DE102007062085A1 - Method and device for generating electricity from heat - Google Patents

Abstract

The invention relates to a method and a device for generating electricity from heat, in particular in Rankine cycles and ORC process, in which low-temperature heat is used for power generation, in order to achieve that a heat use in power generation process in the Low temperature is further optimized, the invention proposes that directly in the return line of the evaporator medium, an additional heat exchanger (Z-WT) is provided, in which low-temperature external heat is fed from outside the evaporator-condenser circuit and preheats the medium returning to the evaporator thus.

Description

The The invention relates to a method and a device for generating electricity out of heat, especially in Rankine cycle and ORC process, in which low-temperature heat for power generation is used, according to the preamble of the claims 1 and 6.

In known Rankine cycle processes such as the ORC process (Organic Rankine Cycle) a medium is evaporated in an evaporator stage. This steam is fed to a turbine, which is operated with it. A mechanical one Coupling with a generator generates from this kinetic energy then electricity. Behind the turbine, the steam has thus again relaxed and is fed to a condenser, from where returned from the medium via a pump again becomes.

In the generation of electricity from heat evaporators are in use in power plants, in which the same is fed to a residual heat exchanger before the entry of the relaxed, still residual heat-carrying medium in the condenser. This residual heat serves to preheat the returning medium to the evaporator. This method is called recuperation. Such a method is from the EP 0275 121 A3 known.

there However, only the residual heat of the relaxed medium used behind the turbine. Such recuperation is in the Application to a low temperature process like ORC not efficient.

Of the Invention is therefore based on the object, a method and a device of the generic type to the effect to further develop that heat use in power generation processes is further optimized at low temperature.

The asked task is in a method of the generic Type according to the invention by the characterizing Characteristics of claim 1 solved.

Further advantageous embodiments are in the dependent claims 2-5 indicated.

Regarding a device is the task according to the invention by solved the characterizing features of claim 6.

Further advantageous embodiments are dependent on the others Claims specified.

core The invention is that directly in the return line the evaporator medium an additional heat exchanger (Z-WT) provided is in which low-temperature external heat from outside the Evaporator-condenser circuit is fed and that to Evaporator returning medium thus preheats. There is a significant difference to the above-described Recuperation. In the invention, external heat is in the Preheating included. When recuperation is native heat right behind the relaxation and in front of entrance in the condenser fed back to the feed line to the evaporator. In the present invention, however, is external heat, the outside the closed evaporator-condenser media circulation is generated via a heat exchanger (additional heat exchanger) as "extraneous heat" with introduced to the preheating of the medium before entering the evaporator. this leads to to a further significant increase in the efficiency of application for example, cogeneration.

In Another advantageous embodiment is specified that at a Cogeneration of the evaporator of the ORC evaporator condenser circuit directly from the engine cooling of an internal combustion engine is fed with thermal energy, and the low-temperature external heat to Supply of additional heat exchanger from a charge air cooler the internal combustion engine by means of a liquid or gaseous Cooling medium is fed. With the waste heat of Engine cooling is fed to the input side of the evaporator d. H. at the higher available temperature.

On the other hand the waste heat of other aggregates (at lower Temperature) such as intercooler, compressor, etc is the Additional heat exchanger for preheating the in Evaporator recycled medium from the closed Evaporator-condenser circuit supplied. Ie. the Preheating of the said medium in the closed evaporator-condenser circuit does not take place in contrast to the prior art described above by recuperation of own heat from the closed Evaporator-condenser circuit itself, but in addition supplied extraneous heat (external heat is Heat not coming from the closed evaporator-condenser circuit itself comes) from the additional units such as intercooler compressor etc.

In a further advantageous embodiment, it is stated that the inlet temperature to the additional heat exchanger is in a range between 55 ° C and 75 ° C. Thus, this additional heat energy is at a state size ie at a temperature lower than the temperature at the heat exchange at the entrance of the evaporator. Thus, this heat is suitable for preheating tion, for which, because it is additionally used external heat, the total heat utilization of the system is significantly increased.

This Incidentally, in the known in the art and recuperation described above, because in the known Recuperation only in the system of the closed evaporator-condenser circuit own heat is used for preheating.

at the invention, however, is MORE heat (external heat) introduced and increases the efficiency of the entire system thus clearly, because the heat energy at lower temperature, the provide the additional units of the engine, in known methods not used. Just because this lower temperature is not enough to evaporate the medium in the evaporator or the desired To achieve working pressure, it is unused in known methods cooled away. In the invention, but this serves the said Preheating, which further increases the efficiency.

In Another advantageous embodiment is therefore indicated that at a cogeneration, the low-temperature external heat from a compressor of a piston power or combustion engine with a liquid or gaseous cooling medium removed and fed to the additional heat exchanger (Z-WT) becomes.

Regarding In one device, the essence of the invention is that in the return line from external heat fed outside the evaporator-condenser circuit Additional heat exchanger for preheating the medium arranged is.

Advantageous it is designed in such a way that with a cogeneration of heat and power the thermal energy for the operation of the evaporator can be removed and the low-temperature external heat from a charge air cooler a piston power or internal combustion engine with a cooling medium removable and via a thermally insulated line with the additional heat exchanger (Z-WT) is connected.

Farther advantageous is configured that a temperature sensor is provided on an external heat supplying unit, which with a valve device of the supply of external heat corresponds to the additional heat exchanger temperature controlled. This allows the process to be controlled to the optimum operating point.

Advantageous is also designed that the external heat source of the intercooler an internal combustion engine is.

As well advantageous is the placement of the additional heat exchanger Z-WT in the return line between the return pump and inlet to the evaporator is arranged. This is a local close Preheating.

In Another advantageous embodiment is specified that the heat source for the evaporator is the main waste heat of a biogas plant, and the heat source for the additional heat exchanger the residual heat from the fermenter or dryer is by means of a cooling medium the additional heat exchanger can be fed.

The The invention is illustrated in the drawing and closer explained.

It shows:

1 : Embodiment of the invention with additional heat exchanger

2 : State of the art

1 shows a first embodiment of the invention. Shown is an ORC cycle, in which in this example the direct waste heat from the engine radiator of an internal combustion engine via a heat exchanger 10 an evaporator 1 is supplied. The feed temperature of a coming from the engine main radiator coolant in the heat exchanger 10 is about 75 ° C to 105 ° C. This evaporator 1 contains a medium which evaporates at a low temperature (lower than 100 ° C). This vaporized medium generates a vapor pressure with which a turbine 3 is driven. The turbine 3 is with a generator 4 coupled, which now generates electrical energy from the converted via the turbine kinetic energy. After relaxation of the medium in the turbine 3 this becomes a capacitor 2 fed, in which a heat exchanger 20 the medium cools down. Via a return pump 5 the medium is returned to the evaporator 1 recycled.

The Incidentally, medium is also volatile, so that it is in a closed evaporator-condenser cycle flows.

According to the invention, an additional heat exchanger Z-WT will now be in the recirculation path of the condenser 2 coming cooled medium arranged. In this case, according to the invention now heat not taken from the closed evaporator-condenser circuit itself, but external heat, ie by definition "not directly from the closed evaporator-condenser cycle coming heat" fed into the system.

This can in this embodiment, the waste heat from the intercooler 8th and / or be compressor of the above-mentioned, not further shown here combustion engine. This waste heat is still at a lower temperature than the heat of the engine main cooling, with which the heat exchanger 10 operated in the evaporator, namely at about 55 ° C to 75 ° C. This heat is doing with a separate coolant from the intercooler 8th and / or supplied from the compressor to the additional heat exchanger Z-WT.

This heat supply can be via a temperature sensor 6 on the intercooler 8th , ie be arranged in the same of the cooling circuit.

The temperature sensor 6 then regulates via a valve and / or a pump 7 the supply of charge air coolant to the additional heat exchanger Z-WT.

The thereby existing heat energy, or the temperature level it is lower, but it is suitable the preheating of the recirculated medium in the evaporator. This will add extra to the combustion engine otherwise unused waste heat with fed in and the efficiency the entire heat-electricity generation is further increased.

there the device shown can also be used in biogas plants, in which of additional in the fermentation or drying process accumulating heat at a temperature lower than that Evaporation temperature of the medium is present, in which then a Use of the same can be brought about.

2 shows the state of the art again to illustrate the differences. In the prior art, the so-called recuperation, the native energy, for example, after relaxation of the medium in the turbine 3 supplied to a recuperation heat exchanger R-WT to thereby preheat the returning medium. As mentioned above, however, system-specific heat is diverted, which must first be supplied to the system as a whole.

In the present invention according to 1 In contrast, additional heat energy from outside the closed evaporator-condenser circuit, that is supplied as extraneous heat. This is at low temperature and is therefore used for preheating.

This is in the present invention over the state The technology is a real external energy that is used.

1

Evaporator

2

capacitor

3

turbine

4

generator

5

Recirculation pump

6

temperature sensor

7

Valve and / or pump

8th

Intercooler

Z-WT

Additional heat exchanger

R-WT

Rekuperationswärmetauscher

10

heat exchangers in the evaporator

11

heat exchangers in the condenser

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - EP 0275121 A3 [0003]

Claims (10)

Process for the production of electricity from heat, in particular in Rankine cycles and ORC process, in which by means of an evaporator medium low-temperature heat is used for power generation, characterized in that directly in the return line of the evaporator medium, an additional heat exchanger (Z-WT) is provided in which low-temperature External heat is fed from outside the evaporator-condenser circuit and thus preheats the return to the evaporator medium. Method according to claim 1, characterized in that that in a cogeneration of the evaporator of the ORC evaporator condenser circuit directly from the engine cooling an internal combustion engine is supplied with thermal energy, and the low-temperature external heat for feeding the additional heat exchanger from a charge air cooler of the internal combustion engine by means of a liquid or gaseous cooling medium is fed. Method according to one of the preceding claims, characterized in that the inlet temperature to the additional heat exchanger in a range between 55 ° C and 75 ° C. Method according to one of the preceding claims, characterized in that at a combined heat and power the low-temperature external heat from a compressor of a Piston power or combustion engine with a liquid or gaseous cooling medium removed and the Additional heat exchanger (Z-WT) is supplied. Device for generating electricity from heat, in particular in Rankine cycle and ORC processes, with an evaporator, a turbine with a generator, a condenser and a return line medium with return pump, characterized that in the return line of a foreign heat fed outside the evaporator-condenser circuit Additional heat exchanger (Z-WT) for preheating the Medium is arranged. Device according to claim 5, characterized in that in a cogeneration the thermal energy for operation of the evaporator ( 1 ) and the low-temperature external heat from a charge air cooler ( 8th ) of a piston power or internal combustion engine with a cooling medium and is connected via a thermally insulated line with the additional heat exchanger (Z-WT). Device according to claim 5 or 6, characterized in that a temperature sensor ( 6 ) on an external heat supplying aggregate ( 8th ) is provided, which with a valve device and / or a pump ( 7 ) with the supply of external heat to the additional heat exchanger (Z-WT) temperature-controlled corresponds. Device according to one of claims 5 to 7, characterized in that the external heat source of the intercooler ( 8th ) is an internal combustion engine. Device according to claim 5 to 8, characterized in that the additional heat exchanger (Z-WT) in the return line between the return pump ( 5 ) and entrance to the evaporator ( 1 ) is arranged. Device according to claim 5 or 7, characterized in that the heat source for the evaporator ( 1 ) is the main waste heat of a biogas plant, and the heat source for the additional heat exchanger (Z-WT) is the residual heat from the fermenter or dryer, which is supplied by means of a cooling medium to the additional heat exchanger.