JPS6226327A - Power generating plant - Google Patents

Abstract

PURPOSE:To improve combustion efficiency by directly connecting a screw type air compressor and a rotary expansion machine and pulsation-damping and decompressing the high-pressure air supplied from the air compressor and utilizing said high-pressure air for the combustion of fuel, and then operating the rotary expansion machine by said combustion gas. CONSTITUTION:A screw type air compressor 2 is directly connected to a screw type or turbine type expansion machine 1 by a shaft 11, and said expansion machine 1 is connected to a dynamo 10 by a shaft 12. The high-pressure air compressed by the air compressor 2 is introduced into a combustion chamber 3 through a pressure tank (pulsation damping means) 15 and a reducing valve 17, and utilized for the combustion of fuel supplied into the combustion chamber 3 through a fuel feeding pipe 9, and said fuel is ignited by a spark plug 19. The combustion gas under high pressure which is generated continuously and uniformly in the combustion chamber 3 flows into the expansion machine 1 through a gas pipe 7, and work is performed, and the dynamo 10 is driven. Therefore, the air pressure on start can be increased, and the combustion efficiency can be improved.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a power generation device that performs expansion work by introducing combustion gas into a rotary expansion Wt machine that is directly connected to a screw type air compressor.

[Conventional technology]

Traditionally, gas combustion turbines use axial or centrifugal air compressors, so compressed air is continuously discharged, mixed with fuel and continuously ignited in the combustion chamber. Can be operated without needing a stopper. However, in axial flow type or centrifugal type air compressors, the air pressure cannot rise rapidly at the start, resulting in poor combustion efficiency. In addition, the rotational speed must always be kept constant, and if the load fluctuates, efficiency will deteriorate.

Also, if we consider the example shown in Figure 3, which has been modified to use a positive displacement air compressor in order to improve the combustion efficiency at the start, the discharge from the positive displacement air compressor 2, such as a screw type air compressor. The pulsating air flows into the combustion chamber 3 through the discharge pipe 6, mixes with fuel from the fuel supply pipe 9, and burns, but it must be ignited at the right time by the spark plug 19 in accordance with the pulsation. However, there are disadvantages in that the structure is complicated and the cost is high.

[Problem that the invention seeks to solve]

The aim is to increase combustion efficiency by increasing air pressure at the start, and to eliminate drawbacks such as the complicated structure of the ignition system that was required due to the pulsation of compressed air introduced into the combustion chamber. be.

[Means for solving the problems] The means of the present invention resides in the following points. That is, the screw type air compressor and the rotary II expansion machine are directly connected.

A pulsation damping means and a pressure reducing means are provided between the air compressor and the combustion chamber, and high pressure air is made to flow through the means.

The compressed air that has passed through the means and the fuel from the fuel supply pipe are introduced into the combustion chamber and combusted.

The combustion gas is expanded in the rotary expander.

[Effect]

Pulsating air discharged from a screw type air compressor is passed through a pulsation damping means and a pressure reducing means so that air at a constant pressure is continuously formed in the combustion chamber to cause combustion, In addition to eliminating the conventional method of operating the spark plug in accordance with the timing of pulsations, the system uses a screw-type air compressor to increase air pressure from the start.

〔Example〕

FIG. 1 shows a first embodiment of the invention.

A screw type air compressor g32 is directly connected to a screw type or turbine type expansion unit 1fff1 by a shaft 11, and the expander 1 is connected to a generator 10 by a shaft 12. A pressure tank 15 is installed between the air compressor 2 and the combustion chamber 3.
and a pressure reducing valve 17 are sequentially provided. '19 is a spark plug.

The pulsating compressed air discharged from the air compressor 2 passes through the discharge pipe 6 and is stored in the -H pressure tank 15 to a constant pressure.Then, it flows through the injection pipe 13 and is then pumped through the pressure reducing valve 11 to a constant pressure. It is continuously flashed into the combustion chamber 3. The combustion of fuel in the combustion chamber 3 is normally performed by the spark plug 19.1. Not pulsating.

Since the combustion gas becomes a uniform and continuous flowing gas and flows into the expander 1 through the gas pipe 7, the rotation of the expander 1 is also uniform. Incidentally, the ignition plug 19 can also be an ignition burner that is always lit, if necessary. Furthermore, the pressure reducing means may be an appropriate throttling mechanism that adjusts the cross-sectional area instead of a pressure reducing valve.

FIG. 2 shows a second embodiment of the invention. In the figure, parts with the same reference numerals as those in the first embodiment have the same functions as those in the first embodiment. In this embodiment, the pressure reducing valve 1 in FIG.
Expander 4 is used instead of 7. Since the flood 1F- caused by the pressure reducing valve 17 in FIG. The engine is operated to pressurize the fuel from the fuel supply pipe 14 and send it to the fuel supply pipe 9.

Note that the ignition plug 19 can also be used as an ignition burner if necessary.

〔Effect of the invention〕

Conventional gas turbine cycle air compressors are of the variant, speed type, axial flow type or centrifugal type. These air compressors are subject to changes in rotational speed depending on usage conditions and intake air conditions (air volume 1
When the artificial air temperature, etc. changes, the design point is exceeded and nerging or choking occurs, so it can only be used within a narrow control range, and the efficiency drops significantly when the design point is exceeded. According to the invention, since a screw type air compressor is used, the above-mentioned drawbacks of the prior art are eliminated.

Further, combustion problems caused by pulsation caused by using a screw type air compressor can be solved by providing a pulsation damping means and a pressure reducing means to average the air pressure in the combustion chamber.

[Brief explanation of the drawing]

1 and 2 are flow sheet diagrams of different embodiments of the power generating device of the present invention, and FIG. 3 is a flow sheet diagram of a conventional power generating device.
0-sheet diagram. 1...Screw type or turbine type expansion IIm as a rotary expander, 2...Screw type air compressor, 3...
Combustion chamber, 4... Expansion rMIl as pressure reduction means, 9. Fuel supply pipe, 15. Pressure tank as pulsation damping means.
17...Pressure reducing valve as pressure reducing means. Procedural amendment (voluntary) July 14, 1985 1 Attorney-at-Law Michibu Uga Relationship with the case of the person who amended the name of the power generator of the invention in Patent Application No. 164833 of 1985 Patent applicant Maekawa Seisakusho Co., Ltd. Agent: 4-3-22 Shinjuku, Shinjuku-ku, Tokyo (Ando Pill) Telephone:
03-352-1561 (Main) Date of amendment order None Specification 1, Name of invention Power generator 2, Claims (1) Screw type air compressor and rotary expander 0
The high-pressure air from the air compressor is passed through the first stage of pulsation damping and pressure reduction means into the combustion chamber, and the fuel from the fuel supply pipe is sent into the combustion chamber to be combusted. A power generating device characterized in that power is generated by expanding in the rotary expander. (2) The power generation side according to claim 1, characterized in that a pressure tank and a pressure reducing valve are sequentially provided between the air compressor and the combustion chamber, so that the combustion chamber serves as a flasher tank. L (3) The moving horn generator according to claim 1, wherein the pressure reducing means is a low pressure air expansion +1. (4) The power generating device according to claim 3, characterized in that a fuel oil injection pump is connected to the low-pressure air bladder Ill. (5) The power generating device according to any one of claims 1 to 4, wherein the rotating 165-speed machine is of a screw type or a turbine type. (6) The power generating device according to any one of claims 1 to 5, characterized in that the combustion chamber is provided with an ignition burner that is kept ignited at all times. Patent 5-'
1, 7 or 9! 1 @ power generation device 3 Detailed description of the invention [Object of the invention] (Industrial field of application) The present invention is a method for performing expansion work by introducing combustion gas into a rotary expander that is directly connected to a screw type air compressor. This invention relates to a moving horn generator that performs the following. (Prior art) Conventionally, gas combustion turbines use axial or centrifugal air compressors, so compressed air is continuously discharged, mixed with fuel, and then stored in the combustion chamber. Continuous operation without the need for a spark hydrant at all times is possible. However, in axial flow type or centrifugal type air compressors, the air pressure cannot rise rapidly at the start, resulting in poor combustion efficiency. In addition, the rotational speed must always be kept constant, and if the load fluctuates, efficiency will deteriorate. Furthermore, considering the example shown in Fig. 3 in which a positive displacement air compressor is used in order to improve the combustion efficiency at the start, the suction of the positive displacement air compressor 2, for example a screw type air compressor, is The pulsating air sucked in through the pipe 5, compressed, and then discharged flows into the combustion chamber 3 through the discharge pipe 6, mixes with fuel from the fuel supply pipe 9, and burns, but is ignited in accordance with the pulsation. Since the spigot 19 must be used to ignite the fire in a timely manner, the structure is complicated and the cost is high. (Problems to be Solved by the Invention) What is the structure of the ignition system that is required to increase the air pressure at the start to increase combustion efficiency and to accommodate the pulsation of compressed air introduced into the combustion chamber? ! ! The aim is to eliminate the drawbacks such as sloppiness. [Structure of the Invention] (Means for Solving the Problems) The means of the present invention resides in the following points. That is, the screw type air compressor and the rotary 13-lens machine should be directly connected. A pulsation damping means and a pressure reducing means are provided between the air compressor and the combustion chamber, and high pressure air is made to flow through the means. The compressed air that has passed through the means and the fuel from the fuel supply pipe are introduced into the combustion chamber and combusted. The combustion gas is expanded in the rotary expander to generate power. (Function) By circulating the pulsating air discharged from the screw type air compressor through the pulsation damping means and the pressure reducing means, combustion is performed so that air at a constant pressure is continuously formed in the combustion chamber. This eliminates the conventional method of operating the spark plug in synch with the pulsation timing, and uses a screw-type air compressor to increase air pressure from the start. (Example) FIG. 1 shows a first example of the present invention. The screw type air pressure Ja12 is connected to the screw type or turbine type expansion rr*m1 by the shaft 11, and the expander 1 is connected to the generator 1G by the shaft 12. Between the air compressor 812 and the combustion chamber 3, the pressure tank 15
and a pressure reducing valve 17 are sequentially provided. 19 is. It's a spark plug. When starting the power generation device, the generator 10 is rotated as an induction motor and used as a starter to drive the expander 1 and the air compressor 2, thereby eliminating the need to use a separate starter. can. The pulsating compressed air discharged from the air compressor 112 passes through the discharge pipe 6 and is temporarily stored in the pressure tank 15 to a constant pressure, then flows through the injection pipe 13, and is continuously compressed at a constant pressure via the pressure reducing valve 17. It is flushed into the combustion chamber 3. The combustion of fuel in the combustion chamber 3 is normally performed by the spark plug 19 and is not pulsating. Since the combustion gas becomes a uniform and continuous flowing gas and flows into the expansion chamber 1111 through the gas pipe 7, the rotation of the expansion machine 1 is also uniform. The expanded gas flows out from the loss of air pipe 8. Incidentally, the ignition plug 19 can also be an ignition burner that is always lit, if necessary. Furthermore, the pressure reducing means may be an appropriate throttling mechanism that adjusts the cross-sectional area instead of a pressure reducing valve. FIG. 2 shows a second embodiment of the invention. In the figure, parts given the same reference numerals as in the first embodiment are parts having the same functions as in the first embodiment. In this embodiment, the pressure reducing valve 1 in FIG.
Expander 4 is used instead of 7. Since the flasher caused by the pressure reducing valve 17 in FIG. is operated via the drive shaft 1G to pressurize the fuel from the fuel supply pipe 14 and send it to the fuel supply pipe 9. Note that the ignition plug 19 can also be used as an ignition burner if necessary. [Effects of the Invention] Conventional gas turbine recycle air compressors are skin type, velocity type, axial flow type, or centrifugal type. These air compressors are subject to changes in rotational speed due to usage conditions
If the air temperature (temperature, etc.) changes, surging or kinging will occur if the equipment is off the 1st point, so it can only be used within a narrow AI++ control range, and if it goes outside the 91st point, the efficiency will drop significantly. However, according to the present invention, since a screw type air compressor is used, the drawbacks of the prior art are overcome. Further, combustion problems caused by pulsation caused by using a screw type air compressor can be solved by improving pulsation damping and by providing a pressure reducing means to average the air pressure in the combustion chamber. 4. Brief Description of the Drawings FIGS. 1 and 2 are flow sheet diagrams of different embodiments of the power generating device of the present invention, and FIG. 3 is a flow sheet diagram of the prior art. 1. Screw type or turbine type expansion machine as rotary expansion ll1lil, 2. Screw type air compressor, 3. Combustion chamber, 4. Expansion machine as pressure reduction means, 9.
- Fuel supply pipe, 10... Generator, 15... Pressure tank as pulsation damping means, 17... Pressure reducing valve as pressure reducing means.

Claims (6)

[Claims] (1) A screw type air compressor and a rotary expander are directly connected, and the high pressure air from the air compressor is sent to the combustion chamber via the pulsation damping means and the pressure reduction means, and the fuel from the fuel supply pipe is sent to the combustion chamber. A power generating device characterized in that the combustion gas is introduced into the rotary expander and then combusted, and the combustion gas is expanded in the rotary expander to generate power. (2) The power generating device according to claim 1, characterized in that a pressure tank and a pressure reducing valve are sequentially provided between the air compressor and the combustion chamber, so that the combustion chamber serves as a flasher tank. (3) The power generating device according to claim 1, wherein the pressure reducing means is a low-pressure air expander. (4) The power generating device according to claim 3, characterized in that a fuel oil injection pump is connected to a low-pressure air expander. (5) The power generating device according to any one of claims 1 to 4, wherein the rotary expander is a screw type or turbine type expander. (6) The power generating device according to any one of claims 1 to 5, characterized in that the combustion chamber is provided with an ignition burner that is kept ignited at all times.