DE534402C - Thermal power machine, especially turbine, and method for their operation - Google Patents

Description

Heat engine, particularly turbine, and method for their operation Steam engines are known in which superheated steam in the machine is used, then completely or partially condensed in a cooler and then the steam-water mixture pumped back into the superheater by a compressor for reuse in the circuit will. In this working process, on the one hand, excessive cooling causes heat of vaporization and on the other hand, compressor work is lost due to pumping over. Steam engines are also known, in which part of the exhaust steam passes through the remaining part of the exhaust steam by means of a turbine and compressor back to the original pressure, if necessary after the compression subsequent overheating, compressed and then again in the steam engine cycle is fed. In this machine, on the one hand, the compression work is useful work lost and, on the other hand, the heat of evaporation from the one driving the compressor system Part of the exhaust steam that is fed to a condenser or to the atmosphere.

There are also known compressed air machines in which heated compressed air fed to a turbine for work performance, then strongly cooled and through a compressor connected to the turbine in the circuit of the heating device again is fed. In this machine, the frictional work power consumed for the compressor goes lost for useful power.

Also known are heat engines in which a steam generator is assembled directly with a steam turbine in such a way that the steam turbine either installed inside the steam generator or arranged around it on the outside is. Either the steam generator rotates with the turbine or it is stationary arranged. The steam used in the turbine is either condensed or escapes through an exhaust pipe. The im Heat of vaporization contained in water vapor is lost.

The invention relates to a method for operating a heat engine, those with alternately heated and cooled, non-liquefied steam or gas works, and the essence is that superheated steam or a gas only so much heat is extracted through the release of energy in a heat engine, that the means of work, by virtue of its living force, is complete or as one essential part in a direct without the interposition of a compressor behind the machine, closed, relatively cool receiving container flows in without liquefaction, whereupon it is after the container has been switched off and heated in this the machine is fed back. Going through this procedure will not only complete when using easily liquefied vapors or gases Preventing the loss of heat of evaporation, but also when using vapors or any gases avoiding the loss of expendable for a compressor, not achievable work performance and therefore the overall efficiency compared the known machines increased considerably.

The heat engine is expediently designed in such a way that that it consists of a ring designed as a rotary valve with preferably radially connected, alternately heated and cooled steam or gas containers exist, their rooms when rotating the ring via a power generator, for example a turbine, alternately connect to each other in pairs. Two radially to each other opposite containers advantageously form a pair of containers, of which During rotation, one is heated, the other is cooled by the container the machine alternates with one or more circular arcs as it rotates Pass through the surrounding heating and cooling rooms. This arrangement makes a faster Change of the heat engine passing through, individually housed in the containers Allowing amounts of steam, such that each brought into effect in the engine Amount of steam can be immediately returned to a boiler room without prior condensation. In each of the refrigerated rooms, only the container wall and its sides are in circulation a small amount of steam remaining in the container cooled, so that the thereby heat losses are low.

Instead of water vapor, other vapors or gases such as ammonia can also be used or air, can be used to operate the machine, and when using air are advantageous devices for injecting fuel for combustion provided with the air contained in the containers and heating them and further Devices for discharging the used air and blowing fresh air into the surrounding containers. It is advantageous when using a turbine as the engine the design of the lines leading from the rotary valve ring into the turbine as nozzles and the drive of the rotary valve ring by a gearbox of the turbine, expedient such that the connection of a pair of containers is interrupted as soon as it approaches Pressure equalization between the two containers is achieved.

The drawing illustrates the invention in one embodiment and brings other valuable arrangements. Fig. I shows a rotary valve ring together with a pair of vessels and a turbine housing in a schematic representation, Fig. 2 a working diagram of the machine, fig. g a vertical section and fig. q. a horizontal section through the machine, Fig.5 a modified embodiment the machine.

In the device shown there is a hot working substance superheated steam and, as a cold substance, approximately saturated steam, air or a Gas used at different temperatures.

Fig. I schematically represents a member of the device. A and B are two containers of the same volume, which are radially opposite one another, are connected by a ring 6 and rotate clockwise: X is a cold field. Y is a hot field.

The same is in the containers at the beginning of the work Amount of working material, for example as saturated steam.

In the position shown in Fig. = There is a closed connection Aa DbB. A and b denote conical nozzles or outlet nozzles, D a turbine.

The container goes up to the position shown in Fig. I A through the hot field, and the saturated steam is superheated with unchanged space.

If initially when passing through the hot field in the container A was a pressure P, then as the temperature rises, the pressure will also increase, while in the container B the pressure falls when passing through the cold field.

For example, with an initial pressure of P = q increases. atü. and at overheating to 450 ° the pressure for water vapor up to 7 atü. When the connection A-a-D-b-B produces as a result of the rotation of the containers A, B, then arises as a result of the Pressure difference in the two vessels a flow from A to B.

The entire static pressure of the steam is converted into energy for the movement of the steam when it passes through narrowed openings at the ends of the container and through conical nozzles a, b, according to the pressure difference.

Part of the kinetic energy is used for the useful power of the turbine consumed and the other part for increasing the steam pressure in the Bel4älters B. When the pressure in tank B reaches its greatest value, the connection interrupted, otherwise the steam would flow back. The container A now passes through the cold field with the reduced steam content, because a part of the steam is due to the pressure difference and the inertia in the Container B passed over. When passing through the cold field, the pressure still falls more. At the same time, the container B passes through the hot field, which becomes steam in B. if the space remains the same, it overheats and its pressure increases. After one turn the process is repeated by 180 °, but with one appropriate Swap the steam content compared to the first process.

In this way a pair of containers is obtained with one full revolution two bursts of propellant, which set the turbine D in motion.

Fig 2 is a. Diagram of the heating process. The straight line i-2 represents represents the overheating of the steam with the same space. This process takes place when passing through the hot field. Curve 2-3 represents the conversion of potential energy in kinetic energy when passing through the cone-shaped Nozzle of a back pressure turbine; the curve 3-q. the further fall of the vapor pressure in the turbine, which is the useful power of the steam in the turbine and the for the increase in steam pressure in the opposite container power expended corresponds, which is caused when the connection A-a D-b-B is closed.

The straight line q.-5 represents the fall of the vapor pressure at constant Space during the vessel's run through the cold field after the suspension the connection A-a-D-b-B. The curve 5-i represents the increase in pressure from the moment the connection A-a-D-b-B is established for the purpose of transferring the vapor from the hot container into the cold container until this connection is interrupted.

Because the to increase the pressure of the steam and corresponding overheating Work expended (curve 5-i) reduces the amount of heat released by the press steam is recorded when passing through the container over the hot field (straight line i-2), so this loss will not cause any noticeable reduction in efficiency.

The loss of heat in the process described is only be the loss in the passage of the container through the cold field, and there the points ¢ and 5 (Fig. 2) can be approximated, so the efficiency of the heating process be high.

According to Fig. 3 and q. form the hollow bodies A, A 1 ... B, Bi, B2 . . . same content an annular, rotating. Superheater. The hollow bodies have hollow pins i which slide between the cylindrical rings 2 when the superheater rotates.

All parts between the inner ring 2 and the axle are through the jacket of the turbine 3 held. This coat has an iron base plate attached to the foundation, 5 are hollow spokes, which the hollow body with the sliding blocks of the rotary valve ring 6 connect, and which have narrowed openings. The openings the sliding shoes and spokes meet.

Two rows of spokes are shown in the drawing, but it can also a row in the middle of the turbine length can be used.

The casing of the turbine carries rings 7 on which the ring 6 slides, and those equipped with two diagonally opposite conical nozzles are.

The outer parts of the pin -i are provided with the ring gear Ring 8 includes which io by the gear driven by the turbine shaft all steam tanks of the superheater are kept in rotation.

ii is a container with working fluid, which is under pressure is located. 12 is a slide that rotates with the superheater. The slider is connected to the hollow bodies by tubes 13. The container ii will run out of time at times connected to the interior of the hollow body by the meeting of the openings.

The tubes 13 have valves 1q., Which are in the direction of open the hollow bodies. The pressure in the container ix is at such a level held that when the pressure in the cooled hollow bodies falls below the norm the feeding of the hollow body takes place by the working fluid.

15 are gate valves, which at the start of work the turbine from Separate the superheater when filling the hollow body with the working fluid.

23 are safety valves for releasing the steam if the pressure is exceeded; 17 is the fireplace. 24 is a pump or fan to cool the cold Field. In the case of air cooling, the air can be used for heating by means of pipe 25.

The following can serve as operating fluid: i. Water when you are strong Energy sources, e.g. B. fuels used.

2. Carbon dioxide or ammonia, if weak energy sources, e.g. B. Steam, hot and cold sewage from workshops or the water of the upper and lower layers of the tropical seas.

In the latter case, the hot field is used by means of a pump warmer waters of the upper layers of the tropical sea. and across the cold field by means of the pump 24 the colder water of the lower layers is pushed through.

If in this case not ammonia or carbonic acid, but water is used, in order to achieve steam formation at the temperature of the heat source, the air is pumped out of the hollow bodies and out of the turbine to create the necessary negative pressure to create.

3. The air. If you use air for the engine, you can work in two ways, namely with single and double heating of the air, can be used: a) with simple heating, the whole process goes as described above, in front of you, similar to the process with water vapor; only the container = i in this one Trap connected to the compressor and the hollow bodies are removed from the air by air Container refilled when the air pressure drops below the norm before heating.

b) with double heating, the first heating takes place as described above, through the surface of the superheater in front of you; the second heating is internal by injecting fuel into the interior of the hollow body.

With double heating, the front part of the device remains (Fig. 4) under the line o-o without change; the rear part, on the other hand, is built as shown in Fig. 5, and the operation is as follows itself: the air comes from the compressor into the hollow body through the container = i, through the tube 13 and through the valve 14 before the hollow body enters the hot field enter.

In the hot field, the air is up to the temperature of spontaneous combustion of the fuel is heated. When the hollow bodies come to the point at which When the connection is closed, fuel from the container is fed into the hollow body 16 through the tube 27 by means of a small pump 18 and a valve at the entrance introduced into the inner space of the hollow body.

The movement of the small pump is regulated by the turbine regulator. The used air with the combustion gases is through the opening = g, which is located in the casing of the turbine, discharged. Then this hollow body goes into cold field and comes into contact with the container = i with the help of the tube 13 and of the slide 12 (Fig. 4).

The incoming air first blows through the hollow bodies; during the During the blow-through, the hollow bodies connect with the air reservoir 2o Help the tube 21. and the slide 22.

After blowing through, the hollow body separates from the container 2o and the connection with the container = i for filling the hollow body is established again with fresh air; then the separation from the container = i takes place again, the hollow body enters the hot field and the process is repeated.

The casing of the turbine must be of some kind in such a mode of operation Have cooler.

Claims (7)

PATENT CLAIMS: i. Process for operating a heat engine, especially turbine that alternates between heated and cooled, non-liquefied Steam or gas works; characterized in that superheated steam or a Gas is only extracted as much heat by releasing energy in the heat engine, that the means of work, by virtue of its living force, is complete or as one essential part in a direct without the interposition of a compressor behind the machine, closed, relatively cool receiving container flows in without liquefaction, whereupon it is after the container has been switched off and heated in this the machine is fed back. 2. Heat engine for carrying out the method according to claim i, which optionally consists of a turbine combined with a steam generator, characterized in that the heat engine consists of a ring (6) designed as a rotary valve with preferably radially connected, alternately heated and cooled steam or gas containers ( A, B) , the spaces of which alternate in pairs when the ring rotates via a power generator, for example a turbine (D). 3. Heat engine according to claim 2, characterized in that two radially opposite one another Containers (A, B) form a pair of containers, of which one in each case during rotation heated, the other is cooled. . 4. Heat engine according to claim 2 or 3, characterized in that one or more .kreisbogeniform, the machine surrounding heating rooms (17) and cooling rooms are provided, which hold the containers (A, B) alternate through their uranium rotation. 5. Wä.rmekraftmaschine according to claim 2 to 4, characterized in that in the wall of the turbine (3) opposite connection parts (g) of the container (A, B) and the ring (6) nozzles (15) are arranged such that the connection between two containers (A, B) is established at the boundary between the heating and cooling rooms. 6. Heat engine according to claim 2 to 5, characterized in that the feed openings of the nozzles (15) and the rotary valve ring (6) and the peripheral speed of the ring (6) are dimensioned such that the Connection of a pair of vessels is interrupted as soon as there is an approximate pressure equalization is achieved between the two containers. 7. Heat engine according to claim 2 to 6, characterized in that the rotary valve ring (6) can be driven by the turbine arranged within the ring by means of a gear (8, = o). B. Heat engine according to claim 4, characterized in that the cooling space is connected to the heating space (i7) by a duct (25) through which the cooling air is fed as combustion air to the heating space (i7) when operating with combustion gases. G. Heat engine according to Claims 2 to 8, characterized in that a refilling device (ii) which is under the lowest permissible pressure for the working substance at the end of the passage of the containers (A, B) through the cooling space, preferably through pressure relief valves (i4) to the container (A , B) can be connected. ok Heat engine according to Claims 2 to g, characterized in that, when air is used as the working substance, devices (i6, 17) for injecting fuel for the purpose of combustion with the air contained in the containers (A, B), discharge lines (ig) for discharging the used Air and devices (2o, '2i) for blowing fresh air into the container (A, B) are provided.