AT511637B1 - TECHNICAL SYSTEM FOR GAS COMPRESSION USING TEMPERATURE AND PRINTING DIFFERENCES - Google Patents

Abstract

In a method for operating a technical system, gas is compressed on the basis of temperature and pressure differences in high-pressure heat exchangers (A) via a pneumatic cylinder (13) and compressor (15), the gas being used to drive a turbine (17). The gas which is passed from the high-pressure gas space (1) of a first high-pressure heat exchanger (A) via the pneumatic cylinder (13) in a second high-pressure heat exchanger (A) is due to exchange of heat and cold in the high-pressure heat exchangers (A) by changing pressure increase and Pressure drop of the gas over the pneumatic cylinder (13) out. By exchanging heat and cold for each individual heat exchanger (A), the use of a gas pump is obsolete.

Description

Austrian Patent Office AT511 637B1 2013-08-15

Description: The invention relates to a technical system with which gas based on temperature and pressure differences in high pressure heat exchangers via a pneumatic cylinder and compressor gas is compressible, wherein the gas is used to drive a turbine. Furthermore, the invention relates to a method for operating such a system.

From US 5,259,363 A and AT 410 966 B a plant for solar production is known. Therein a device for compressing a gas by means of solar energy and / or ambient heat is described, wherein a first heat exchanger at a high temperature level and a second heat exchanger at a low temperature level and therebetween a turbine for delivering mechanical energy is provided. The disadvantage here is that after the pressure equalization of the gas must be recycled by a pump that consumes additional energy.

From US 2005/0198960 A1 (D2), a generic system is known in which each high-pressure heat exchanger is connected in each case only with a chamber of the pneumatic cylinder. From the first high-pressure heat exchanger, a pipe leads into the first chamber of the pneumatic cylinder. From the second high-pressure heat exchanger, a line leads into the second chamber of the pneumatic cylinder. Gas is heated in the first high-pressure heat exchanger, increasing the gas pressure. In the second high pressure heat exchanger, gas is cooled causing the gas pressure to drop. A valve in the conduit extending from the first high-pressure heat exchanger is opened, whereby gas at elevated pressure flows from the first high-pressure heat exchanger into the first chamber of the pneumatic cylinder and moves the piston in one direction. At the same time, a valve in the line issuing from the second high-pressure heat exchanger is opened, whereby lower-pressure gas flows from the second high-pressure heat exchanger into the second chamber of the pneumatic cylinder and moves the piston in the same direction. After maximum stroke of the piston, these two valves are closed. Subsequently, the second high-pressure heat exchanger is heated and the first high-pressure heat exchanger is cooled. The valves are reopened, which now flows gas at elevated pressure from the second high pressure heat exchanger into the second chamber of the pneumatic cylinder and lower pressure gas from the first chamber of the pneumatic cylinder into the first high pressure heat exchanger. The piston of the pneumatic cylinder is thereby moved in the other direction.

The invention is based on the object to provide a technical system available that can be operated as energy efficient as possible to save a pump.

This object is achieved according to the invention with a technical system, which has the features of claim 1.

Furthermore, this object is achieved by a method which has the features of claim 5.

Preferred and advantageous embodiments of the invention are the subject of the dependent claims.

According to the invention it is provided that each high-pressure heat exchanger is connected via one line in such a way with two chambers that of each high-pressure heat exchanger with increased pressure for a piston stroke is performed in a chamber and gas at a lower pressure in the return stroke of the piston of the another chamber is returned to the corresponding high pressure heat exchanger.

The invention aims that the gas which is passed from the first high-pressure heat exchanger via the pneumatic cylinder in the second high-pressure heat exchanger, not described in Patent AT 410 966 B after pressure equalization by a pump - which consumes additional energy - are recycled must, but is replaced by exchange of heat and cold at each individual high-pressure heat exchanger by changing pressure increase and pressure drop of the gas through the compressor. Furthermore, by means of built-in registers in the high-pressure heat exchanger (tertiary circuit), in which hot water or cold water circulates, the gas in the high-pressure gas space (primary circuit) is heated or cooled. In addition, this effect is achieved by supplying hot gas or cold gas through the double jacket of the high pressure heat exchanger in a secondary circuit. By this arrangement, the primary circuit in the closed system can be controlled easily.

Further details, features and advantages of the invention will become apparent from the following description with reference to the accompanying drawing, in which a preferred embodiment is shown.

Fig. 1 shows a schematic representation of the system.

The system consists of at least two high-pressure heat exchangers A, in which the primary side equal pressure prevails in the initial state. In a first heat exchanger A gas is heated, for example by solar energy, geothermal, industrial heat and the like, resulting in a pressure increase up to 250 bar in this heat exchanger A. In a second heat exchanger A, gas is e.g. due to lower ambient temperature, cooling water, industrial cooling, wind influence, etc., cooled, causing a pressure drop in this heat exchanger.

The high-pressure heat exchanger A are equipped with register 3 and double jacket 2. The registers 3 are fed by the energy storage, namely the hot water tank 5 and the water storage tank 6, with hot water and cold water via pipes (tertiary circulation). The high-pressure gas chamber 1 (primary circuit) in the high-pressure heat exchanger A is either heated or cooled by mutual opening and closing of valves 7, 8 via the registers 3, resulting in the required pressure increase or pressure drop of the gas.

The gas under elevated pressure from the heated high-pressure heat exchanger A is passed through a pneumatic cylinder 13 to the cooled high-pressure heat exchanger A. This connection is controlled by opening and closing valves 4 until the pressure equalization takes place. By the gas pressure in the pneumatic cylinder 13, a piston 14 is moved, which allows a further piston in a compressor 15 through the suction port 16 to suck and compress gas. The pressurized gas in the compressor 15 is directed to a turbine 17 which generates mechanical energy and used to drive it. After the exit of the gas from the turbine 17, the gas relaxes and cools off sharply. This cooled gas is in a memory 11, from there into the double jacket 2 of a corresponding high-pressure heat exchanger A, in which the cooling of the gas in the primary circuit is required for pressure drop, and finally passed through a valve 18 to the outside (secondary circuit).

Through a second line from the compressor 15 compressed gas enters a memory 9 and leads there to strong warming. This heated gas is passed into the double jacket 2 of a corresponding high-pressure heat exchanger A, in which heat in the primary circuit is required to increase the pressure (secondary circuit).

After the pressure equalization has taken place in a heat exchanger pair is switched by opening and closing of valves 4 to another heat exchanger pair, whereby the cycle begins again.

In summary, an embodiment of the invention can be represented as follows: The system contains at least two high-pressure heat exchanger A, in which in the initial state the same pressure prevails on the primary side. In the first heat exchanger A, the gas pressure is increased by secondary and tertiary side supply of heat to 250 bar. In the second heat exchanger A, the gas pressure is reduced by secondary and tertiary side cooling. Through the exchange of heat and cold at each heat exchanger A, the use of a gas pump is obsolete. The pressure difference in the two high-pressure heat exchanger causes a displacement of the piston 14 in the pneumatic cylinder, which compresses gas in a compressor 15. The resulting compression heat is conducted into a memory 9 and from there on the secondary side into the double jacket 2 of the high-pressure vessel 1 and via vent valves 18 to the outside. The compressed gas from the compressor 15 is used to drive a turbine 17 and relaxed after leaving the turbine. The strongly cooled by the relaxation gas is passed into the memory 11 and the secondary double shrouds 2 of the high-pressure vessel and vent valves 18 to the outside. 3.6

Claims (10)

Austrian Patent Office AT511 637 B1 2013-08-15 Claims 1. Technical plant with which gas is compressible on the basis of temperature and pressure differences in high-pressure heat exchangers (A) via a pneumatic cylinder (13) and compressor (15), the gas being used to drive a turbine (17) is used, wherein the gas flowing from the high-pressure gas space (1) of a first high-pressure heat exchanger (A) via the pneumatic cylinder (13) in a second high-pressure heat exchanger (A), due to exchange of heat and cold in the high-pressure heat exchangers ( A) by changing pressure rise and pressure drop of the gas via the pneumatic cylinder (13) is guided, and wherein the pneumatic cylinder (13) has two chambers separated by a piston, characterized in that each high-pressure heat exchanger (A) via one line connected to both chambers is. 2. Plant according to claim 1, characterized in that the gas in the high-pressure gas chambers (1) is guided in a closed primary circuit and that hot or cold gas through a double jacket (2) of the high-pressure heat exchanger (A) is guided in a secondary circuit. 3. Plant according to claim 2, characterized in that the gas in the primary circuit in the high-pressure heat exchanger (A) by the double jacket (2) of the high-pressure heat exchanger (A) in the secondary circuit can be heated or cooled. 4. The technical system according to claim 2 or 3, characterized in that hot and cold water in the high-pressure heat exchangers (A) arranged registers (3) and energy storage is performed in a tertiary cycle and that the gas in the primary circuit in the high-pressure heat exchanger (A) by a Register (3) in the tertiary cycle can be heated or cooled. 5. A method for operating a technical system, with the gas based on temperature and pressure differences in high-pressure heat exchangers (A) via a pneumatic cylinder (13) and compressor (15) gas is compressed, wherein the gas used to drive a turbine (17) wherein the gas passed from the high-pressure gas space (1) of a first high-pressure heat exchanger (A) via the pneumatic cylinder (13) to a second high-pressure heat exchanger (A) is replaced by heat and cold in the high-pressure heat exchangers (A). is guided by changing pressure rise and pressure drop of the gas via the pneumatic cylinder (13), and wherein the pneumatic cylinder (13) has two chambers separated by a piston, characterized in that each high pressure heat exchanger (A) is connected via one line in such a way with two chambers in that, of each high-pressure heat exchanger (A), gas at elevated pressure for one piston stroke is led into the one chamber and gas never at the return stroke of the piston from the other chamber into the corresponding high-pressure heat exchanger (A) is returned. 6. The method according to claim 5, characterized in that the gas in the high pressure gas spaces (1) is guided in a closed primary circuit and that hot or cold gas via a double jacket (2) of the high pressure heat exchanger (A) is guided in a secondary circuit. 7. The method according to claim 6, characterized in that the gas is heated or cooled in the primary circuit in the high-pressure heat exchanger (A) through the double jacket (2) of the high-pressure heat exchanger (A) in the secondary circuit. 8. The method according to claim 6 or 7, characterized in that hot and cold water through in the high-pressure heat exchangers (A) arranged registers (3) and energy storage is performed in a tertiary cycle and that the gas in the primary circuit in the high-pressure heat exchanger (A) by a register (3) is heated or cooled in the tertiary cycle. 4/6 Austrian Patent Office AT511 637 B1 2013-08-15 9. The method according to any one of claims 5 to 8, characterized in that the guiding of the gas between the two high-pressure heat exchangers (A) by opening and closing of valves (4) is regulated until a pressure equalization takes place. 10. The method according to claim 9, characterized in that by opening and closing the valves (4) is switched to a further heat exchanger pair after the pressure equalization has taken place in a previous high-pressure heat exchanger pair. For this 1 sheet drawings 5/6