JPS58178811A - Freon gas turbine power generater - Google Patents
Freon gas turbine power generaterInfo
- Publication number
- JPS58178811A JPS58178811A JP6287382A JP6287382A JPS58178811A JP S58178811 A JPS58178811 A JP S58178811A JP 6287382 A JP6287382 A JP 6287382A JP 6287382 A JP6287382 A JP 6287382A JP S58178811 A JPS58178811 A JP S58178811A
- Authority
- JP
- Japan
- Prior art keywords
- water
- gas
- water tank
- tank
- turbine power
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Pending
Links
Classifications
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01K—STEAM ENGINE PLANTS; STEAM ACCUMULATORS; ENGINE PLANTS NOT OTHERWISE PROVIDED FOR; ENGINES USING SPECIAL WORKING FLUIDS OR CYCLES
- F01K25/00—Plants or engines characterised by use of special working fluids, not otherwise provided for; Plants operating in closed cycles and not otherwise provided for
- F01K25/08—Plants or engines characterised by use of special working fluids, not otherwise provided for; Plants operating in closed cycles and not otherwise provided for using special vapours
Abstract
Description
【発明の詳細な説明】
この発明はフロンガスタービン発電機のガスの凝縮、蒸
発方法に関するものである。DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method for condensing and evaporating gas in a fluorocarbon gas turbine generator.
フロンガスタービン発電機は凝縮器1で冷水とガスを熱
交換してガスを凝縮させたのをポンプ4により蒸発器に
送り、そこで温室と凝縮したガスを熱交換してガスを蒸
発させてその蒸発ガス圧力でタービンをまわして発電す
るのである。The fluorocarbon gas turbine generator exchanges heat between cold water and gas in the condenser 1, condenses the gas, and sends the condensed gas to the evaporator using the pump 4, where it exchanges heat with the greenhouse and the condensed gas to evaporate the gas. Gas pressure turns a turbine to generate electricity.
今迄冷水、温水共一度通水で熱交換していたので、充分
カロリーを吸収しようとするため、出来る■少量を低速
で流していたのである。Up until now, both cold and hot water had been used for heat exchange by passing water through the water once, so in order to absorb enough calories, the smallest amount possible had to be passed at a low speed.
しかしこれでは水の流れがガスの流れよりおくれ完全凝
縮、完全蒸発せず効率は上らなかったのである。However, with this, the flow of water was delayed from the flow of gas, and complete condensation and evaporation did not occur, resulting in no increase in efficiency.
この発明は凝縮器側に水タンク6を設置し、水ポンプ7
を介して水パイプ8で、凝縮器1と水タンク6とを往復
結び、又蒸発器2側に水タンク6′を設置し、水ポンプ
7′を介して水パイプ8′で蒸発器2と水タンク6′を
往復結ぶものである。In this invention, a water tank 6 is installed on the condenser side, and a water pump 7 is installed.
A water pipe 8 connects the condenser 1 and the water tank 6 back and forth, and a water tank 6' is installed on the evaporator 2 side, and a water pipe 8' connects the evaporator 2 and the water pump 7'. It connects the water tank 6' back and forth.
これで水タンク6に冷水、水タンク6′に温水を入れ、
水ポンプ7、7′を動かして凝縮器1、蒸発器2に於て
ガスと熱交換してガスを凝縮、蒸発させるものである。Now fill water tank 6 with cold water and water tank 6' with hot water.
The water pumps 7 and 7' are operated to exchange heat with the gas in the condenser 1 and evaporator 2 to condense and evaporate the gas.
この時冷水、温水は出来る■大量、急速に流すものであ
る。At this time, cold water and hot water must be flowed quickly and in large quantities.
水を大量、急速に流すとポンプの負符はかかるようであ
るが、凝縮器、蒸発器の水取り入れ、取り出し口を■数
にしたり。そのポンプの圧力を排水に利用することによ
り負符はあまり多くならない。It seems that pumping a large amount of water rapidly will have a negative effect on the pump, but the number of water intake and outlet ports for the condenser and evaporator should be increased. By using the pressure of the pump for drainage, the negative sign will not be so large.
大量急速に水を流すことにより一度通水の取り出しカロ
リーは少ないのであるが、循環することにより必要カロ
リーは取り出せる。By rapidly flowing a large amount of water, only a few calories are taken out once the water is passed, but the necessary calories can be taken out by circulating the water.
これで水タンク6の水温は上り、水タンク6′の水温は
下がる。This raises the water temperature in the water tank 6 and lowers the water temperature in the water tank 6'.
定められた温度になると水取り出し口8、8′より排出
してその分補給する。When a predetermined temperature is reached, the water is discharged from the water outlets 8 and 8' and replenished accordingly.
水を大量、急速に流して循環して熱交換するとガスの凝
縮、蒸発がよくなることは■ちに於て、クーラーの実験
で実証済である。It has already been proven in experiments using coolers that gas condensation and evaporation improve when a large amount of water is rapidly circulated to exchange heat.
これで凝縮器で液化して圧力の下ったガスはガスパイプ
Sを通り、ポンプ4により蒸発器2に入り、温水により
蒸発して圧力が上がり、タービン発電機3を動かし、又
凝縮器1に戻り冷水により液化すようになる。The gas, which has been liquefied in the condenser and whose pressure has decreased, passes through the gas pipe S, enters the evaporator 2 by the pump 4, is evaporated by hot water, the pressure rises, drives the turbine generator 3, and returns to the condenser 1. Becomes liquefied in cold water.
図はその構成を示した略図である。
1、凝縮器、2、蒸発器、 3、タービン発電機、4、
ガスポンプ、 5、ガスパイプ、6、6′水タンク′、
7、7′、水ポンプ、8、8′、水パイプ、9、9′、
水取り出し口、
出願人 大栗 ■The figure is a schematic diagram showing the configuration. 1. Condenser, 2. Evaporator, 3. Turbine generator, 4.
Gas pump, 5, gas pipe, 6, 6'water tank',
7, 7', water pump, 8, 8', water pipe, 9, 9',
Water outlet, applicant Oguri ■
Claims (1)
なるフロンガスタービン発電機に於て、凝縮器側に水タ
ンク6、蒸発器側に水タンク6′を設置し、凝縮器1と
水タンク6を、水ポンプ7を介して水パイプ8で結んで
水が循環するようにし、又蒸発器2と水タンク6′を水
ポンプ7′を介して、水パイプ8′で結んで水が循環す
るようにし、凝縮器1と水タンク6、蒸発器2と水タン
ク6′間を双方共、水を強制循環するようにしたフロン
ガスタービン発電機。In a fluorocarbon gas turbine generator consisting of a condenser 1, an evaporator 2, a turbine generator 3, and a pump 4, a water tank 6 is installed on the condenser side and a water tank 6' is installed on the evaporator side. The tank 6 is connected with a water pipe 8 via a water pump 7 so that water circulates, and the evaporator 2 and the water tank 6' are connected via a water pump 7' with a water pipe 8' so that water circulates. A fluorocarbon gas turbine generator in which water is forced to circulate between a condenser 1 and a water tank 6, and between an evaporator 2 and a water tank 6'.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP6287382A JPS58178811A (en) | 1982-04-14 | 1982-04-14 | Freon gas turbine power generater |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP6287382A JPS58178811A (en) | 1982-04-14 | 1982-04-14 | Freon gas turbine power generater |
Publications (1)
Publication Number | Publication Date |
---|---|
JPS58178811A true JPS58178811A (en) | 1983-10-19 |
Family
ID=13212817
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP6287382A Pending JPS58178811A (en) | 1982-04-14 | 1982-04-14 | Freon gas turbine power generater |
Country Status (1)
Country | Link |
---|---|
JP (1) | JPS58178811A (en) |
-
1982
- 1982-04-14 JP JP6287382A patent/JPS58178811A/en active Pending
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