and utilize moisturizing bypass 11 to increase the object that moisturizing increases storage heater 20 supplies; By opening the 3rd valve 7 and the 7th valve 26, realize and utilize the unnecessary hot water of flat panel solar heat collecting system 10 through storage heater 20 heating supply steam; By opening the first valve 4, the 8th valve 27, close the 3rd valve 7, realize under the not enough operating modes of flat panel solar heat collecting system 10 heat supplies when mixed hot water water storage tank 15 water levels transfinite through moisturizing branch road 5 and steam bypass duct 24 complementary heatings; Under without sun condition, by closing the second valve 6, the 3rd valve 7, the 4th valve 8, the 6th valve 14, the 9th valve 29, the first Open valve 4, the 5th valve 9, the 7th valve 26, the 8th valve 27, realize and only by storage heater (20), carry out steam and hot water supply.

The course of work of the present utility model is: combustion gas is generated electricity and provided electric energy to electricity consumption end 38 by burning in Gas Turbine Generating Units 36, and in addition, the high-temperature flue gas of generation enters storage heater 20 and double-effect lithium bromide heat pump 21 successively by flue 18.In storage heater 20, high-temperature flue gas stores high-grade heat energy by heat exchange, compared with low-grade flue gas, as the thermal source of double-effect lithium bromide heat pump 21, be directly that air conditioner user end 23 carries out heat supply or cooling, the tail gas of eliminating is discharged after flue gas after-treatment device 19 is processed.

Under desirable solar irradiation working condition, the second valve 6, the 4th valve 8, the 6th valve 14, the 9th valve 29 is opened, other valves are all closed, moisturizing in moisturizing pond 1 by small pump 2 through filling pipe 3 with Photospot solar filling pipe 39 is transported to respectively flat panel solar heat collecting system 10 and light-concentrating solar heat-collection system 33 heats, the hot water that flat panel solar heat collecting system 10 produces offers hot water user terminal 16 through being transported to mixed hot water water storage tank 15 by heat-exchanger pump 17 through hot water delivery pipe 13, the middle high-temperature steam that light-concentrating solar heat-collection system 33 produces offers steam user side 31 by the second steam pump 32 through solar steam pipe 30 and main steam header road 28.

When the steam of 33 pairs of steam user sides 31 of light-concentrating solar heat-collection system is under-supply, open the 5th valve 9 and the 7th valve 26, moisturizing in moisturizing pond 1 is heated through filling pipe 3 and moisturizing bypass 11 inflow storage heaters 20, and in generation, high-temperature steam is supplied to steam user side 31 to supplement through main steam header road 28.When the hot water amount that produces when flat panel solar heat collecting system 10 is too much, open the 3rd valve 7, unnecessary hot water flow into simultaneously storage heater 20 as moisturizing carry out again heat produce in high-temperature steam.

When the hot water that produces when flat panel solar heat collecting system flat-plate solar thermal collection system 10 is not enough, the water yield in mixed hot water water storage tank 15 surpasses restriction, close the 3rd valve 7, open the first valve 4 and the 8th valve 27, by the moisturizing in filling pipe 3 and main steam header road 28 and middle high-temperature steam, through moisturizing branch road 5 and steam bypass duct 24, at the entrance of mixed hot water water storage tank 15, mix and carry out hot water and supplement respectively, meet the supply of hot water user terminal 16.

Under without sun working condition, close the second valve 6, the 3rd valve 7, the 4th valve 8, the 6th valve 14, the 9th valve 29, open the first valve 4, the 5th valve 9, the 7th valve 26, the 8th valve 27, whole system is carried out hot water and steam supply by storage heater 20.

Claims (3)

1. the distributed multiple-supplying device based on solar energy auxiliary gas turbine, is characterized in that comprising moisturizing pond (1), small pump (2), filling pipe (3), the first valve (4), moisturizing branch road (5), the second valve (6), the 3rd valve (7), the 4th valve (8), the 5th valve (9), flat panel solar heat collecting system (10), moisturizing bypass (11), vulcanize again water pipe (12), hot water delivery pipe (13), the 6th valve (14), mixed hot water water storage tank (15), hot water user terminal (16), heat-exchanger pump (17), flue (18), flue gas after-treatment device (19), storage heater (20), double-effect lithium bromide heat pump (21), pipes system (22), air conditioner user end (23), steam bypass duct (24), the first steam pump (25), the 7th valve (26), the 8th valve (27), main steam header road (28), the 9th valve (29), solar steam pipe (30), steam user side (31), the second steam pump (32), light-concentrating solar heat-collection system (33), gas tank (34), gas pipeline (35), Gas Turbine Generating Units (36), transformer station (37), electricity consumption end (38), Photospot solar filling pipe (39), gas tank (34) is connected by gas pipeline (35) with Gas Turbine Generating Units (36), and Gas Turbine Generating Units (36) is connected by flue (18) in turn with storage heater (20), double-effect lithium bromide heat pump (21) and flue gas after-treatment device (19), Gas Turbine Generating Units (36) is connected by transformer station (37) with electricity consumption end (38), double-effect lithium bromide heat pump (21) is connected by pipes system (22) with air conditioner user end (23), moisturizing pond (1) is connected with flat panel solar heat collecting system (10) arrival end by filling pipe (3), flat panel solar heat collecting system (10) port of export is connected with the moisturizing arrival end of storage heater (20) by vulcanizing water pipe (12) again, and the steam (vapor) outlet end of storage heater (20) is connected with steam user side (31) by main steam header road (28), small pump (2) is housed on filling pipe (3), and the entrance point of flat panel solar heat collecting system (10) is equipped with the second valve (6), then vulcanizes water pipe (12) arrival end the 3rd valve (7) is housed, the two ends of moisturizing bypass (11) respectively with filling pipe (3) with vulcanize again water pipe (12) and be connected and form the bypass of flat panel solar heat collecting system (10), the arrival end of moisturizing bypass (11) is equipped with the 5th valve (9), main steam header road (28) is equipped with the first steam pump (25) and the 7th valve (26) successively, the port of export of flat panel solar heat collecting system (10) is connected with hot water user terminal (16) with mixed hot water water storage tank (15) in turn by hot water delivery pipe (13), heat-exchanger pump (17) and valve six (14) are housed on hot water delivery pipe (13) successively, the two ends of moisturizing branch road (5) are connected with the arrival end of mixed hot water water storage tank (15) with filling pipe (3) respectively, and the first valve (4) is housed on moisturizing branch road (5), the two ends of steam bypass duct (24) are connected with the arrival end of mixed hot water water storage tank (15) with main steam header road (28) respectively, and valve eight (27) is housed in steam bypass duct (24), light-concentrating solar heat-collection system (33) outlet is connected with main steam header road (28) by solar steam pipe (30), solar steam pipe (30) is equipped with the second steam pump (32) and the 9th valve (29) successively, the two ends of Photospot solar filling pipe (39) are connected with light-concentrating solar heat-collection system (33) entrance with filling pipe (3) respectively, and valve four (8) is housed on Photospot solar filling pipe (39).

2. a kind of distributed multiple-supplying device based on solar energy auxiliary gas turbine according to claim 1, it is characterized in that described flat panel solar heat collecting system (10) and light-concentrating solar heat-collection system (33) are arranged in building roof realization and merge mutually with building, wherein the optically focused form of light-concentrating solar heat-collection system (33) is flat linear Fresnel secondary reflection concentrating or plate compounding parabolic concentration.

3. a kind of distributed multiple-supplying device based on solar energy auxiliary gas turbine according to claim 1, is characterized in that the exhanst gas outlet temperature of described storage heater (20) is 200 ~ 220 ℃.