JPH0354306A - Expansion method and device - Google Patents

Abstract

PURPOSE:To suppress temperature drop of working gas and enlarge expansion work by heating by pouring, from a nozzle, high temperature liquid over the surface of a piston when the piston is in its downward stroke. CONSTITUTION:In a reciprocating expansion machine, a piston 2 in a cylinder 1 moves toward a direction marked with an arrow 3, and gas flowed into the space ABQP from a valve 6 expands. High temperature liquid in a tank 14 is then pressurized with a pump 10, and poured over the surface PQ of the piston 2 from a nozzle 9. With the return of the piston 2, the high temperature liquid is discharged from a valve 7 together with exhaust gas, and brought back to a high temperature again with a heater 13 after passing through a passage 8 and an accumulator 11. Since the temperature drop of working gas can thus be avoided, the gas expands without experiencing any compression of its volume so that expansion work can be enlarged.

Description

[Detailed Description of the Invention] (Industrial Application Means) The present invention relates to a device that utilizes gas expansion. For example, it relates to internal combustion engines and gas turbines.

(Conventional technology and its problems) Conventional gas expansion devices burn fuel in the cylinder when the volume between the cylinder and the piston becomes small, create high-pressure gas, and push the piston to expand. When expanding the volume or injecting high-pressure gas into a low-pressure area using a nozzle, as the pressure decreases within the nozzle, the gas expands, increases its speed, and is injected with a high-speed flow to rotate a turbine, etc. The disadvantage is that when the gas expands, the temperature drops and the energy due to the expansion decreases, as seen in cases where the gas expands. This invention provides an efficient expansion device, such as a turbine or an internal combustion engine, by accurately grasping the temperature drop of a gas, reducing the temperature drop of the gas, and increasing the work of gas expansion. (Means for solving the problem) Generally, when gas is expanded, it is cooled. The explanation is shown in FIGS. 1 and 5.

Assume that the gas in the cylinder l is expanded by the piston 2 at a speed of V. Assuming that the gas molecules 4 in contact with the cylinder surface AB have a vibration velocity of V due to molecular vibration, the AB surface is stationary, but the molecules 4 colliding on the AB surface
bounces back at the same speed V after the collision, so the vibration speed remains the same, so the temperature of the molecules remains the same. The same applies to AD and CB surfaces.

However, since the PQ surface is moving at V in the direction of arrow 3, the molecule of 5 repelling on the PQ surface of the piston 2 bounces back at a speed of (v-V), and the vibration speed decreases, so the molecule's The temperature drops. Therefore, there is gas inside the cylinder! Generally, the temperature of the gas decreases during printing.

[According to molecular kinetic theory, vcl: -7T (absolute temperature)] At this time, if the surface PQ surface of piston 2 is higher than the temperature of molecule 5, when molecule 5 repulses, it receives heat from the PQ surface and its temperature rises. Therefore, it is possible to suppress a drop in temperature due to expansion, and it is possible to expand in a state close to isothermal expansion.

Figure 5 explains the case where the gas expands inside the nozzle. It is assumed that the gas flowing into the AB plane is constricted and discharged from the CD plane. Between AP and BP, streamlines flow in parallel, and Bernoulli's gas flows in parallel. According to the law, the flow velocity is higher on the CD surface than on the AB surface. Since the streamline is narrowed between PQ, PQ
During this period, a speed like V in the diagram occurs. This V is P
A. It does not occur between PCs. Due to this velocity between PQ, the vibration velocity of molecules colliding with the PQ surface becomes (v-V) and becomes smaller, so that the temperature of the molecules decreases.

Therefore, in this case as well, as in the case of FIG. 1, if the PQ surface is heated to a higher temperature than the gas molecules, the gas can be expanded in a state close to isothermal expansion (effect). If the PQ surface is constantly heated so that it is kept in a high temperature state, the gas expands and cooling is avoided, so expansion close to isothermal expansion can be achieved. Figure 7 shows
It shows the work of expansion when there is an isothermal change. The diagram shows specific volume on the horizontal axis and pressure on the vertical axis. Gas in state A is compressed and burnt as B, resulting in state C (the temperature is higher in the H direction).
and increase the specific volume. Conventionally, when expanded from state C, state D is close to adiabatic expansion, but if it is expanded isothermally, the temperature does not drop, so state D is higher than state D.
', and from the conventional adiabatic expansion work ABCD, the area CD
Since D' becomes large ABCD' and the expansion work becomes large, it is possible to obtain an expander that is advantageous in terms of energy. (Embodiment) An embodiment of the present invention will be described with reference to the drawings. Fig. 2 shows a cylinder of a reciprocating expander, in which a piston 2 moves in a direction 3 in a cylinder 1, and a space ABQP flows in from a hull 6. When the gas inside expands, as mentioned above, the gas becomes PQ
The temperature decreases due to the repulsion of the surface, so by pouring a higher temperature than the nozzle 9 onto the PQ surface and heating the PQ surface, the temperature drop of the gas can be avoided.The gas expands without shrinking in volume, so it performs expansion work. It can be made larger. When the piston 2 returns, the high-temperature liquid is discharged from the valve 7 along with the exhaust gas. Sprayed from a nozzle.

FIG. 3 shows one embodiment of a crank piston, in which the piston 17 and the cylinder 17 are double cylinders, and the valves 17-l, 17-2, 17-3,
It is assumed that cylinders 18', 19', and 20' corresponding to the pistons 18, 19, and 20 in which the cylinder 17-4 is installed are also equipped with valves in the same way as the cylinder 17. It is assumed that the pistons 17, 18, 19, and 20 are driven by the crank 16. In Figure 3, 17 compression, l8 expansion, 1
Assuming the starting point for 9 exhaust and 20 intake, exhaust valve 19-
When the high-temperature exhaust gas discharged from cylinder 4 is introduced into the back side of piston 17 through valve 17-3, piston 17 compresses the air in cylinder 17', the back side of piston 17 is filled with high-temperature exhaust gas, Next, the histones can be sufficiently expanded because they are constantly heated by the exhaust gas during the combustion expansion process. The front side of the piston is the side where the fuel enters, and the back side of the piston is the side where the exhaust gas enters. 1
If cylinder 7' is in the exhaust process, exhaust valve 17-
The exhaust gas coming out from 4 passes through the valve 19-3 to the piston 19.
All you have to do is send it to the back side of the . The exhaust gas that has entered the back side of the piston l7 is discharged through the valve 17-3 during the expansion process.

Figure 4 shows an example of a rotary vane type expander.
When the rotor 30, which has a movable vane 32 and rotates within a solid cylinder 3l, rotates eccentrically with respect to the cylinder 31, the distance between the rotor 30 and the cylinder 31 changes depending on the angle, and the E point is the minimum and the F point is the maximum. Become. Air enters through the inlet at 2F and is compressed while its volume decreases until it reaches the fuel inlet at 21. When the fuel burns in space 22, the combustion gas expands and exits as exhaust from the outlet at 24. 29
is the direction of rotation. At this time, part of the exhaust gas is guided into the cover 25, heated in the cylinder 31, and discharged from 26. In addition, the space 22 to 23 is in the expansion process, and the inner surface of the cylinder 31 is a PQ surface. Gases can expand without being cooled. Therefore, sufficient expansion work can be achieved.

FIG. 6 shows an example of expanding and accelerating gas within the nozzle as described in FIG. By doing so, the gas is sufficiently expanded, and
High-temperature gas is sent from outlet 15 to help expand the heated gas on the surface of section 33. This is because the portion 33 is the expansion surface and the PQ plane as described above.

8 and 9 show an application of the above-mentioned principle to a rotary turbine. High-pressure gas sent from the inlet 43 of the stator 40 is accelerated by the nozzle 36 from the high-pressure gas chamber 37, and is accelerated by the blades of the rotor 39. 'l38, rotor 39
is rotated to form a stream 41, which is discharged from an outlet 42. At this time, by sending high-temperature fluid into the nozzle cover 44 shown in FIG. 9, the gas can be expanded and accelerated while preventing the temperature of the gas from dropping. 10 and 11 show an example of application to an axial flow turbine, in which a rotor 45 equipped with blades 55 and a load 61 are shown.
rotates around the shaft 60 and injects fuel into the combustion chamber 50 of the stator 46 equipped with guide vanes 4156.
Twisted, and also air is inserted into the population 49, the passage 51, and the injection port 53.
the rotor blades 55 from the nozzle 54.
to rotate the rotor. Next, the combustion gas enters the guide vane 56 from the vane 55, is accelerated, enters the next vane 55, and finally is discharged from the outlet 47. Separately, if high-temperature fluid is guided to the guide vane 56 from the high-temperature fluid passage 58, high-temperature chamber 57, and passage 59 and heated, the PQ surface of the nozzle will be heated as described above, so the gas inside the guide vane will be thoroughly heated. It can be expanded and accelerated.

The high-temperature fluid may be introduced from the combustion chamber 50 or from the exhaust gas of the first turbine blade, as long as it can heat the guide blade. 52 is a combustor.

(Effects of the Invention) As described above, according to the expansion method and expansion device of the present invention, in the expansion of gas, there is a problem that conventionally it was not possible to obtain sufficient expansion work due to a decrease in the temperature of the gas. As shown in the figure, the work of the conventional ABDC has been reduced to BAD' C by the method of the present invention, so an extremely large work can be obtained, so even if the required fuel for internal combustion engines and combustion turbines is reduced, the same result can be achieved. It is possible to produce a large amount of output, and it has desirable effects both economically and in terms of pollution.

[Brief explanation of drawings]

Figures 1, 2, and 3 are side views of an example in which the present invention is used for reciprocating expansion. FIG. 4 is a side view of one application of the present invention in the case of a vane type rotary expander. Figures 5, 6, 8, 9, 10, and 1l are examples of side views of the present invention when applied to gas expansion acceleration. Figure 7 is a diagram of the thermodynamic principle of the present invention. 1... Cylinder 2... Piston, 2'... Cover, 3, 3'... Direction, 4, 5... Gas molecules, 6, 7...
Valve, 8...Passage, 9...Nozzle, ]O...Bomb,
11, 14...tank, 13...heater, 15...tapered passage, 16...crank, 17, 18, 19, 20...piston, +7'
18', 19'20'...Cylinder 17-
1, 17-2, 17-3, 17-4, l8-1, 18-
2, 18-3, 18-4, 19-l. ．． 19-2, l9
-3, 19-4, 20-1, 20-2, 20-3, 20
-4, Valve, 21... Fuel inlet, 22, 23... Space, 24... Exhaust outlet, 25... Cover, 26... Outlet, 2
7.Air inlet, 28.Space, 29.Rotation direction, 3
0... Rotor 31... Cylinder 32... Vane, 33... Tapered passage section, 34... Inlet, 35... Outlet, 36... Nozzle, 37... High pressure chamber, 38... Vane, 39... Rotor ,
40...Stator, 41...Flow, 42...Outlet, 4
3. High pressure gas inlet, 44. Cover, 45. Rotor 4
6... Stator 47... Outlet 48... Fuel inlet, 49... Air inlet, 50... Fuel chamber, 51... Passage, 52... Combustor, 53... Jet outlet, 5
4... Nozzle, 55... Vane, 56... Guide vane, 57
...High temperature fluid chamber, 58, 59...Passway, 60...Axis, 6
1. Load AB, AD, BC: Cylinder outer wall, PQ
: expansion surface, ■, V: velocity, AP, BP, BQ, QII outer wall, outer tube, A. B, C, I
): state, P. P. :Pressure, vs Vo VII'V
n': Specific volume, H: Direction, E, F: Position ◆ Ic7j Baboon r'$ Zero-kan←3 躬g figure procedural amendment E&/June/ra

Claims (1)

[Claims] 1) A reciprocating gas expansion method characterized by heating the expansion surface of a piston in a reciprocating gas expander. 2) A gas expansion method according to claim 1, characterized in that the heating liquid is directly injected or poured onto the gas expansion surface of the piston to heat the expansion surface. 3) An internal combustion engine that uses a reciprocating piston and is characterized by sending exhaust gas to the back surface of the piston to heat the surface of the piston. 4) A steam engine using a reciprocating piston, which heats the surface of the piston by sending exhaust gas to the back surface of the piston. 5) A gas expansion method characterized by heating the casing during the gas expansion stroke in a vane type gas expander. 6) Expansion method and device, characterized in that the casing is heated by exhaust air in the method according to claim 5. 7) A gas expansion method characterized by accelerating a gas acceleration nozzle in a turbine engine. 8) An axial flow multi-stage turbine characterized in that the stator is heated by introducing gas or discharge gas to a higher temperature inlet in the axial flow multi-stage turbine. 10) A gas expansion method characterized by accelerating the acceleration surface of a gas acceleration nozzle. 11) A gas expansion method characterized by injecting high temperature fluid onto the accelerating surface of a gas accelerating nozzle.