WO2012084922A1 - Method and device for utilizing waste heat of a heat engine - Google Patents

Abstract

The invention relates to a method for utilizing waste heat (A) of a heat engine (12), in which a working fluid (B) is heated by means of the waste heat (A) of the heat engine and evaporated and subsequently supplied to an expansion engine (16). According to the invention operation-optimal pressure and temperature values (p_opt, T_opt) of the working fluid (B) that is supplied to the expansion engine (16) are determined in each case for different operating states of the heat engine (12) and stored, and during operation of the heat engine (12) the respective operating state of the heat engine (12) is determined, and then the pressure (p) and temperature (T) of the working fluid (B) supplied to the expansion machine (16) are regulated to those optimal pressure and temperature values (p_opt, T_opt) which are stored for the respective determined operating state.

Description

 description

title

 Method and device for using waste heat of a heat engine

The invention is based on a method for utilizing waste heat of a heat engine according to the preamble of claim 1 and of a device suitable for carrying out this method according to the preamble of claim 6.

From DE 10 2005 061 214 A1 a method is known in which the

Optimization of the output of the expansion machine in a Clausius-Rankine cycle process used for the heating and evaporation of the working fluid waste heat flow and one of the expansion machine supplied

Working fluid flow are regulated. In this scheme, however, only partial aspects of the cycle are optimized, so that the expansion machine is not operated at the optimum operating point.

The object of the invention is in contrast to develop a generic method and a generic device to the effect that in all different operating conditions of the heat engine the

Expansion machine can be operated with the optimum efficiency.

Advantages of the invention

This object is achieved by a method having the features of claim 1 and a device having the features of claim 6. According to the invention, therefore, a concrete operating strategy for using the waste heat of a heat engine is specified, the one

optimized performance operation of the expansion engine allows.

Overall, the overall efficiency and the utilized heat flow of the working fluid can be optimally adjusted. This allows the

 Expansion machine at different operating states (load cases) of the heat engine, as they occur for example in an internal combustion engine of a motor vehicle, are operated with improved or optimum efficiency. The optimum pressure and temperature values which depend on the respective operating state can be stored as a characteristic map or characteristic maps. The respective operating state of the heat engine can in operation based on characteristic operating parameters of the heat engine, such as

Exhaust gas temperature, exhaust gas mass flow, speed and / or torque can be determined in a simple manner.

The temperature of the working fluid as a controlled variable is preferably by

Adjusting the flow rate of the pumping the working fluid to the heat pump. The pressure of the expander machine supplied working fluid is preferably by an adjustment of the

Expansion engine regulated. This can be done by a speed control in reciprocating engines or by adjusting the distributor in steam turbines.

Further advantages and advantageous embodiments of the subject invention are the description, the drawings and claims removed.

drawings

The method according to the invention and the associated apparatus will be explained in more detail below with reference to an exemplary embodiment which is shown in highly schematic form in the drawing. Show it: Fig. 1 is a block diagram of the device according to the invention for

 Performing the method according to the invention for utilizing waste heat of a heat engine; and

2 shows an operating characteristic of the device according to the invention for a selected operating state of the heat engine.

Description of the embodiment

In Fig. 1 is a highly schematic block diagram of a device 10 for the use of waste heat of e.g. designed as an internal combustion engine

Heat engine 12 shown.

The working according to the so-called Clausius-Rankine cycle

Apparatus 10 includes a heat exchanger 14 in which the waste heat A of the heat engine 12 is transferred to a working fluid B, which is thereby heated and vaporized. The vaporized working fluid B becomes one

Expander 16 supplied by which the energy contained in the evaporated working fluid B is at least partially converted into mechanical work. The expansion machine 16 is followed by a condenser 18, in which the led out of the expansion machine 16 relaxed working fluid B is condensed. The liquid working fluid B is then raised by a pump 20 back to the pressure level required for evaporation and fed again to the heat exchanger 14, so that the working fluid B is guided in total in a closed circuit.

The device 10 has to control the vapor pressure p and the

Steam temperature T of the expansion machine 16 supplied vaporous working fluid B, a control device 22 which a pilot control 24, a data memory 26 and a controller 28 for the vapor pressure and a controller 30 for the steam temperature of the expansion machine 16 supplied

Working fluid B has.

As primary input variables of the precontrol 24 serve characteristic operating parameters 32 of the heat engine 12, such as Exhaust gas mass flow, exhaust gas temperature, torque and / or speed. The feedforward control 24 determines based on the characteristic

Operating parameters 32, the respective operating state of the heat engine 12 and assigns this operating state with respect to the power of the

Expansion engine 16 operating optimum steam pressure and

 Steam temperature values p_opt, T_opt for the working fluid B to. This assignment takes place on the basis of data stored in the data memory 26 for a multiplicity of operating states (load cases) typically encountered in practice

Heat engine 12 stored maps of the cycle. When determining the optimum vapor pressure value p_opt of the working fluid B, the pilot control 24 can also take account of a condenser pressure 34 of the working fluid B which prevails in the condenser 18 because, together with the vapor pressure, the usable pressure ratio and

achieves attainable steam cycle efficiency. The thus determined optimal steam pressure and steam temperature values p_opt, T_opt are determined by the

Pilot control 24 as setpoints 36, 38 to the respective controller 28, 30th

output.

The vapor pressure regulator 28 comprises a pressure sensor 40 for pressure detection of the expansion machine 16 supplied vaporous working fluid B and regulates via an adjusting device of the expansion machine 16, preferably on the speed, the vapor pressure of the working fluid B to the optimal operation

Vapor pressure value p_opt. The steam temperature controller 30 includes a

Temperature sensor 42 for temperature detection of the expansion machine 12 supplied working fluid B and regulates the flow rate of the pump 20, the temperature of the working fluid B to the optimum steam temperature T_opt.

The control device 22 with feedforward control 24 and regulators 28, 30 makes it possible to react quickly to changing operating states of the heat engine 12, without having to realize high loop gains that tend to instability. As a result, a high control quality and a stable system behavior are achieved overall. In Fig. 2, the efficiency (Eta) 50 of the cyclic process, in the

Circuit transmitted heat 52 (indicated as heat flow Q) and the resultant of these sizes useful power 54 of the expansion machine 16 in response to the vapor pressure p (process pressure) of the

Expander 16 supplied working fluid B by way of example for a specific operating state (load case) of the heat engine 12 shown.

While with increasing pressure p of the working fluid B, the efficiency 50 of the cycle increases, the transferred or transferred into the cycle process or.

transferable heat 52. From the opposite behavior of these two variables results for the operating state of the heat engine 12 shown in Fig. 2, a Nutzleistungsmaximum 56 at an optimum vapor pressure p_opt of the working fluid B of about 18 bar. This optimum vapor pressure p_opt is output by the precontrol 24 as a setpoint value 36 to the vapor pressure regulator 28. For the operating state of the heat engine 12 shown in Fig. 2 is in

 Data memory 26 stored in a corresponding manner, the optimum temperature T_opt of the expansion machine 12 supplied working fluid B of about 320 ° in the map, which of the pilot control 24 as a target size 38 to the

Steam temperature controller 30 is output.

For each operating state or point of the heat engine 12, there is thus an optimum set of steam parameters (p_opt, T_opt), with which the highest efficiency of the expansion machine 16 can be achieved. The respective parameter sets can be determined by an optimization calculation in which the steam cycle efficiency and the heat transferred into the steam circuit are jointly optimized. Alternatively, the parameter sets (p_opt, T_opt) can also be determined during an application measurement of the device 10 and stored in each case as a characteristic field in the data memory 26. Overall, the overall efficiency and the utilized heat flow of the working fluid B can be optimally adjusted

Claims

claims

1 . Method for utilizing waste heat (A) of a heat engine (12), wherein a working fluid (B) is heated and evaporated by means of the waste heat (A) of the heat engine (12) and subsequently fed to an expansion engine (16),

 characterized,

 in each case optimum operating pressure and temperature values (p_opt, T_opt) of the working fluid (B) supplied to the expansion engine (16) are determined and stored for different operating states of the heat engine (12) and that during operation of the heat engine (12) the respective operating state of the heat engine ( 12) is determined and then pressure (p) and temperature (T) of the expander (16) supplied working fluid (B) to those operating optimum pressure and temperature values (p_opt, T_opt) are regulated, which are stored for each particular operating condition.

2. The method according to claim 1, characterized in that the respective operating state of the heat engine (12) on the basis of

 Operating parameters of the heat engine (12) is determined.

3. The method according to claim 1 or 2, characterized in that when determining the operating optimum pressure value (p_opt) a condenser pressure (34) of the working fluid (B), the output side of the

 Expansionsmaschine (16) downstream capacitor (18) prevails is taken into account.

4. The method according to any one of the preceding claims, characterized

characterized in that the temperature (T) of the working fluid (B) over the Flow of a working fluid (B) promotional pump (20) is controlled to the optimum operating temperature value (T_opt).

5. The method according to any one of the preceding claims, characterized

 in that the pressure (p) of the working fluid (B) is regulated to the operating-optimum pressure value (p_opt) via the rotational speed of the expansion machine (16).

6. The method according to any one of the preceding claims, characterized

 characterized in that the pressure (p) of the working fluid (B) through a

 Adjustment of the flow conditions within the expansion machine (16) to the operating optimum pressure value (p_opt) is regulated.

7. The method according to any one of the preceding claims, characterized

 in that the optimum operating pressure and temperature values (p_opt, T_opt) are set via a combination of feedforward control and regulation.

8. Device (10) for utilizing waste heat of a heat engine (12),

 with a heat engine (12),

 with a heat exchanger (14) for heating and evaporating a working fluid (B) by means of the waste heat (A) of the heat engine (12), with an expansion machine (16) for converting the thermal energy contained in the vaporized working fluid (B) into mechanical work, and with a control device (22) for controlling process parameters for the working fluid (B),

 characterized,

that the control device (22) is assigned a data memory (26) in which operating-optimum pressure and temperature values (p_opt, T_opt) of the working fluid (B) fed to the expansion engine (16) are stored for different operating states of the heat engine (12), and in that the control device (22) is programmed such that pressure (p) and temperature (T) of the expansion machine (16) supplied operating fluid (B) to those operating optimum pressure and temperature values (p_opt, T_opt) are regulated, which are stored in the data memory (26) to the respective operating state. Arrangement according to claim 8, characterized in that the

 Control device (22) by a combination of a pilot control (24) and a controller (28, 30) is formed.