DE102005045333A1 - Thermal power arrangement used in power station technology comprises a heat pump with a Carnot process running to the left in combination with the Clausius-Rankine process to replace a heat source and a cooling system - Google Patents

Abstract

Thermal power arrangement comprises a heat pump with a Carnot process running to the left in combination with the Clausius-Rankine process to replace a heat source and a cooling system. Preferred Features: The arrangement has a liquid collector formed as a liquid column for equalizing the suction vacuum of the pump. A further cooling process receives the heat of condensation from the waste steam from a turbine.

Description

The technical field to which the invention belongs is the or power plant technology.

The prior art (Figure 1), as is known, uses primarily thermal power plants for the production of electrical energy, and those which convert fuels such as coal, oil and gas into electrical energy ,

in this connection takes the Clausius-Rankine cycle for water vapor by means of a Evaporator heat energy from a fossil-fired steam generator (B in Figure 1) on which he a turbine with generator for generating electrical energy supplies (C). The steam-condensate mixture exiting the turbine is in a cooling system liquefied (D), where the heat of condensation is delivered to the environment. The remaining in the cycle Water is brought from a pump (A) to the evaporator pressure and starts the next one here the repetitive cycles.

The problem underlying the invention is on the one hand in the environmental impact of smoke, ash, CO ₂ , SO ₂ NO, cooling water consumption, waste heat, as well as in the sharply rising fuel prices and the world's increasing energy demand with decreasing resource stock. Power plants of renewable energy sources are limited in terms of location and climate.

The present invention of a cycle thermal power plant consists of a pair of one incomplete each left and right-handed Circular process with the composition of the prior art State points, in the order 1-2-3-4-A-B-C-D-1.

The Numbers stand for counter-clockwise, the letters, for distinction, for right-hand (Fig. 2).

The Sections 4-1, evaporator and D-A, condenser, each too a complete one Belonging to the cycle process, omitted. The present used in power plant technology right-handed Clausius-Rankine cycle is waiving the route D-A with a left-turn heat pump cycle, under Elimination of the route 4-1, in the points 4-A and D-1 by means of liquid collector and liquid separators connected. The working medium, water or water vapor, passes through the eight state points in the order of priority given above. in this connection flows through steam the condenser 2-3, relax in the adiabatic 3-4 by means of a turbine as a relaxation machine in the liquid collector 4, from the the pump A for the right-handed Part the water sucks and brings to the evaporator pressure, the evaporated in B-C and the heat of 2-3 absorbs in C-D by means of turbine in the liquid separator 1 up to 100 ° C / 1.01 bar relaxes and thus reaches the starting point where the compressor 1 at 100 ° C / 1.01 bar steam for sucks the next cycle.

The circuit used in this invention (Figures 2 and 3) the use of a considerably more elaborate heat pump set in cascade connection between the capacitor D-A, which we refer to in this Circuit process have omitted and the evaporator B-C to absorb the condensation heat and to compress to the evaporator temperature, with all associated components such as heat exchangers and the like

With Another cycle 1'-2'-3'-4'-A'-B'-C'-D'-1 'is by the recovery also the condensation heat from the exhaust steam of the turbine 3-4 and their transfer to A-B, the self-sufficient Operation of the thermal power plant guaranteed (Picture 2 and 4).

The thermal power plant in the present invention consists mainly of plant parts, which are in the electrical system technology and process gas industry belong to the state of the art, but currently do not occur in the proposed arrangement for power generation. The know-how of the design, manufacture The installation, installation, commissioning and operation of the system components used here, as well as the respective operating and safety instructions of the manufacturer, are also valid in this order.

The arrangement of the plant parts in the present invention is, as for the Clausius-Rankine (C.R.) cycle, also for the Organic Rankine cycle (ORC.), the Kalina process and other circular processes suitable for this application.

For the selection of components and for the production of the power plant, high standards are recommended, which are geared to functional reliability, long machine running times, low maintenance in the largest possible distances and a high efficiency in terms of current efficiency. Regarding the rules of careful design of heat pumps in general, in terms of lower than in refrigerators usual flow resistance, more abundant than in refrigerators usual sized heat exchanger surfaces and their arrangement in a the LORENZ process Approximated circuit that these rules that characterize the heat pump literature, especially in the execution of a heat pump used in a power plant, attention, insofar as they have no desire to generate electricity, counteracting effect and have a high coefficient of performance and a higher yielding if possible Produce electricity.

The performance of a unit as described above is determined by the capacity of the compressors. The largest currently known to the author of this description, water vapor-compatible and volume flow adjustable process gas screw compressor, manufactured by Aerzener Maschinenfabrik GmbH D-31556 Aerzen, has a maximum flow rate of 120 000 m ³ / h. In conjunction with a Rankine cycle process part as used herein, generation of usable electrical energy, as calculated on pages 4 and 5, is possible at about the level of compressor power consumption. Power plants can be assembled from several thermal power plants of the type presented.

The cycle thermal power plant is started with starter. Starting a ready-to-use thermal power plant can be done as follows:
In the case of an existing grid connection, in which the generated power is to be fed, the starting can be done with power from the grid.

These It is island operation, a starter is required. The starting process in screw compressors takes due to the thermal inertia of the System mass longer as in internal combustion engines that ignite spontaneously. Of the Starter will be longer accordingly claimed. For larger thermal power plants are therefore sizes with Graded performance selected. The smallest plant may e.g. both with electric motor and with e.g. a gas engine are equipped as a starter, the gas engine is disengaged after a successful start. The smallest, first running Plant starts the next plant, this again the next and so on to the largest facility. This assumes that the plant sizes correspond to the required Grading be interpreted. Since the compressors up to approx. 40% of the Nominal power are adjustable down, they are with their smallest Power started and then started up to the next plant to start. This order is generally recommended for the Construction of larger power plants.

There the demand for power fluctuates during the course of the day, the week and the year and plant performance over large margins sometimes must be regulated at short notice, should also be a rule or appreciated Needed reserve capacity for spontaneous Insert available be.

The following calculation sheets and allow drawings an insight into the structure of the cycle with 8 state points. The centerpiece the module is the big one Compressor Unit 1. It is the largest of thirteen sizes of these Type in the manufacturer program.

One another compressor 2, which uses ammonia as a working medium here, is smaller.

The Heat pumps 1 and 2 are atypical for relaxation on the adiabatic 3-4 and 3'-4 ', which we the Siedelinie follow, each a turbine with generator (Figure 2). arithmetical The internal energy on this route is enough to absorb the liquid to evaporate. In practice, this solution is avoided, with the justification of low adiabatic performance, which does not pay the effort.

in the industrial scale however, it is worthwhile. We oversize the evaporator by spreading it and / or the cross-section continue to enlarge.

• ⁶) Brockhaus Enzyklopedie in 24 Bd., 19.Aufl. Bd. 4 1987, S.600
• ⁷) Taschenbuch f. Heizung + Klimatechnik 2000, Recknagel, Sprenger, Schramek, R. Oldenbourg Verlag München Wien 69.Auflage 1999, S.778.

By processing and using its own waste heat, this thermal power plant provides an internal cooling and heat coupling (internal cogeneration) Advantages and applications of the cycle thermal power plant with internal cogeneration: Advantages over the prior art applications Emission-free operation Arrangement in the center of the supply Vibration-free run of the machines area, also in housing estates Low noise operation Drive for rail vehicles Low space requirement Drive for ships Low machine wear On islands Base load capability relocated farms No waste Mountain hotels No fuel storage required craft No fuel costs Industry No high voltage electrosmog isolated operation No cooling system required Every village No flue gas cleaning effort Every city, several times No chimney required estates No overland network costs Delivery to the net Long machine running time military location independence Polar regions improvement service areas Widely spaced maintenance intervals sports facilities Further development potential All over

• ⁶ ) Brockhaus Encyclopedia in 24 Bd., 19th ed. Vol. 4, 1987, p. 600
• ⁷ ) Paperback f. Heating + air-conditioning technology 2000, Recknagel, Sprenger, Schramek, R. Oldenbourg publishing house Munich Vienna 69.Auflage 1999, S.778.

calculations

1. Heat pump H ₂ O cycle process, without evaporator

• ¹ ) Formula from HANDBUCH DER KÄLTETECHNIK Bd.VI / A, Rudolf Plank, Springer Verl. 1969, S.482.

2. Clausius Rankine H ₂ O cycle process without capacitor

• ⁶ ) Formula from Brockhaus encyclopedia in 24 Bd., 19th edition Bd. 4 1987, p. 600.
• ⁷ ) Formula from Taschenb.f.Heizg. + Klimatechn.2000, Recknagel u. Sprenger, p.

3. Heat pump 2 -NH ₃ - cycle without evaporator

• ¹ ) Formula from HANDBUCH DER KÄLTETECHNIK Bd.VI / A, Rudolf Plank, Springer Verl. 1969, S.482.

4. Kalina NH ₃ cycle process without capacitor

• ³ ) Formula from Brockhaus Encyclopedia in 24 Bd., 19th edition Bd. 4 1987, p. 600.

Claims (19)

Heat power plant for generating electrical energy by converting heat energy from a heat source, with transfer of the heat of condensation to a cooling system, using the Rankine process, characterized in that the heat source and the cooling system by a heat pump with left-handed Carnot process in combination with be replaced by the clockwise Clausius-Rankine process, which cause a simultaneous appearance of the cold and heat effect by mechanical compression of the water vapor and its relaxation in the cycle itself and consequently an internal cooling-heat coupling (internal cogeneration) represent Thermal power plant according to claim 1, characterized in that the combination of Carnot process with the Clausius Rankine process by waiving on the evaporator 4-1 of the former and on the capacitor D-A of the second process and the merger of both process bodies in the points 4-A and D-1 is produced, with the result of Circulatory composition in the form 1-2-3-4-A-B-C-D-1, wherein the pay for counter-clockwise and the letters for clockwise stand, Thermal power plant according to claim 1 and 2, characterized in that the connecting piece of the process hulls in 4-A a liquid collector and in D-1, a liquid separator is Thermal power plant according to claim 3, characterized in that the liquid collector 4-A represents a column of liquid, which compensates for the intake negative pressure of the pump, Thermal power plant according to claim 1 to 4, characterized in that the use of the cycle 1-2-3-4-ABCD-1 cooling is avoidable and otherwise technically the same is done as with heat pump + Clausius-Rankine cycle together, with fewer components and higher yield of usable electrical energy, Thermal power plant according to claim 1 to 5, characterized in that a further Circular process 1'-2'-3'-4'-A'-B'-C'-D'-1 'the heat of condensation absorbs the exhaust steam of the turbine 3-4 and releases it to A-B, Thermal power plant according to claim 1 to 6, characterized in that the relaxation by means of turbines on the adiabatic 3-4 in a liquid collector and on C-D in a liquid separator he follows, Thermal power plant according to claim 1 to 7, characterized in that the eigesetzten Compressors are screw compressors, Thermal power plant according to claim 1 to 8, characterized in that the compressor with delivery rate control are equipped Thermal power plant according to claim 1 to 9, characterized in that the present Invention also with other circling processes such as the Organic Rankine cycle (ORC.) And the Kalina process instead of the Clausius-Rankine process can be, Thermal power plant according to claim 1 to 10, characterized in that for the start prepared thermal power plant is started by a starter, Thermal power plant according to claim 1 to 11, characterized in that the starter power higher as the power consumption of the thermal power plant in its lowest gear, Thermal power plant according to claim 1 to 12, characterized in that in a power plant with several thermal power plants the starting process starts at the smallest plant and from this gradually the successively larger systems are started, which presupposes that the systems have been designed accordingly and that the smallest plant itself from a generator, hybrid drive or started in a different way, Thermal power plant according to claim 1 to 13, characterized in that if they are for the feed their production into public Network is determined, can be started from this network, Thermal power plant according to claim 1 to 14, characterized in that they are after Start continues and over their own needs beyond an excess power, the after current assessment Own needs to over Exceeds 90%, what in the calculation example 6 MW, Thermal power plant according to claim 1 to 15, characterized in that the energy, which drives and cures them, from the condensation heat, the heat equivalent the compressor capacity and from the remaining in the Carnot process, unused residual energy exists and that a larger power with larger or can be reached by several machines, Thermal power plant according to claim 1 to 16, characterized in that except for water, Sewage and for the supply of generated electrical energy usually no additional media connections required are, with water except in the sanitary facility also to compensate for the losses of circulating and machine cooling water needed becomes, Thermal power plant according to claim 1 to 17, characterized in that no fuel storage required is. Thermal power plant according to claim 1 to 18, characterized in that transmitted by the use of screw compressors, their following characteristics directly on the thermal power plant and made her own: a. that the main engines used, the screw compressors, work frictionless and wear-free by design, except bearing replacement, after more than 50 years of operation no machine parts had to be worn or exchanged, ie have a remarkably long running time, b. that they have maintenance intervals that are far apart c. that they work vibration-free, d. that they work emission-free e. that they can also be used as relaxation machines, f. that they have a small footprint, g. that instead of a large aggregate several small can be used.