DE2904232A1 - Thermal power station - combines cooling and working process to lower upper temp. level thus making it independent of outside coolant source - Google Patents

Abstract

The operation of a thermal power station is made independent of an outside coolant source which ensures working in regions with scarce water, and at the same time improves the overall efficiency. This is achieved by combining the work process with a cooling process which derives the energy from the former. The exhaust steam of a urbine (12) is fed to a condenser (14) while the condensate is returned to a boiler (10) by a pump (16). The turbine drives the compressor (18) handling the evaporated coolant while a heat exchanger (20) is included in the circulation loop of the working medium. The coolant and liquefied medium passes a throttle (24) before returning to the condenser (14) where it evaporates due to the steam condensation.

Description

Process and system to improve efficiency

of power plants The invention relates to a method for improvement the efficiency of power plants in which a work process between a upper and a lower temperature level takes place, with an under energy supply working fluid heated to the upper temperature level, which is under power mechanical Work is relaxed and cooled down to the second temperature level.

Usually, power plants work with water and steam as working media. They contain a steam generator, one acted upon by the steam from the steam generator Prime mover, a condenser in which the exiting from the prime mover Steam is condensed by heat exchange with a coolant, and a condensate pump, which feeds the condensate back to the steam generator.

In conventional power plants, for example, as a coolant for the condenser Related to river water. This river water is heated by the condensation of the steam, and the heated river water is returned to the river.

The temperature of the coolant in the condenser is significant Influence on the efficiency of the power plant. In other power plants this is done Condensation of the steam by means of a cooling tower, whereby the heat is released into the air will.

The temperatures of river water or air are relative in hot zones high, which affects the efficiency of power plants in these areas.

When using cooling water from rivers or lakes, Restrictions on the location of the power plant. Through the introduction of the heated cooling water back into the rivers or lakes, these become undesirable Heated up to or above the biologically permissible limit. That can in particular occur when several power plants are built on a river. Through this out undesirable warming of rivers or lakes or the same for ecological reasons unwanted climate change through cooling towers also goes a large part, namely around a third of the heat supplied to the power plant by the fuel is lost.

The invention is based on the object of designing a power plant in such a way that that it becomes independent or largely independent of external coolants, whereby it is much more environmentally friendly, furthermore the operation in arid and hot areas Enabling areas and increasing the efficiency of the power plant.

The method according to the invention is characterized in that simultaneously a cold process is carried out with the work process, in which (a) the power to operate the refrigeration process is provided by the work process, (b) the cooling capacity of the cooling process to lower the second temperature level is withdrawn from the relaxed working medium and (c) the heat output of the cooling process is supplied as part of said energy supply to the working fluid to be heated.

According to the invention, the work equipment circuit (normally Water or steam) a refrigerant circuit in the opposite direction coupled. In a normal power plant, this happens in such a way that the evaporator of the refrigerant circuit in the form of a heat exchanger at the same time the condenser of the working medium cycle. The condenser of the refrigerant circuit is also designed as a heat exchanger and heats the feed water of the steam generator. No external coolants are required. Because the temperature of the refrigerant can be reduced very significantly in the condenser regardless of the outside temperature, a favorable efficiency of the engine results. Another improvement the efficiency is achieved in that the refrigeration circuit acts as a heat pump and the waste heat otherwise lost with the cooling water to preheat the Feed water can be used.

Plants for carrying out the process according to the invention and others Refinements of the invention are the subject of the subclaims.

The invention is shown below in a few exemplary embodiments Explained in more detail with reference to the accompanying drawings: Fig. 1 shows a diagram of a power plant designed according to the invention.

Fig. 2 shows a modification of the power plant with a multi-stage Refrigerant circulation.

Fig. 3 shows a further modification.

Fig. 4 shows an embodiment in which the refrigerant circuit works according to the absorber principle.

A steam generator, for example a boiler, is designated by 10 Fuel an amount of heat B is supplied. The steam generator gives steam to a Power machine 12 in the form of a turbine. The one emerging from the prime mover 12 Steam enters a condenser 14, where it is exchanged by heat with a coolant is condensed. The condensate is returned to the steam generator by a condensate pump 16 10 supplied. That would be the normal working fluid cycle.

According to the invention is a refrigerant circuit for carrying out a Cold process provided. This contains a drive connection with the engine 12 standing compressor 18 for an evaporated refrigerant. In the work equipment cycle a heat exchanger 20 is arranged between the condensate pump 16 and the steam generator 10. The compressed and heated refrigerant flows through this heat exchanger, as indicated by the coil 22. The compressed and heated refrigerant is thereby cooled and thus liquefied. Through this cooling process the condenser fed to the steam generator 10 is in turn preheated.

The cooled and liquefied refrigerant is released via expansion agents, which are formed in Fig. 1 by a throttle 24, throttled with further cooling relaxed and as a coolant dem Capacitor 14 supplied as is indicated by the coil 26. In the condenser 14, the refrigerant evaporates with condensation of the steam in the working medium circuit and the compressor 18 supplied. A generator 28 is connected to the engine 12 and the compressor 18 coupled. This supplies the electrical output power of the power plant.

In the embodiment of FIG. 2, corresponding parts with the the same reference numerals as in FIG. 1.

In the embodiment according to FIG. 2, in addition to the first heat exchanger 20, a second heat exchanger 30 as a preheater between condensate pump 16 and (not shown) steam generator. With the power machine In addition to the first compressor 18, a second compressor 32 is coupled. Both compressors 18 and 32 draw in the refrigerant evaporated in the condenser 14 in parallel and compress it it. The refrigerant compressed and heated by the first compressor 18 is in a first refrigerant circuit which corresponds to the refrigerant circuit of FIG. 1, to the first heat exchanger 20 and via expansion means 24 to the condenser 14 switched. The refrigerant compressed and heated by the second compressor 32 is switched to the second heat exchanger 30 in a second refrigerant circuit, as indicated by the coil 34, and via relaxation means in the form a throttle 36 on the first refrigerant circuit upstream of the first heat exchanger 20 given.

As shown in Fig. 3, instead of the throttle 24 or 36, respectively an expansion motor 38 may be provided, which simultaneously with the condensate pump 16 is coupled and its drive motor 40 supports.

It is also possible not to use all of the condensation heat in the condenser 14 via the refrigerant circuit but also a cooling e.g. to be provided by river water.

On the other hand, the refrigerant circuit can be used to not only dissipate heat from the condenser 14 but also the flue gas at the same time to cool and to recover the amount of heat given off by the flue gas.

In the embodiment according to FIG. 4, the working medium circuit is like this formed in Fig. 1. Corresponding parts are provided with the same reference numerals like there.

The refrigerant circuit contains an expeller 42 in heat exchange with the working medium branched off from the working medium flow upstream of the turbine 12 and heated (Vapor) to drive the refrigerant out of a solution. The heated work equipment is routed via line 44, coil 46, and line 46, for example.

There is still a condenser in the refrigerant circuit, of the expelled and heated refrigerant via pipe coil 22 and of the first heat exchanger 20 (similar to FIG Heat exchanger 20 is provided in Fig. 1, which again preheats the to be heated Working medium, i.e. the condensate, through the refrigerant with cooling and liquefaction the latter causes. The refrigerant is then released via an expansion agent 24 with further cooling, throttled relaxed. The so relaxed refrigerant arrives in a second heat exchanger acting as an evaporator, that of the condenser 14 of the working medium circuit is formed in heat exchange with that by the turbine 12 relaxed work equipment. With evaporation of the refrigerant, the Heat withdrawn from working media. The refrigerant circuit also contains one with the pipe coil 26 of the condenser 14 connected absorber 44, which The solvent is supplied from the expeller 42 via a throttle 46 after expulsion will. This causes the evaporated refrigerant to dissolve again in the solvent. The solution so obtained is then recycled by suitable means such as a pump 48 promoted to expeller 42.

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Claims (8)

Method for improving the efficiency of Power plants in which a work process is between an upper and a lower Temperature level takes place, with a supply of energy to the upper temperature level heated work equipment, which relaxes while performing mechanical work and is cooled to the second temperature level, characterized in that at the same time a cold process is carried out with the work process, in which (a) the performance to operate the refrigeration process is supplied by the work process, (b) the refrigeration capacity of the cooling process to lower the second temperature level of the relaxed working medium is withdrawn and (c) the heat output of the refrigeration process as part of said Energy supply is supplied to the working fluid to be heated. 2. Plant for performing the method according to claim 1, characterized characterized in that to carry out the refrigeration process according to the compressor principle working refrigerant circuit is provided, which contains the following components: (a) a compressor (18) operated by the working medium circuit for a vaporized Refrigerant, (b) one of the compressed and heated refrigerant and the to be heated working medium flowed through the first heat exchanger (20), the one Preheating of the working medium to be heated by the heated refrigerant under Causes cooling and liquefaction of the latter, (c) relaxation means (24), via which the refrigerant is relaxed with further cooling, and (d) a second heat exchanger (14) in which the refrigerant thus expanded is in heat exchange with the relaxed working medium and is under evaporation of the refrigerant heat is extracted from the working medium. 3. Power plant according to claim 2, characterized in that the compressor (18) is a mechanical compressor, which is arranged with a in the working fluid circuit Engine is in drive connection. 4. Power plant according to claim 2, characterized in that the compressor is a jet compressor that is operated with heated working fluid. 5. System according to one of claims 2 to 4, in which the working medium circuit a steam generator in a closed circuit, one of the steam from the steam generator acted upon engine, a capacitor, in which the from the engine escaping steam is condensed by heat exchange with a coolant, and contains a condensate pump, which feeds the condensate back to the steam generator, through this characterized in that the first heat exchanger in the working medium circuit between the condenser pump (16) and steam generator (10) is arranged and that the second heat exchanger of the capacitor (14) of the working medium circuit is formed. 6. Plant according to claim 5, characterized in that the relaxation means are formed by an expansion motor (38), which with the condensate pump (16) is coupled. 7. Plant according to claim 5 or 6, characterized in that the Working medium circuit two or more heat exchangers (30,30) as preheaters between the condensate pump (16) and steam generator (10) contains that with the prime mover two or more compressors (18,32) are coupled, which draw in the refrigerant evaporated in the condenser in parallel and compress that that compressed and heated by the first compressor (18) Refrigerant in a first refrigerant circuit on the first of the named heat exchangers (20) and is connected to the capacitor via expansion means (24) and that the refrigerant compressed and heated by the second compressor (32) in one second refrigerant circuit to the second of said heat exchangers (30) and Via expansion means (36) to the first refrigerant circuit upstream of the first heat exchanger (20) is switched. 8. Plant for carrying out the. The method according to claim 1, characterized characterized in that an absorber principle is used to carry out the refrigeration process working refrigerant circuit is provided, which contains the following components: (a) an expeller in heat exchange with heated working fluid for expulsion of the refrigerant from a solution, (b) one acting as a condenser, of which expelled and heated refrigerant as well as the working fluid to be heated through which the first heat exchanger flows, which preheats the working fluid to be heated caused by the refrigerant with cooling and liquefaction of the latter, (c) Relaxation means through which the refrigerant is throttled with further cooling is expanded, (d) a second heat exchanger acting as an evaporator, in which the so relaxed refrigerant in heat exchange with the relaxed working medium and heat is extracted from the working medium with evaporation of the refrigerant, (e) an absorber connected to the evaporator, to which the solvent is supplied after expelling the refrigerant, so that the evaporated Refrigerant redissolves in the solvent, and (f) means for conveying the so obtained solution to the expeller.