WO2013185783A1 - Energy transformation system - Google Patents

Abstract

It was therefore the problem to modify, and combine, already-known technical methods such that the previously unutilized energy forms available independently at the location of a consumer and locally can be selectively gathered, converted, produced and utilized, with the aim of lowering the energy demand from central networks and relieving the networks of load at peak times, realizing the greatest possible utilization of all exergies arising from production processes and utilizing the reconversion thereof into electricity with considerably greater efficiency, minimizing exergy losses and thus attaining a considerable saving of production costs, and protecting the environment. The method for the decentralized and individual gathering, generation, conversion and continuous provision of electrical energy is characterized by a decentralized adiabatic energy transformation system by means of which mechanical energy from the liquefaction and decomposition of air, motion energy from kinetic and thermal energy sources, and electrical energy from external electricity and, independently thereof, from process waste heat from separate plants, from mechanical energy, from regenerative thermal energies, and from energy from wind turbines and solar plants, can be stored separately according to demand and in individually required amounts at the location of a consumer, in that, by means of the decentralized adiabatic energy transformation system, process heat and process refrigeration, environmental heat, heat of compression, heat of decompression and fuel heat from regenerative sources can be reconverted into electricity or converted directly into mechanical energy and motion energy, and in that the processes of energy storage, energy conversion and reconversion into electricity are combined such that the basic method steps of electricity generation, storage and reconversion into electricity can be carried out in accordance with the respectively present energy resources and the energy requirements of a local consumer in the form of a refrigeration-operated, heat-operated or electrically operated system, and in that the refrigeration-operated, heat-operated and electrically operated systems operate individually or in combination and permanently in a steady state and, when required, can be adjusted immediately to required on-demand power by means of a load management system.

Description

 Energy transformation system

A method for the decentralized and individual reception, generation, conversion and continuous provision of electrical energy that is to be used by consumers of electricity from the centralized networks in all sectors of industry, in particular large-scale customers.

At present, electric power is generated by various techniques, such as nuclear power plants, thermal power plants, regenerative energy sources by chemical, thermal and mechanical conversion of natural energy resources such as wind, solar, biogas conversion, and liquefaction of air and its conversion to oxygen Nitrogen and other gases. Regenerative energies can only be produced and stored sporati- cally because they depend on the natural conditions of wind and heat from solar radiation and on the storage capacities of the central grids.

The existing power generation, conversion and reconversion plants either have too little or no storage. This has the consequence that the energy generated must be conducted mainly directly into the central power line networks. Since the nuclear power plants continuously supply the networks with large amounts of electrical energy that can not be continuously decreased in equal amounts by the consumers and the networks also have only a limited storage capacity, alternative energy producers must be temporarily shut down because their energy storage also limited and the central Networks are overloaded during rush hours. The large amounts of energy that are taken from the mains by large consumers of energy are only required at peak times, so that the energy requirement drops rapidly in the weak usage times. For this purpose one needs so-called shadow power plants, which, which must compensate for fluctuations in power resulting from discontinuous power take-off.

CONFIRMATION COPY In addition, in almost all industrial production processes by using electricity from the central networks, large amounts of energy absorbed through the process-related generation of heat and cold unused returned to the environment, resulting in high energy losses.

All previously used solutions, such as expansion of the networks, construction of new networks above or below ground, pumped storage power plants, wind turbines, etc. are costly and sometimes severely deface nature.

Even in processes that convert alternative energy and sell it as a finished product, process-related heat and cold is returned unused to the environment. For example, in air liquefaction systems, as described in DE 3307181

C2 and EP 0989375 are known in which liquid air is separated into pure liquid oxygen, nitrogen and possibly noble gases. The liquid oxygen and nitrogen are removed from the plant in cold liquid state at -196 ° C and sold. With the removal of the products, the exergy content in the form of cooling energy is taken.

At the same time purified gaseous treated air is passed with a pressure of 1.2 bar and with a heat temperature of 20 ° C from the process circuit as waste back into the atmosphere. If only individual gaseous products, such as nitrogen, are produced in these plants, the entire oxygen content is also lost in their removal

Atmosphere returned. The tanks in such plants are pure product stores and the products are used exclusively outside the plants. When removing the products from the tanks, the energies already mentioned, such as cold, heat and gases, which are generated by their manufacturing process, are lost unused. These

Air liquefaction plants are technologically costly, since the products they produce with special transporters to the user need to be transported, and low energy efficiency, due to the resulting energy losses in product production.

In EP 0250390 an air separation process is disclosed in which oxygen and nitrogen and possibly natural gases are discharged separately via product gas lines, characterized in that at least one branch gas line is connected to a product gas line, which is passed through a heat exchanger that at least two memory for two different liquefied gases are provided. Again, this is pure product memory. When these products are removed from the storage tanks, the exergy produced during production is returned to the environment unused. DE 2434238 provides a method for storing and recovering energy in which a gaseous auxiliary energy carrier is liquefied and stored almost without pressure in times of low energy demand, while compressed in times of greater energy demand of the gaseous auxiliary energy carrier, warmed and work is relaxed. This storage method is based only on the storage of individual products. From DE 19632019 C1, the ORC process (Organic Rankine

Cycle process). This is a thermodynamic cycle for the use of waste heat, in which, instead of water, other, low-boiling, organic substances, such as silicone oils, hydrocarbons and fluorocarbons, circulate as a working medium. This process can already work at temperatures above 100 ° C and pressures well below 20 bar to couple out maximum work from this process. Thus, in such systems with little technological effort and small thermal energy sources can be converted economically into electrical energy. In these ORC processes it is possible to generate electrical energy, waste heat, geothermal energy, biomass or from solar thermal sources due to the special thermodynamic properties and the various working media. These are the plants with specific technological features for each Use cases equipped. Thus, the ORC processes are broken down into different individual processes to regulate the resulting energies. It accounts for more than 90% of the electrical power consumption from the grid in the form of heat, which is passed into a cooling circuit and also goes unused about the water outlet temperatures. The plants generate process-related energies that are returned to the environment unused. Moreover, this method is not suitable in the known forms for reconversion.

In DE 373941 1 Cl a superconducting current storage is disclosed with a storage coil consisting of several sub-coils, these are characterized in that when charging a part or all sub-coils are connected in series and a part or all sub-coils are connected in parallel during discharging. Furthermore, separate discharge coils are provided, which are magnetically coupled to the sub-coils, wherein the number of sub-coils connected in parallel is adjustable during discharge. These plants are pure electricity storage and are only used as such.

Finally, in EP 0348465 Bl a current storage in the form of a superconducting storage coil is described, characterized in that the storage coil is constructed with a plurality of successive in the longitudinal direction of the storage coil segments, which are individually prefabricated and combined under electrical wiring to a storage coil. In the dependent claims, the shading from DE 3739411 Cl are provided and the most diverse materials for superconductors and their most diverse types of construction disclosed, with which in a simple way and optionally storage coils with smaller and larger storage capacity can be produced. All of the above methods and equipment are local, since the

Energy sources that are used by them, are only location-related to make available. The energy that is generated must be transported via appropriate networks. The in the manufacturing process Emerging exergies are mostly not used and are lost to the environment unused.

It was therefore an object of the invention to change already known technical processes and connect with each other, which can be taken independently at the location of a consumer and of the locally available and previously unused forms of energy optional, convert, manufacture and use, with the The aim is to reduce the energy demand from centralized networks and to relieve the grids in peak periods, to make the most extensive use of all the exergy from production processes and their re-conversion with significantly higher efficiency, to minimize exergy losses and thus to a considerable saving of production costs as well as the protection to reach the environment. The object is achieved with the features of claim 1, characterized in that the method is a decentralized and adiabatic energy transformation system, with the mechanical energy from the air liquefaction and decomposition, kinetic energy, from kinetic and thermal energy sources, and electric energy from external power and independent of this from process waste heat from own plants, from mechanical energy, regenerative thermal energies, as well as energy from wind and solar plants need to be stored separately and in individually required quantities at the place of consumption, that with the decentralized adabate energy transformation system process heat and cold, Regenerating ambient heat, compression, decompression, and fuel heat from regenerative sources, or converting it directly into mechanical and kinetic energy, is such that the energy storage, energy conversion, and reconversion processes are interconnected, that the basic process steps, power generation, storage and reconversion, according to the respective existing

Energy resources and the energy requirements of a local consumer, as a cold-led, heat-led or power-guided system are performed and that the cold, heat and power systems individually or in combination constantly working in a steady state and when needed immediately required

On-demand performance, via load management are to be regulated. The energy transformation system according to the invention has the advantage that it can be adapted independently of the location of the consumer to its individual energy requirements and the locally available energy resources. It can be used as a compact and specially adapted process system.

It should be emphasized that the regenerative treatment of functionally incurred accrued previously unused exergy, for example, from compressed air systems, heating systems, air conditioning, freezer, air conditioning systems, emergency oxygen devices, etc., and their conversion is ensured in electricity. All energy flows and their manifestations can be used economically. The dentral and adiabatic energy transformation system works with heat of compression during storage and with cold during reconversion and ensures steady state operation in steady state. It keeps the operating state of the system between power generation, storage and reconversion constantly in equilibrium and thus in an economically advantageous area. In addition, it is ensured that the system can be controlled immediately and, if necessary, on demand performance by load management. In the reverse power is first the environmental heat, then the process heat, then the power from the power storage, such as excess electricity from the grid and wind power and photovoltaic systems to be incorporated, from thermal power plants with night power and finally from the oxidation of biomass, hydrogen and biogas and Used fuel heat. In addition, the basic supply of the consumer and the constant operation of the system in steady state can be secured. Due to the three different storage systems, which complement each other, the system is also able to provide island supply without external power. Expansion circuits also load the kinetic energy storage systems and the electricity storage systems. The charging and discharging as well as the continuous power supply are regulated as required by the consumer via the load management. The efficiency of the reconversion in the combined or individual systems depends on the on-site energy resources and their own energy needs. The consumer is protected and external power must be removed only at low-load times from the central networks, which in turn saves costs and helps to relieve the networks. Since the Operators of the system but also is self-generators and can store overproductions, he can, if available, integrate wind and solar power in its process, continuously absorb their energy levels, use as needed or sell on the power exchange. The consumer can decide for himself when he wants to remove what amounts of energy from the network and what energies he wants to take inexpensively from cheaper resources, self-generated energy or surplus energy of his own production from their own power storage. This helps to relieve the burden on the nets by returning the exergy from production processes to the process and using it as needed by the producer. It prevents that exergy from being recycled into the environment unused and damaging it. Of particular advantage, it is also that the system in combination of all possible cold-guided, heat-guided and current-controlled procedures, constantly working in a steady state and can be controlled immediately if necessary on demand demanded.

However, it should also be emphasized the flexibility of the decentralized and adiabatic energy transformation system according to the invention, adapted to the need to use individually as a cold led system, according to the claims 2 and 3, in which in the cold-guided system liquid working fluid from the storing process for mechanical energy in to conduct the refrigeration cycle, wherein thermal energy and pressure energy is to be fed using the pressure gradient an expansion circuit and a part of the mechanical energy and the cooling energy via the cooling water circuit of a compressor to resume the storing process for mechanical energy and the heat of compression of the compressor from the waste heat of the Cooling circuit is a generator and a circulation pressure pump feed, the own power consumption is low and the reconversion by the return of gaseous working fluid, its pressure energy and cold energy takes place below the ambient temperature of an expansion circuit and the integration and retrieval of the mechanical energy from the expansion circuit, the irreversible expansion of a refrigerant evaporator during storage of the working fluid air and the precooling of the working fluid through the cooling circuit of the circulation pressure pump from a heat exchanger, the so generated energy in a partially closed loop in the work cycle of the refrigerated system ziirückgeführt is and another part of the liquefied air, which arises during reconversion, for maintaining the steady state of an Organic Rankine cycle process is available.

It is also advantageous that the system according to the invention, adapted to the needs, individually as a heat-guided system, according to the claims 4 and 5, is to be used in which to heat by additional heat energy from renewable fuels, which are to be processed in an evaporation process, the working medium air in the expansion circuit isentropically to relax in several stages and to consume the complete refrigeration capacity in the Organic Rankine Cycle - process and to direct that under pressure, cold liquefied air through several circuits of an air heat exchanger, there to heat, gas and regulated is to lead into the evaporation process. In addition, compressed liquid fuel can additionally be supplied from a fuel tank via a pressure pump, and the solid fuel is first gasified, then compressed and then passed into the evaporation process.

The efficiency of the reconversion, including the coverage of the need for compressed air and technical gases for a furnace is higher than in a refrigerated system, it has a much lower own consumption of electricity for production and process cooling and a very low overall efficiency through the use of waste heat the production. For the air conditioning of rooms, the refrigerant circuit in the consumer and the cold discharged from a heat exchanger and the cold required for the Organic Rankine Cycle process are available.

Particularly noteworthy is the current-carrying system, adapted to the need to use individually, according to claims 6 to 9, by charging the current-carrying system with external power or independently of this via at least one multi-stage expansion circuit of mechanical energy and the working fluid from air the stored in the expansion cycle mechanical energy or with the refrigerant from the Organic Rankine cycle process, to be supplied, these processes are simultaneously run in parallel or in series, and the working medium air is heated with the heat of compression from the compression circuit of a base compressor to heat the waste heat of a production process or with excess heat and stored thermal energy, the refrigerant from oxygen-poor liquid air, especially liquid nitrogen, from a nitrogen-rich zone of a pressure condenser from the air liquefaction process usable, the refrigerant is to perform work in a working process, the environmental heat and waste heat of the power storage process, from the charging and discharging process, by short-term energy pulses infinitely repeatable, thereby keeping the required transition temperature of the storage process for kinetic energy safely and that a pressure pump increases the operating pressure for a multi-stage expansion cycle, the refrigerant flows through the evaporator and thereby convert it to gaseous working fluid and partly via a Kälteverb smoker on the suction side of the base compressor and so in the working circuit of the Enegietransformations- system is leading back and the refrigerant without use of an expansion circuit directly via a control or three-way valve cold and gaseous on the suction side of the base compressor is feasible. The reconversion and power storage in the power system reach a significant degree of efficiency.

The benefits of using demand-controlled, heat-managed or power-guided systems as needed are also that the decentralized and adiabatic energy transformation system must be adapted locally to a consumer and taking into account the individual conditions as well as the existing and resulting energy resources, with unnecessary procedures from the outset can be left out if they are not required. Thus, the cold-run system is used by a consumer who has a high demand for cold save power and where the heat energy resulting from the manufacturing process is absorbed, converted and stored. The heat-driven system is used when the consumer needs a lot of heat in addition to electricity. Finally, a current-carrying system is used when the consumer needs a lot of electricity and heat and cold can be converted back into electricity as controllable by-products and stored. The advantage of the adapted process sequences continues to be that from the prior art already known processes and associated plant concepts only adapted extended and not newly developed. The inventive coupling of known processes with the new storage, conversion and

Reverse-current systems for all forms of energy through new complementary process steps, the capabilities of the known methods are extended and used more effectively, energy and Exergieverluste largely limited and significantly reduced the environmental impact.

Finally, the decentralized and adiabatic energy transformation system according to the invention makes it possible to retrieve electric energy from the individual storage processes at peak load times, to market it at a high surplus on the power exchange, and to take electricity from the central networks inexpensively in low-load periods.

The invention will be described below with reference to a block diagram. Fig.l shows a block diagram of the energy transformation system with all possible procedures.

1 shows that the decentralized and adiabatic energy transformation system according to the invention is subdivided essentially into three basic process sequences. It includes a recording procedure adapted to individual requirements and conditions for all forms of energy. With this recording method, it is capable of process waste heat, environmental heat, electricity surplus from the network of wind power and photovoltaic systems, from thermal power plants with night power, from oxidation of biomass, hydrogen and

To absorb biogases. Depending on the type, from the recording process it passes on the absorbed energy forms either directly into the three possible storage processes for mechanical energy, kinetic energy and electricity or into the conversion and reconversion processes.

From the conversion and reconversion process, the converted and recovered energy can be directed into the storage processes. Of the storage processes and of the conversion and Rückverstromungsprozessen can be returned as needed, the respective required amounts of the various generated and stored forms of energy either directly into the existing on-site manufacturing process, or in the energy transformation system to maintain its internal work processes or for purchase for other consumers or for sale at the Electricity exchange can be retrieved. The energy to be produced in this way, back to leading and to be taken away, are electricity, liquid gases and air and nitrogen produced therefrom and pure oxygen as well as heat, cold and pressurized gas.

The energy transformation system described consists of a combination of all possible systems, namely the cold-guided, the heat-guided and the current-guided system. Of course, these processes can also be used individually or combined differently depending on requirements and conditions.

It is also very important that this energy transformation system can work independently of the season, because it can compensate energy surpluses in certain seasons and energy requirements to third parties that are not available.

Claims

Patent claims

1. A method for decentralized and individual recording, generation, conversion and continuous provision of electrical energy, characterized in that the method is a decentralized adiabatic energy transformation system, with the mechanical energy from the air liquefaction and decomposition, kinetic energy, kinetic and thermal Energy sources, as well as electric power, from external power and independent of this from process waste heat from their own plants, mechanical energy, regenerative thermal energy, and energy from wind and solar plants, need to be stored separately and in individually required quantities at the place of a consumer that with the decentralized adiabatic energy transformation system, process heat and cold, environmental heat, compression, decompression and fuel heat from renewable sources to flow back or directly into mechanical energy and kinetic energy is to convert and that the energy storage tion, energy conversion and re-current processes are interconnected so that the basic process steps, power generation, storage and reconversion, according to the energy resources available and the energy requirements of a consumer on site, are performed as cold-led, heat-controlled or current-carrying system, that the refrigeration, heat and power systems operate individually or in combination constantly in a steady state and are to be regulated immediately if required on demand performance via a load management.

2. The method according to claim 1, characterized in that in the cold-guided system liquid working fluid is to be led from the storage process for mechanical energy in the refrigeration cycle, wherein thermal energy and pressure energy to be supplied using the pressure gradient an expansion circuit and a part of the mechanical energy and to absorb the cooling energy through the cooling water circuit of a compressor back into the storage process for mechanical energy and the heat of compression of the compressor from the waste heat of the cooling circuit to supply a generator and a circulation pressure pump, the own power consumption is low.

3. The method according to claim 2, characterized in that in the cold-guided system, the reconversion by the return of gaseous working fluid, of its pressure energy and cold energy below the ambient temperature of an expansion circuit and the integration and retrieval of the mechanical energy from the expansion circuit, the irreversible Expansion of a refrigerant evaporator during storage of the working fluid air and the pre-cooling of the working fluid through the cooling circuit of the circulation pressure pump from a heat exchanger, wherein the energy thus generated is due in a partially closed circuit in the working circuit of the refrigerated system and another part The liquefied air produced during reconversion can be used to maintain the steady state of an Organic Rankine Cycle process.

4. The method according to claim 1, characterized in that in the heat-controlled system by additional heat energy from renewable fuels, which are to be processed in an evaporation process, the working fluid to heat air in the expansion cycle isentropically to relax in several stages and the complete cooling capacity in Organic - Rankine cycle - process is consuming.

5. The method according to claim 4, characterized in that in the heat-guided system under pressure, cold liquefied air to pass through several circuits of an air heat exchanger, there to heat and gasify and regulated in the evaporation process is to be directed.

6. The method according to claim 1, characterized in that the current-carrying system is to be charged with external power or independent of this via at least one multi-stage expansion circuit with mechanical energy and the working with the air, from the stored in the expansion circuit mechanical energy from the Organic Rankine Cycle process, these processes are simultaneously to run in parallel or in series and the working fluid air, with the heat of compression from the compression cycle of a base compressor, with the waste heat of a production process, with excess heat, as well as with stored thermal energy, is too heated.

7. The method according to claim 6, characterized in that in the current-carrying system, the coolant from oxygen-poor liquid air, especially liquid nitrogen, from a nitrogen-rich zone of a pressure condenser from the air liquefaction process is available, the coolant is to perform a work process in a work process, the environmental heat and waste heat of the power storage process, from the charging and discharging, by means of short-term energy pulses infinitely repeatable, records to keep the required Sprungtemeperatur the kinetic energy storage process safely.

8. The method according to claim 6, characterized in that in the current-controlled system, a pressure pump increases the operating pressure for a multi-stage expansion circuit, the refrigerant flows through the evaporator, thereby converting to gaseous working fluid and partially via a refrigeration consumer to the suction side of the base compressor and so in the working cycle of the energy transformation system is to lead back.

9. The method according to claim 6, characterized in that in the current-carrying system, the refrigerant without use of the expansion circuit directly via a control or three-way valve cold and gaseous to the suction side of the base compressor and so is to lead back into the working cycle of the energy transformation system.

10. The method according to any one of the preceding claims, characterized in that at peak load times to retrieve electrical energy from the individual storage processes and market at a high excess on the power exchange and to take in low load times electricity from the central networks inexpensively and complete.