KR890007809Y1 - Power generator - Google Patents

Abstract

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Description

Power generator

1 is an external view of the present invention.

2 is a cross-sectional view of the present invention.

3 is an external view of the rotor of the present invention.

4 is a front and side view of FIG.

5 is a cross-sectional view taken along the line A-A of FIG.

6 is a cross-sectional view taken along the line B-B in FIG.

7 is a cross-sectional view taken along the line C-C of FIG.

8 is a cross-sectional view taken along the line D-D of FIG.

9 is a cross-sectional view taken along the line E-E of FIG.

10 is a flow chart of the working fluid for the power generation process of the present invention.

* Explanation of symbols for main parts of the drawings

1: gas supply rotor 2: power rotor

5, 6: hub 7: gas inlet

8, 8 ': Gas passage 9: Exhaust port

20: gas carrying pocket 21: expansion pocket

44: gas supply chamber 55: expansion chamber

The present invention relates to a power generator for generating power from high pressure compressed gas.

The object of the present invention is to provide an ideal power converter capable of high speed operation like a gas turbine, good thermal efficiency like a piston reciprocating engine, and no exhaust noise and small size and high power.

Piston reciprocating engines have considerably higher thermal efficiency because of the high temperature / pressure of the working fluid. However, the piston engine has disadvantages that cannot be improved in structure, that is, heavier, vibrating, energy exhaust loss and exhaust noise.

Panhyeon. The gas turbine has the advantage of low temperature, pressure, and low thermal efficiency, but low weight, no vibration, continuous power generation and high output.

If a gas turbine and, for example, a diesel engine all operate at the same compression ratio, the thermal efficiency of the gas turbine will be higher than that of the diesel engine.

However, gas turbines are not easy to cool all elements that come into contact with hot working fluids and cannot operate at high compression ratios as high as diesel engines.

In an internal combustion engine, the higher the compression ratio, the higher the temperature of the working fluid and the higher the thermal efficiency.

And the higher the engine runs, the higher the output. Therefore, the engine must operate at high compression ratio and high speed in order to produce high power with high thermal efficiency.

However, if the compression ratio is high, the temperature of the working fluid is also high.

Therefore, all elements that come into contact with the hot working fluid must be adequately cooled to prevent them from overheating and to maintain an oil film on their sliding surfaces (eg cylinder walls).

And in order for the engine to run at high speed, all the rotors must be balanced with the moment of inertia about their axis of rotation to enable high speed rotation.

Power is generated when a pressurized gas expands by the reverse of the piston in the cylinder. However, when flowing into a given space and expanding in an instant in an irreversible process, no power is generated, but instead the gas entropy increases.

Thermodynamically, as the entropy increases in the internal combustion engine, the thermal efficiency of the engine is correspondingly reduced.

Therefore, in an internal combustion engine, there is no irreversible expansion process in which the gas expands in an instant, or if present, this irreversible process should be minimized.

That is, the gas must be expanded in a copper entropy process.

Since the planetary rotary vankel rotary engine has been realized as one internal combustion engine, many different types of rotary engines have been invented.

However, none of them solved the problems of adequate cooling related to the high compression ratio described above, the balance of the rotor's moment of inertia for high speed operation, and the expansion of the gas in the entropy process.

Thus, none of the inventions were realized as an internal combustion engine.

These problems are all solved by the present invention.

Furthermore, the present invention is designed to operate in a Brayton cycle or Rankine cycle, such as a gas turbine or steam turbine, but has a higher thermal efficiency than that of a gas turbine or steam turbine operating at the same compression ratio.

Because in gas turbines and steam turbines, the energy of the high pressure working fluid is converted into kinetic energy by expansion through the nozzle, and then useful power is obtained from this kinetic energy, which greatly increases the entropy of the working fluid. The kinetic energy of the working fluid leaving the last stage is not available, but the energy of the high pressure working fluid is not converted into the kinetic energy which causes the entropy increase, but is directly converted into the useful power.

In order to solve this problem, the present invention installs a gas supply chamber and a gas expansion chamber (larger than a gas supply) in which a pair of empty hollow rotors are installed side by side, and connects them by two passages. When a certain amount of high-pressure gas flows from the gas supply chamber into the expansion chamber by the rotation of the rotor and rotates the rotor of the expansion chamber, it is designed to expand (power generation).

The present invention consists of two large and small workshops that are close to each other. Each work room has a shape in which two cylindrical vessels each having fixed shaft hubs 5 and 6 shaped like cylinders are respectively overlapped.

In each of these chambers a pair of piston rotors, similar to the rotor of the circumferential piston pump, is arranged to be supported by each fixed shaft hub as in the circumferential piston pump.

That is, the rotors are configured to circularly move around the fixed shaft hub in the workshop.

According to the present invention, by the circular motion of these rotors, high-pressure combustion gas is transferred from a small work room to a large work room, thereby producing expansion and power.

In the future, this small work chamber will be referred to as the gas supply chamber 44 and the large work chamber as the expansion chamber 55.

As shown in FIG. 2, there is a gas inlet 7 in the gas supply chamber 44 and an exhaust port 9 in the expansion chamber 55, and these gas supply chambers 44 and the expansion chambers 55 are combustion gases. The holes are connected by two small passages so that gas can flow from the gas supply chamber into the expansion chamber.

This passage is hereinafter referred to as gas passage 8 (8 ').

The gas passages 8 and 8 'are lined with a heat resistant material.

The gas supply chamber rotates the pair of rotors to supply a certain amount of combustion gas from the gas inlet 7 to the expansion chamber through the gas passage 8.

These rotors are hereinafter referred to as gas supply rotors 1.

On the other hand, the rotors of the expansion chamber are rotated by the high-pressure combustion gas, which will be referred to as the power rotor (2) in the future. Both of these gas supply rotors 1 and power rotors 2 can be rotated at high speed without vibration because the moment of inertia about the rotation axis is perfectly balanced.

All rotors protrude two places symmetrically.

Thus, all the rotors have recesses formed between the protrusions.

However, this recessed space is completely surrounded by the gas supply chamber wall surface 3 or the expansion chamber wall surface 4 when the rotor rotates, and is also partially enclosed and opened.

In the future, each of the recesses formed in the gas supply chamber and the expansion chamber is referred to as a gas carrying pocket 20 and an expansion pocket 21, respectively.

Therefore, there are four gas transport pockets 20 in the gas supply chamber 44, and four expansion pockets 21 in the expansion chamber 55 as well.

Inside the rotors there is a passage 10-16 symmetrically arranged inside the body as shown in FIG. Through this passage, the refrigerant (air, water or oil) is circulated to remove heat absorbed by the rotor from the hot working fluid.

In the future, this passage is called a refrigerant passage.

The rotors of the present invention are designed to be circular in the state supported by the fixed shaft hubs 5 and 6 at the same rotational speed by the timing gears in the timing gearbox 25. These rotors do not engage or touch each other as they rotate.

Furthermore, they are not intended to be in direct contact with the walls 3, 4 of the associated gas supply chamber and expansion chamber, except for the bearing part.

In the housing of the expansion chamber, a pair of valve nozzles 22 are arranged as shown in FIG. 2 in order to prevent the pressure in the expansion chamber from dropping below 1 atm, where the shank automatically opens and closes according to the pressure difference. Although not shown, the valve 23 is provided with at least one pair of poppet-type valves operated by a cam and a tab such as a suction valve of a piston reciprocating engine.

This valve is hereinafter referred to as a bridging valve. In addition, in the housing of the expansion chamber, there is an instrument nozzle 19 for sensing the pressure in the expansion chamber after the expansion process, and a pressure sensing instrument PI is installed therein.

In the future, this instrument is called an exhaust pressure sensor.

In the drawings, reference numerals S and S 'are shafts of respective rotors, 5' and 6 'are hubs (5) and (6) flanges, C is a power generator of the present invention, D is a generator, and F is a fuel supply pump. , G is the fuel tank, H is the radiator and K is the cold water (refrigerant) circulation pump.

When the present invention configured as described above is equipped with a compressor (A), a combustor (B), a peripheral device for cold steel, etc. as symbolically shown in FIG. 10, the present invention operates in a Brayton cycle like a turboshaft engine.

In other words, it is like connecting the subject innovation instead of a turbine in a turbine shaft engine.

Thus, like the turbine, the present invention also produces power by high pressure gas.

However, the power production method of the present invention is also different from that of a turbine.

In the turbine, the pressure of the gas is converted to the high-speed motion of the gas by expansion through the nozzle of the high-pressure gas, and then power is generated by the gas colliding with the turbine blade (BLADE), but in the present invention, as in the piston engine Power is generated directly from the pressure.

As shown in FIG. 10 of the present invention, the peripheral device is provided so that hot / high pressure combustion gas flows from the combustion chamber into the gas inlet 7 of the present invention and enters the open gas carrying pocket 20. do.

Next, when another gas carrying pocket is opened as the rotor rotates, the already opened gas carrying pocket is sealed, and the hot and high-pressure combustion gas in the sealed pocket is transferred to the expansion chamber and displaced.

That is, when the gas carrying pocket is supplied with gas from the gas inlet 7 and closed, the gas carrying pocket 20 rotates about one half of the gas carrying pocket 20 through the gas passage 8. And the high pressure combustion gas in this pocket flows into the front corner of the expansion pocket 21 which is just connected through the gas passage and rotates the power rotor 2 until it expands to atmospheric pressure.

Power is then generated and the space in front of the expansion pocket grows to form a complete expansion pocket. Then, the expansion pocket containing most of the expanded combustion gas is sealed, so that the expanded combustion gas is separated into a small amount of combustion gas existing outside the expansion pocket. Then, while a large amount of combustion gas is transferred to the exhaust port 9 so that the combustion gas is discharged to the atmosphere, a small amount of combustion gas from which the high pressure combustion gas from another gas conveying pocket 20 expands to perform the next expansion process. Flows into the front corner of the expansion pocket where it stays momentarily, mixes with them, and expands to produce power as previously described.

Immediately before the high pressure combustion gas enters the front corner of the expansion pocket in this expansion process, the space in the front corner of the expansion pocket is hereinafter referred to as the dead space 24.

In this unexpanded process, a small amount of combustion gas that is fully expanded is left in the dead space 24 and a high-pressure combustion gas enters.

Therefore, the high pressure gas expands for a while without generating power as it enters the dead space, so the smaller the entropy of the gas is, the better.

Next, after the gas has expanded in the dead space, it expands as the rotor rotates, producing power.

Instead of the piston rotor (1, 2) and the fixed side hub (5, 6) of the present invention, a rotor that meshes with each other, for example, a rotor of a well-known rotary lobe pump (LOBE PUMP) In the structure assuming that the dead space described above is very large.

However, the present invention, which consists of a piston-type rotor mounted on a fixed shaft hub so as not to interlock with each other, does not make the dead space 24, but it makes it possible to make the dead space smaller than that of any other type of rotor. It is characteristic.

Therefore, in the present invention, the combustion gas is expanded while producing most of the power, and most of the combustion gas that has been expanded in the previous expansion process can be exhausted without being mixed with the high-pressure combustion gas of the next expansion process.

In the present invention, the flow of the workdue is uniform at the gas inlet 7 and the exhaust port 9, and the above-described processes of inflation and exhausting occur four times for each revolution of the rotor.

Therefore, the pulsating power four times per one rotation of the rotor alternately occurs from the two power rotors 2.

The pressure in the expansion pocket 21 sealed in the expansion chamber is hereinafter referred to as closed pocket pressure.

This closed pocket pressure is always maintained at 1 atmosphere.

If the closed pocket pressure is below or above 1 atm, the pressure difference with this atmospheric pressure is not only an energy loss, but also causes exhaust noise as in a piston engine during the exhaust process.

The present invention has a large enough size of the power rotor so that the closed pocket pressure is 1 atm at the maximum output. In other words, the power rotor has a sufficiently large scale as compared with the gas supply rotor so that the closed pocket pressure does not exceed 1 atm for the maximum amount of fuel injected into the combustion chamber.

Therefore, the present invention does not exceed 1 atm of closed pocket pressure during normal operation.

On the other hand, when the pressure in the expansion chamber is 1 atm or less, the check valve 23 is automatically opened according to the pressure difference, so that the atmosphere immediately flows into the expansion chamber through the check valve.

Thus, the vibration of the closed pocket pressure drops below 1 atm.

Instead of this check valve, a valve (a bridging valve) such as an intake valve used in a piston reciprocating engine may be used.

This bridging valve can be actuated by cams and levers which are normally used depending on the amount of fuel injected into the combustion chamber.

In other words, if the amount of fuel injected into the combustion chamber decreases, the bridging valve opens quickly, and if the amount of injected fuel increases, the bridging valve opens late, so that the bridging valve opens just before the closed pocket pressure drops below 1 atm. .

However, the atmosphere flows into the expansion chamber, whereby the closed pocket pressure is always maintained at 1 atmosphere. In FIG. 10, the outlets of the check valve and the brising valve described above are open to the atmosphere.

This is more helpful in explaining and understanding the present invention.

However, although not shown, it is better to connect the outlet of this check valve or bracing valve to the exhaust port 9 by piping all.

Therefore, when these valves are connected and operated, a part of the exhaust gas flows back from the exhaust port 9 and flows into the expansion chamber.

Nevertheless, the closed pocket pressure is still maintained at 1 atmosphere.

Thus, in the present invention, a positive pressure exhaust process is achieved, and exhaust noise is thus eliminated.

All the rotors 1 and 2 of the present invention have a very wide circumferential surface of their protrusions close to the gas carrier wall 3 or the expansion chamber wall 4 and their bodies as shown in Figs. 5-9. Refrigerant passages 10-16 are provided to circulate the refrigerant through the inside.

Therefore, the work absorbed by the rotor from the hot combustion gas is discharged to the outside through the wide circumferential surface and the circulation of the refrigerant through the refrigerant passage 10-16.

2 does not consider any means for its cooling with respect to the housing of the present invention, but should also be adequately cooled.

Cooling of this housing is possible by a well-known technique.

In other words, if the WATER JACKET or COOLING FIN is formed in the housing of the present invention, the housing can be cooled appropriately.

In a piston reciprocating engine, the circumferential surface of the piston slides in oil contact with the cylinder wall surface. Therefore, if the temperature of the cylinder wall becomes high, the oil film is destroyed on the sliding surface, and they make metal contact.

For this reason, when the cooling method of a piston engine is air-cooled, the engine must be operated at a lower compression ratio (i.e., lower temperature) than a water-cooled engine in order to keep oil film on slip.

Thus, although the cooling loss is reduced, the thermal efficiency is lower as a result.

However, in the present invention, all the surfaces of the rotor are not in direct contact with the wall surfaces of the associated gas delivery chamber 44 and the expansion chamber 55. In other words, all sliding surfaces of the rotor maintain a very close clearance with the associated combustion chamber and expansion chamber walls 3, 4, and are in contact with each other and may be in oil contact.

Moreover, even if airtightness is somewhat insufficient in gas carriers, this does not have a significant structural impact on the thermal efficiency.

There is also a fixed shaft hub (5) (6) there is no sealing of gas between the rotor and the rotor is required to form the pocket (20) (21) to operate the present invention at a higher temperature It is possible to line the curved surface of the rotor with heat-resistant heat-resistant material.

For this reason, the present invention is air-cooled and can be operated at a high compression ratio.

At this time, the air passes through the refrigerant passage 10-16 inside the rotor body.

When the engine is air-cooled and operated at a high compression ratio, the cooling losses are reduced and the thermal efficiency is somewhat improved.

As described above, in the present invention, in the case of producing power by the Brayton cycle as in a turbo engine, unlike a turbine, a high pressure is applied to a piston (rotor) that rotates to minimize an increase in entropy, which causes a decrease in thermal efficiency of the engine. Its working fluid is designed to produce power.

In other words, the present invention generates a power as the working fluid expands in a piston reciprocating engine because of the small dead space, and gradually expands, but unlike a piston engine, the power is generated in a Brayton cycle having a constant pressure exhaust process. have.

In addition, the present invention can be operated at a high speed, such as a turbine, and the temperature of the working fluid can be increased as in the piston reciprocating engine in the present invention, the thermal efficiency is good and small and high power is possible.

Furthermore, in the present invention, the exhaust noise is removed because the positive pressure exhaust process is satisfied.

Therefore, the present invention can also be used as a silencer.

Claims (1)

In the gas supply chamber 44 and the expansion chamber 55 larger than this, the empty gas supply rotor 1 and the power rotor 2 are respectively arranged to rotate the hubs 5 and 6 axially, And a gas generating chamber (44) and an expansion chamber (55) communicating with each other through a gas passage (8) (8 ').