EP2411652A2

EP2411652A2 - Exhaust gas heat utilization in motor vehicles

Info

Publication number: EP2411652A2
Application number: EP10712331A
Authority: EP
Inventors: Jan GÄRTNER; Thomas Koch
Original assignee: Daimler AG
Current assignee: Mercedes Benz Group AG
Priority date: 2009-05-09
Filing date: 2010-03-24
Publication date: 2012-02-01
Also published as: WO2010130317A3; JP2012526224A; DE102009020615A1; CN102422007A; WO2010130317A2; US20120090321A1

Abstract

The invention relates to an exhaust gas heat utilization device (1) in a motor vehicle using an exhaust gas heat utilization cycle (2) in which a working temperature of a working fluid of the exhaust gas heat utilisation cycle (2) is controlled. The working temperature (T1, T2, T3) is controlled by adapting a mass flow of the working fluid flowing through the heat exchanger (5) of the exhaust gas heat utilisation cycle (2) such that a maximum permitted working temperature, in particular the decomposition temperature, of the working fluid is not exceeded.

Description

Exhaust gas heat recovery in motor vehicles

The present invention relates to a method for operating an exhaust gas heat recovery cycle in a motor vehicle, having the features of the preamble of claim 1. Furthermore, the invention relates to an exhaust heat utilization device, a motor vehicle. Furthermore, the invention relates to a fluid for use as working fluid in an exhaust heat utilization device.

DE 10 2007 057 164 A1 describes a system with an Organic Rankine circuit system for driving at least one expansion machine, a heat exchanger for driving an expansion machine and a method for operating at least one expansion machine.

In a Rankine cycle system according to US 2006 0 201 153 A1, water is vaporized as the working fluid of the Rankine cycle system, by the waste heat of the exhaust gas in an evaporator through which the exhaust gas flows. In this case, the temperature of the steam exiting the evaporator is measured and regulated by means of this steam temperature, the evaporator supplied amount of water.

Described in a Rankine circuit system according to DE 20 2007 002 602 U1, with an organic compound as the working fluid, such. As methylcyclohexane or octane or heptane, the organic working fluid is vaporized by the exhaust heat. For safety monitoring, a safety temperature limiter is arranged on the exhaust side of the evaporator after the flow through it with exhaust gas, which spends the system by means of switching signal in a safe state when a temperature threshold is exceeded. As a result, other safety equipment, such. B. account for a flow monitoring in the working fluid circuit of the Rankine circle system. A low temperature indicates a flooded and flowed evaporator. A temperature control device for an evaporator is described in EP 1 431 523 A1, wherein the evaporator can be part of a Rankine circuit system with which an exhaust heat of an internal combustion engine in a motor vehicle can be used. In this case, water is evaporated as working fluid in the heat exchanger of the Rankine circular system by the waste heat of the exhaust gas. In this case, the steam temperature is adjusted by means of the temperature control device by regulating the amount of water fed into the evaporator, based on the flow rate of the exhaust gas, the temperature of the exhaust gas, the temperature of the water and the steam temperature.

Rankine circuit systems can be operated with organic or non-organic media. Rankine circular systems that are operated with organic working fluid are also referred to as Organic RC or ORC. By contrast, Rankine cycles operated with organic media are often referred to as Clausius-Rankine circular systems or CRCs.

A disadvantage of Rankine circular systems with an organic working fluid is the limited to relatively low temperatures thermal stability of the organic working fluid.

The present invention deals with the problem for an operating method or for an exhaust heat utilization device or for a working fluid to provide an improved or at least another embodiment, which is particularly characterized in that the thermal stability of the working fluid is better taken into account. In particular, a higher efficiency is sought.

According to the invention, this problem is solved by the subject matters of the independent claims. Advantageous embodiments are the subject of the dependent claims.

The invention is based on the general idea, when operating an exhaust heat utilization cycle in a motor vehicle, to control a working temperature of a working fluid of the exhaust heat recovery cycle by adjusting a mass flow of the working fluid flowing through the heat exchanger of the exhaust heat recovery cycle. It should be avoided by regulating the working temperature that the working fluid exceeds a maximum allowable working temperature. Especially in the case of using organic working fluids, the exhaust gas temperature can be well above the chemical decomposition temperature of the working fluid. Therefore, it is expedient to regulate the maximum permissible operating temperature of the working fluid only slightly below the chemical decomposition temperature. Preferably, the process temperature of the working fluid should fall below the decomposition temperature by the tolerance range of the temperature control quality. As a result, decomposition of the particular organic working fluid can be prevented or at least reduced or delayed.

In the case of a working fluid designed as a mixture, the decomposition temperature is preferably the lowest of the chemical decomposition temperatures of the components of the working fluid. This is also referred to below as the lowest chemical decomposition temperature of the working fluid.

Exhaust gas heat recovery cycle processes that are equipped with, in particular, organic, working fluids and are operated so that the operating temperature is regulated by adjusting a mass flow of the working fluid flowing through a heat exchanger of the exhaust gas heat recovery cycle can be used in exhaust heat utilization devices of a motor vehicle.

As the working fluid, an organic fluid may be used in such exhaust heat utilization device of a motor vehicle having an exhaust heat utilization cycle. The fluid is vaporizable and condensable, an organic compound or a mixture of organic compounds and has at least methanol, ethanol, N-propanol, iso-propanol, dimethyl ether, ethyl methyl ether, diethyl ether or an alkane. At least one of the organic compounds or a compound mixture containing at least methanol, when used in a waste heat utilization device, causes the waste heat utilization device to have a higher efficiency than with water as the working fluid.

The exhaust heat utilization may utilize the heat of the exhaust gases in the exhaust system and / or the heat of the recirculated exhaust gas recirculation gases.

Other important features and advantages of the invention will become apparent from the dependent claims, from the drawings and from the associated figure description with reference to the drawings. It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

Preferred embodiments of the invention are illustrated in the drawings and will be described in more detail in the following description, wherein like reference numerals refer to the same or similar or functionally identical components.

Show, in each case schematically,

Fig. 1 a via a heat exchanger with the exhaust stream of a

FIG. 2 shows an efficiency behavior of different working fluids. FIG.

1, an exhaust heat utilization device 1 for use in automobiles, an exhaust heat utilization cycle 2 and an internal combustion engine 3, which are connected to each other via an exhaust gas supply line 4. The exhaust heat utilization cycle 2, which is formed in this embodiment as a Clausius-Rankine cycle, has a heat exchanger 5, a turbine 6 with a power converter 7, a capacitor 8 and a pump 9. If such an exhaust heat recovery cycle process 2 is operated by a process according to the Rankine cycle, a pressure P ₁ and a temperature T ₁ prevails between the condenser 8 and the pump 9, a pressure p ₂ between the pump 9 and the heat exchanger 5 and a temperature T ₂ , between the heat exchanger 5 and turbine 6, the pressure p ₂ and a temperature T ₃ and between the turbine 6 and condenser 8, the pressure P ₁ and the temperature T ₁ , wherein the pressure p _{2 is} greater than the pressure P ₁ and the temperature T _{3 is} greater than the temperature T ₂ and greater than the temperature T ₁ . The exhaust heat utilization cycle 2 can also be operated according to other cycles, such. B. after the Carnot cycle, the Stirling cycle or the Joule cycle or the like. In this case, possibly other pressure and temperature conditions occur in the working fluid.

Hot exhaust gas introduced from the internal combustion engine 3 into the heat exchanger 5 via the exhaust gas supply line 4 flows through the same and evaporates the working fluid circulated in a circulation line 10, which is in a turbine 6 is expanded, whereby part of the waste heat 11 supplied in the heat exchanger 5 can be converted into usable work 12 by the power converter 7. The expanded working fluid is subsequently liquefied in the condenser 8 and pumped through the heat exchanger 5 for receiving waste heat 11 by means of the pump 9 at elevated pressure p ₂ .

In an embodiment presented here, the exhaust heat utilization cycle 2 can be operated by a method in which the working temperature of the working fluid is controlled by adjusting a mass flow of the working fluid flowing through the heat exchanger 5 so that a maximum allowable working temperature of the working fluid is not exceeded. Especially with organic working fluids such. As methanol, diethyl ether, dimethyl ether or the like or organic compound mixtures, the regulation of the working temperature T ₁ , T _{2 of} the working fluid is essential for the proper functioning of the exhaust heat recovery cycle 2, since due to the hot exhaust gases, for example, the temperatures of 700 ⁰ C can reach, a decomposition temperature of a working fluid of z. B. 350 ⁰ C is far exceeded. In this case, at full load, the hot exhaust gas flowing through the heat exchanger 5 would at least partially decompose the organic working fluid also flowing through the heat exchanger 5 in opposite directions. Since this should be prevented, it is expedient to select the maximum permissible operating temperature of the working fluid so that it is, for example, at least 20 ⁰ C less than the chemical decomposition temperature of the working fluid.

In the case of substance mixtures, it must be taken into account that the individual organic compounds are decomposed at different temperatures. In this case, it is a condition to choose the maximum allowable working temperature so that the lowest chemical decomposition temperature is taken into account. It is expedient that the chemical decomposition temperature of the working fluid above the control range of the temperature, for example 2O ⁰ C above the maximum temperature of the waste heat, then the chemical decomposition of the working fluid can be neglected by the waste heat and at least only occurs if by a technical defect exposes the flow rate of the working fluid through the heat exchanger 5 and thus to flow through the working fluid contained in the heat exchanger 5 without the heat exchanger 5, remains in the same. In addition, the working temperature of the working fluid can be regulated by cooling it prior to entry into the heat exchanger 5. Also, the operating temperature may be affected by limiting the waste heat fluid mass flow passing through the heat exchanger 5 and by admixing cold fluids to the waste heat fluid before entering the heat exchanger 5. Such measures are advantageous if in the circulation line 10, a maximum possible working fluid mass flow is reached and this can not be increased. If, in this case, a temperature increase continues after the heat exchanger 5 in the direction of the turbine 6, and there is the danger that the maximum permissible operating temperature of the working fluid is exceeded, the waste heat 11 which is present in the heat exchanger 5 can be removed by the above-described measures is supplied by the waste heat, limited and thus the working temperature of the working fluid can be controlled.

In order to allow a more accurate and finer adjustment of the working temperature of the working fluid, further parameters can be taken into account in the regulation of the working temperature. Thus, due to the detection and processing of the temperature of the waste heat fluid before and / or after the heat exchanger 5 and / or a temperature of the working fluid before and / or after the heat exchanger 5 and by a pressure of the working fluid before and / or after the turbine 6 and / or by a flow rate of the working fluid and / or the waste heat, the waste heat 11 transferred in the heat exchanger 5 are determined in particular in time dependence due to the detection signals and thus the working temperature are kept constant regardless of peak loads below the chemical decomposition temperature.

It is advantageous to use such organic compounds as the working fluid in a waste heat utilization device 1, in which the efficiency of the waste heat recovery device 1 is greater than using water as the working fluid. As an example, methanol should be mentioned here, as can be seen from FIG. According to FIG. 2, several efficiency curves of n-octane 13, n-heptane 14, toluene 15, n-hexane 16, cyclohexane 17, benzene 18 and ethanol 19 show a poorer efficiency behavior than the efficiency curve of water 20. In the examples given alone the efficiency curve of methanol 21 is superior to water 20 in terms of efficiency. Also suitable as working fluid are alkanes. It should be noted at this point, however, that other organic compounds, used as working fluid, may have an even higher efficiency of the waste heat utilization device 1. In an advantageous Embodiment thus uses an organic working fluid comprising an organic compound or a mixture of organic compounds, which working fluid in the exhaust heat utilization device 1 has a higher efficiency than water 20.

A change in the mass flow of the working fluid changes the temperature T3 of the working fluid. Increasing the mass flow reduces the heat input per mass and lowers the working medium temperature T3. A reduction of the mass flow can increase the heat input per mass and thus the working medium temperature T3. In this way, a regulation of the operating temperature T3 by means of adaptation of the working fluid mass flow can be displayed.

In this case, the decomposition temperature of such a working fluid can be taken into account by regulating the working temperature by adjusting the working fluid mass flow in such a way that the working temperature in each case remains below the decomposition temperature of the working fluid during operation of the exhaust heat utilization device.

LIST OF REFERENCE NUMBERS

1 Abgaswärmenutzungsvorπchtung

2 exhaust gas heat recovery cycle

3 internal combustion engine

4 exhaust gas supply line

5 heat exchangers

6 turbine

7 power converters

8 capacitor

9 pump

10 circulation pipe

11 waste heat

12 work

13 N-octane

14 N-heptane

15 Toloul

16N-hexane

17 cyclohexane

18 benzene

19 ethanol

20 water

21 methanol

Claims

claims

1. A method for operating an exhaust gas heat recovery cycle (2) in a motor vehicle, with a regulation of a working temperature (T ₁ , T ₂ , T ₃ ) of a working fluid of the exhaust heat recovery cycle (2), characterized in that the working temperature (T ₁ , T ₂ , T ₃ ) by adjusting a by a heat exchanger (5) of the exhaust heat recovery cycle (2) flowing mass flow of the working fluid is controlled so that a maximum allowable working temperature of the working fluid is not exceeded.

2. The method according to claim 1, characterized in that the working temperature (T ₁ , T ₂ , T ₃ ) of the working fluid is also regulated by at least one of the following measures:

Cooling a waste heat fluid, in particular an exhaust gas of an internal combustion engine (3), before entering the heat exchanger (5),

Limiting the waste heat fluid mass flow flowing through the heat exchanger (5),

- Mixing of cold fluids to waste heat fluid before entering the heat exchanger (5).

3. The method according to any one of the preceding claims, characterized in that in the regulation of the working temperature (T ₁ , T ₂ , T ₃ ) at least one of the following parameters is taken into account:

a temperature of the waste heat fluid upstream of the heat exchanger (5), a temperature of the waste heat fluid after the heat exchanger (5),

a temperature (T ₂ ) of the working fluid upstream of the heat exchanger (5),

a temperature (T ₃ ) of the working fluid after the heat exchanger (5),

a pressure (p ₂ ) of the working fluid in front of a turbine of the exhaust heat utilization cycle (2),

a pressure (P ₁ ) of the working fluid after the turbine, the exhaust heat utilization cycle (2), a flow rate of the working fluid,

a flow velocity of the waste heat fluid.

4. The method according to any one of the preceding claims, characterized in that the maximum permissible operating temperature of the working fluid is below a chemical decomposition temperature of the working fluid.

5. The method according to claim 4, characterized in that the maximum operating temperature of the working fluid falls below the chemical decomposition temperature by the tolerance range of the temperature control quality.

6. The method according to any one of the preceding claims, characterized in that the method comprises a cyclic process, which is configured in particular as Carnot cycle, as Clausius-Rankine cycle, as a Stirling cycle or as a Joule cycle or the like.

7. An exhaust heat utilization device of a motor vehicle, comprising an exhaust heat recovery cycle (2), which is equipped so that it can be operated according to a method of claims 1 to 6.

8. fluid for use as working fluid in an exhaust heat utilization device (1), in particular according to claim 7, a motor vehicle with an exhaust heat recovery cycle (2), wherein the fluid vaporizable and is condensable and an organic compound or a mixture of organic

Contains or consists of compounds, characterized in that the fluid has at least one of the following compounds:

- a simple alcohol, such as. For example, methanol, ethanol, n-propanol, iso-propanol, an ether such. As dimethyl ether, ethyl methyl ether, diethyl ether,

- an alkane.

9. fluid according to the preceding claim, characterized in that the lowest chemical decomposition temperature of the working fluid to the control range of the temperature grade is above a maximum temperature of the waste heat fluid.