DE202009002710U1 - Plant for solar thermal power generation - Google Patents

Abstract

Plant for solar thermal power generation
Characterized in that there is a liquefied gas in a pressure vessel (LPG tank). The pressure vessel (LPG tank) is connected to a pump by means of a piping system. This pump in turn is connected by means of a piping system to the inlet side of the primary circuit of a heat exchanger (evaporator). The heat exchanger (evaporator) is in turn connected to its outlet on the primary side by means of a piping system to a turbine. The turbine is driven by the vaporized gas and transfers the power by means of a shaft to a generator, which is also mounted on the shaft of the generator from. The generator generates electrical energy and delivers it to the power grid. This is done with AC directly or by transformer. For DC generators by means of an inverter between generator and power grid. The turbine, which can expand the gas is connected by piping to an expansion tank (pressure vessel). The expansion tank is connected by piping to the inlet side of the primary circuit of a heat exchanger (condenser). The condenser ...

Description

The The invention relates to the assembly structure of a decentralized solar thermal Power generation plant with R245fa. The problem that still exists today lies in the fact that a generation of solar thermal energy only with great financial and technical effort in large plants was to be realized. Examples are in particular the parabolic mirror systems, where a thermo-oil through bundled Sunbeams to high operating temperatures of more than 400 ° C is heated. With this available Thermal energy is usually driven by a steam turbine.

This Procedure is very expensive on the one hand and high on the other hand Space required. The operation of such power plants can also only profitable in warm regions. Already operated plants in Germany or even more northerly Regions usually run with low returns or even deficits.

Here Our development comes to bear, already with low temperatures of 65 ° C electricity can generate. According to the invention, two different types of Vacuum tube collectors. These are inventively designed that allows a flat support becomes. Every single tube itself is according to the latitude from the angle to the horizon and thus sun aligned. The 1st version of the invention used Collectors has 20 vacuum tubes with a construction length of about 2.80 m and a diameter of about 7 cm. This collector is inventively mainly in the northern one Regions used. The 2nd version of the invention used Collectors consist of 6 vacuum tubes with a length of about 3.00 m and a diameter of about 12 cm. This collector is inventively mainly in warmer Regions south used.

The Collectors according to the invention with a Water-glycol mixture flows through. The inventive arrangement the collectors is grouped in a cluster. This cluster according to the invention consists of 12 × 6 or 6 × 6 or 12 × 7 or 6 × 7 or 10 × 6 or 24 × 6 or 3 × 6 in Row of connected collectors. The connection of the collectors takes place according to the invention over the so-called Tichelmann principle.

The absorbed thermal energy is transmitted through a piping system to a cascade storage battery according to the invention by means of heat exchanger dissipated. The cascade storage battery is so controlled, so also at low temperatures already the incoming thermal energy can be stored in the water storage.

The inventive acquisition The thermal energy to the so-called ORC cycle via heat exchangers in which the liquid Gas R245fa is vaporized. According to the invention this is heated and in the Pressure increased to the invention used Small turbine handed over. The thermal energy that is not completely consumed during expansion is medium by means of an economizer according to the invention the still liquid R245fa gas delivered. With the aid of a cooling system according to the invention The R245fa gas is completely liquefied again and the circuit medium liquid receiver fed again. The powered small turbine drives via a corresponding gear a generator and feeds this electrical energy generated in the power grid or builds according to the invention in island operation own Power on.

Claims (69)

Plant for solar thermal power generation Characterized in that in a pressure vessel (liquefied gas tank) is a liquefied gas. The pressure vessel (LPG tank) is connected to a pump by means of a piping system. This pump in turn is connected by means of a piping system to the inlet side of the primary circuit of a heat exchanger (evaporator). The heat exchanger (evaporator) is in turn connected to its outlet on the primary side by means of a piping system to a turbine. The turbine is driven by the vaporized gas and transfers the power by means of a shaft to a generator, which is also mounted on the shaft of the generator from. The generator generates electrical energy and delivers it to the power grid. This is done with AC directly or by transformer. For DC generators by means of an inverter between generator and power grid. The turbine, which can expand the gas is connected by piping to an expansion tank (pressure vessel). The expansion tank is connected by piping to the inlet side of the primary circuit of a heat exchanger (condenser). The condenser cools the gas on the primary side by means of a cooling circuit connected on the secondary side and liquefies it again. The primary side is connected on the outlet side by means of piping system to the liquefied gas container, where the liquefied gas is taken up again. The secondary side of the condenser is connected at its outlet side by means of a piping system to a cooling system, or cooling water storage. After cooling, the cooling system returns the circulating medium in the cooling circuit to the inlet side of the condenser secondary side by means of a piping system. On the secondary side of the evaporator is Spei connected by piping system. This is also the buffer memory for the connected solar thermal system. The solar thermal system consists of vacuum tube collectors which are flowed through by a solar pump with a heat transfer medium. The solar energy thus absorbed in the collectors and transferred to the heat transfer medium is delivered to the buffer memory. The connection of the individual collectors, as well as the collector assembly to the solar pump and to the buffer tank by means of piping system. Plant for solar thermal power generation according to the aforementioned Claims. Thereby characterized in that the gas used is R254fa. Plant for solar thermal power generation according to the aforementioned Claims. Thereby characterized in that the gas used is CO2. Plant for solar thermal power generation according to the aforementioned Claims. Thereby characterized in that the gas used is ammonia (NH3). Plant for solar thermal power generation according to the aforementioned Claims. Thereby characterized in that the gas used is R236fa. Plant for solar thermal power generation according to the aforementioned Claims. Thereby characterized in that the gas used is propane. Plant for solar thermal power generation according to the aforementioned Claims. Thereby characterized in that the gas used is nitrogen. Plant for solar thermal power generation according to the aforementioned Claims. Thereby characterized in that the collectors used with over 20 vacuum tubes a length of about 2.10 m and a diameter of about 7 cm. Plant for solar thermal power generation according to the aforementioned Claims. Thereby characterized in that the collectors used consist of 6 vacuum tubes a construction length of about 2.80 m and a diameter of about 12 cm. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the collectors with a water-glycol mixture flows through become. Plant for solar thermal power generation according to aforementioned claims. Thereby in that the inventive arrangement of the collectors are clustered together. This cluster consists of 12 Rows a '6 collectors. The connection is made by Tichelmann principle. Plant for solar thermal power generation according to aforementioned claims. Thereby in that the inventive arrangement of the collectors are clustered together. This cluster consists of 12 Rows of a '7 collectors. The connection is made by Tichelmann principle. Plant for solar thermal power generation according to aforementioned claims. Thereby in that the inventive arrangement of the collectors are clustered together. This cluster consists of 10 Rows a '6 collectors. The connection is made by Tichelmann principle. Plant for solar thermal power generation according to aforementioned claims. Thereby in that the inventive arrangement of the collectors are clustered together. This cluster consists of 14 Rows a '6 collectors. The connection is made by Tichelmann principle. Plant for solar thermal power generation according to aforementioned claims. Thereby in that the inventive arrangement of the collectors are clustered together. This cluster consists of 3 Rows a '6 collectors. The connection is made by Tichelmann principle. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the plant to external heat sources such as process heat, waste heat, recooling systems and geothermal plants is connected Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the plant is connected to power generation plants for power generation when generating energy by combustion (CHP) is connected. Plant for solar thermal power generation according to the aforementioned claims. Characterized in that the absorbed thermal energy via a piping system a cascade storage battery is discharged by means of a heat exchanger. The cascade storage battery is controlled so that even at low temperatures already the incoming thermal energy can be stored in the water tank. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that it is one or more memory with the connection principle according to Tichelmann acts. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that water is used as a storage medium. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that brine (salt / water) used as a storage medium becomes. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that fat is used as a storage medium. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that PCM is used as a storage medium. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that silicon is used as a storage medium. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that pressure-free accumulators are used. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that pressure accumulators are used. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that an ECONOMIZER (heat exchanger) for increasing the Energy yield and associated increase in plant efficiency between turbine and condenser is installed. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that a liquefied gas storage after EC type examination (Module B) 97/23 / EC. Before the turbine is installed. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the heat transfer to the ORC circuit and storage by means built in memory Internal heat exchanger he follows. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the heat transfer to the ORC circuit and storage by externally installed heat exchanger he follows. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the piping systems used are made of copper consist. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the piping systems used are made of brass consist. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the piping systems used are made of carbon steel consist. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the piping systems used are made of V2A consist. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the piping systems used are made of V4A consist. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the piping systems used are made of V4A consist. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the piping systems used according to EN378 is made. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the piping systems by means of press connectors (Press system) is connected. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the piping systems by means of screw connections is connected. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the piping systems by means of solder joints is connected. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the piping systems by means of welded joints is connected. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the piping systems by means of Börtelverbindungen is connected. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the cooling system used according to EN387 and in consideration the EC type examination (Module B) 97/23 / EG is manufactured. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the cooling system a water cooler is. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the cooling system a water-air cooler is. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the cooling system a liquefier is. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the cooling system an absorption cooler is. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the cooling by means of combined heat and power works and the heat on heating systems. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that designed according to EN378 overpressure systems in the ORC cycle. Plant for solar thermal power generation according to aforementioned claims. Thereby in that prescribed by pressure vessel regulation Safety systems are available at the water tanks. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that a synchronous generator operated in island mode becomes. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that an asynchronous generator operated in network operation becomes. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that a DC generator operated in island mode becomes. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that a DC generator operated in network operation becomes. Plant for solar thermal power generation according to aforementioned claims. Thereby in that a transmission with appropriate over- and Reduction between turbine and generator is installed. in this connection is in particular the speed of min 1450 -1 min and 2900 -1 min, which corresponds to a mains frequency of 50 Hz. Of the Island operation is inventively with a Synchronous generator realized according to the requirement also must reach appropriate speeds to build a standalone power grid. At required 50 Hz, this also corresponds to speeds of min 1450 -1 min and 2900 -1 minute Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that a rotary piston turbine is used. The Frame sizes vary between 0.5 KW and 50 KW. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that a screw turbine is used. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that a turbo turbine is used. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that an eccentric turbine is used. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that an axial turbine is used. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that a radial turbine is used. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that a recirculating turbine is used. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that a spiral turbine is used. Plant for solar thermal power generation according to aforementioned claims. Thereby in that a Hubkolbenturbine, or a reciprocating engine is used. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that instead of the medium water directly to be evaporated Direct gas through the collectors or another heat exchanger to direct There to produce an evaporation and exclude possible heat exchanger losses. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that between solar or other energy supplier a compressor for the gas is interposed. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the memory once as a choke or damping for the system act. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that the memories function as a long-term storage system, to over the energy feed into the system to produce electric power and thus a 24 h supply can be guaranteed. Plant for solar thermal power generation according to aforementioned claims. Thereby characterized in that no expansion tank is installed.