DE102009022062A1 - Device for producing tensioned process gas i.e. steam, for hybrid vehicle, has heat exchanger including cavity for medium converted to process gas in exchanger, where gas is supplied to transducer for transformation into hydraulic energy - Google Patents

Abstract

The device (1) has a shielding component (2) for thermal shielding of a motor (3) or a motor component (4), and a heat exchanger (8) e.g. matrix heat exchanger, heat conductively connected with a shielding layer (5) and including a cavity (6) for liquid medium (7) e.g. water. The liquid medium is converted to hot, tensioned process gas (9) i.e. steam, in the heat exchanger, and the process gas is supplied to a transducer (W) for transformation into mechanical, electrical or hydraulic energy. The transducer is designed as a motor (10) or a turbine with a generator (15). The heat exchanger is designed as a shell-heat exchanger or a tube-heat exchanger.

Description

The The invention relates to a device for generating a tensioned Working gas with a shielding member for heat shielding an engine or an engine component with at least one shielding layer and a thermally conductive associated with having a cavity for a liquid working medium Heat exchanger.

The Thermal management, For example, in vehicles, and thus the requirements for thermal and acoustic shielding components is complex because of modern engines through ever higher power density distinguish with ever smaller space. Factors such as vehicle design, Air resistance and occupant safety systems limit that to disposal standing space in motor vehicles. Further, a rising Number of components to consider which is due, for example, to increasing exhaust emission standards, rising costs Required space for electronic components for engine and accessory control and last but not least because of the expectations of end customers of comfort. For example, by the limited Space available for the removal of heat or heat required cooling air circulation impaired. A big part the components must therefore protected against high temperatures become.

The primary The function of shielding components is more sensitive to temperature Components. Heat sources in the vehicle are, for example, as engine components the exhaust gas leading Parts, such as exhaust manifolds, turbochargers, catalytic converters, Soot particle combustion systems and more. Mostly If the shielding or heat shields are in order three-dimensional free-form surface components, which are also referred to as structural component technical language. The Shielding component should on the one hand as close as possible to the relevant heat source be placed to protect the environment from those arising during operation Heat energy, be it by radiation or convection. It Shielding components are known, the heat-absorbing coolant record and part of a refrigeration cycle are. However, the known Abschirmbauteile are not yet Energy recovery been used.

Of the Invention is based on the object with the aid of a Abschirmbauteils a device for energy recovery to accomplish.

These Task is according to the invention by a Device with the features of claim 1 in its entirety solved.

By doing a shielding member or generally a structural member for shielding from heat sources with at least one shielding layer heat-conducting with an outward media-tight cavity for a liquid Working fluid, such as water, is connected, is a heat exchanger created, with the help of which often very high heat energy contributions from engines or engine components, especially in vehicles, for conversion of the liquid Working means to a hot Tensioned working gas can be used to the working gas a suitable Transducer for conversion to mechanical, electrical or hydraulic To supply energy.

To The labor tax paid can be used as part of a cycle condensed in a condenser and then in turn the heat exchanger supplied become. It may be appropriate the steam with the help of the heat exchanger to overheat or the steam in it suitable separate means for supplying heat from the relevant Direct heat source.

Frequently the shielding also formed multi-layered, so that it at a pertinent structure is advantageous between two screen layers the heat exchanger to arrange. The heat exchanger can be completely the outer shape of the Adapted shield layers be formed by this example, as a matrix heat exchanger. heat exchangers the matrix type are to be used there in an appropriate manner, where two media streams, between which transfer heat is to be kept within separate line courses. The heat will then from one pipe or pipe to the other over one transmit solid medium or a matrix, which surrounds the pipe or pipes. Matrix heat exchanger are of heat exchangers other type, such as the shell and tube type, a concentric tube type and the like, although it is dependent the application case can be quite advantageous, in particular if the heat radiating component itself has a tubular shape, Such heat exchanger types to use in tube form.

Shell heat exchangers or tube heat exchangers have only a wall or barrier, which separates the liquid working fluid from the heat-carrying fluid, for example formed by exhaust gas streams, from one another. In flow channels or pipes, in which the liquid working medium is guided, a plurality of inner and outer structural elements can preferably be provided to increase the area of the heat exchanger and / or to influence the flow direction and the flow speed of the liquid working medium to improve the heat energy transfer. Are suitable for example, inner grooves, grooves, grooves, gutters, ribs and the like. Inside the pipes for the liquid working fluid results in a vortex flow with improved heat transfer and a rapid transition into the gas phase for the respective working fluid. The tensioned working gas can then leave the heat exchanger under high pressure, wherein such flow resistances in the interior of the heat exchanger lines attenuate a backward reaction in the direction of the liquid working medium phase, wherein preferably the working medium flow is valve-controlled in the heat exchanger.

The liquid Work equipment can be used in a step process - especially for stationary heat sources, in which no moving parts occur - are heated. For heat sources with moving components, such as in engines or exhaust turbochargers of vehicles, however, it is advantageous, with the help of an additional, driven by the movable components pump for the liquid working fluid a continuous feed or supply to the heat exchanger make.

to Equalization of Flow rate of the Tensioned working gas, it is advantageous to appropriate memory provided. A conversion into mechanical and / or electrical and / or hydraulic energy can be generated by means of a piston engine as a converter, which is operated with the tensioned working gas done. Here would be a Use of valve-controlled or slide-controlled motors with oscillating Piston or rotating piston conceivable. Further, it may be advantageous be for operating an electric generator as a converter Turbine with the tense working gas to feed. electrical Energy can be save it or for the Operation of electric motors, for Auxiliary units of an internal combustion engine or in a hybrid vehicle for feeding into an electro-hydraulic traction motor.

Further Advantages, features and details of the invention will become apparent the dependent claims and the following description, in which in the drawing embodiment described in more detail is. It can those in the claims and mentioned in the description Features individually for each Seen in itself or in any combination essential to the invention be.

The single FIGURE shows a schematic circuit diagram for a device for generating a strained working gas with a shielding. According to the content of the figure is a motor vehicle 17 with a device 1 shown for generating a stressed working gas 9 with the help of two shielding components 2 . 2 ' , each having a first and second shielding layer 5 . 12 exhibit. The shielding component 2 serves to heat shield an engine 3 of the motor vehicle 17 to components of an electrical device and a fuel system, not shown, of the motor vehicle. The second shielding component 2 ' serves to heat shield an exhaust manifold of the engine 3 as engine component 4 ,

Both shielding components 2 . 2 ' have a surface extension and are with their shape of the respective contour of the motor to be shielded against heat 3 or the engine component 4 adjusted and set with the least possible distance to the respective heat source. Each shielding component 2 . 2 ' has a first shielding layer 5 on, which is a hot component of the engine 3 or the engine component 4 facing, and a second shielding layer 12 which is facing away from said hot components accordingly. Between the respective, formed from a metal sheet with good thermal conductivity screen layers 5 . 12 is a cavity 6 or a piping system for a liquid working fluid 7 , which is preferably formed from water, as part of the heat exchanger thus formed 8th arranged. The heat-conducting with the conduit system for the liquid working fluid 7 connected screen layers 5 . 12 are thus an integral part of the heat exchanger 8th with which the liquid working medium 7 in a prestressed working gas 9 is transferred. The respective first shielding layer 5 is further provided with a, the heat absorption-promoting coating in a preferred manner.

The device 1 for generating a strained working gas is for a continuous operation of the heat exchanger 8th designed, ie one by means of the internal combustion engine (engine 3 ) drivable pump 13 continuously promotes liquid working fluid via a valve system, not shown in detail 18 the heat exchanger 8th to. The pipe system of the heat exchanger 8th is designed so that a rapid transition of the liquid phase into the gas phase takes place and a discharge of strained working gas 9 Overheated, into a store under high pressure 14 he follows. The memory 14 is particularly useful when used as a heat source engine components without significant heat capacity for use and, as a result, a relatively irregular volume flow of the stressed working gas 9 is effected.

The working gas 9 is then an engine 10 or a turbine with a connected generator 15 supplied as a converter W and for obtaining electrical energy and for operating an electric motor 16 or another drive for an accessory of the motor vehicle 17 used. A capacitor 11 serves the liquefaction of the exhaust steam of the engine 10 , where the condensate the heat exchanger 8th is fed again in the sense of a closed cycle.

Claims (14)

Device for generating a stressed working gas ( 9 ) with a shielding component ( 2 . 2 ' ) for heat shielding an engine ( 3 ) or an engine component ( 4 ) with at least one first shield layer ( 5 ) and a heat-conducting associated therewith, a cavity ( 6 ) for a liquid working fluid ( 7 ) having heat exchanger ( 8th ), characterized in that in the heat exchanger ( 8th ) the liquid working medium ( 7 ) to a hot, stressed working gas ( 9 ) and the working gas ( 9 ) is supplied to a converter (W) for conversion into mechanical, electrical or hydraulic energy. Device for generating a compressed working gas according to claim 1, characterized in that the converter is a motor ( 10 ) or a turbine with a connected generator ( 15 ). Device for generating a stressed working gas according to claim 1 or 2, characterized in that the liquid working medium ( 7 ) Water and the working gas ( 9 ) Steam is. Device for generating a stressed working gas according to one of claims 1 to 3, characterized in that the tensioned working gas ( 9 ) after discharge in a condenser ( 11 ) condenses and the heat exchanger ( 8th ) is fed again. Device for producing a stressed working gas according to one of claims 1 to 4, characterized in that the steam in the heat exchanger ( 8th ) is overheated. Device for generating a stressed working gas according to one of claims 1 to 5, characterized in that the Wärmetau shear ( 8th ) between two shield layers ( 5 . 12 ) of the shielding component ( 2 . 2 ' ) is arranged or formed by these. Device for generating a stressed working gas according to one of claims 1 to 6, characterized in that the heat exchanger ( 8th ) is designed as a matrix heat exchanger or as a shell heat exchanger or as a tube heat exchanger. Device for generating a stressed working gas according to one of claims 1 to 7, characterized in that a heat transfer tube of the heat exchanger ( 8th ) in its interior structural elements for enlarging the surface of the heat exchanger ( 8th ) and influencing the flow direction of the liquid working medium. Device for generating a stressed working gas according to one of claims 1 to 8, characterized in that the liquid working fluid ( 7 ) by a pump ( 13 ) continuously or stepwise the heat exchanger ( 8th ) is supplied. Device for generating a stressed working gas according to one of claims 1 to 9, characterized in that the working gas ( 9 ) is directed through one or more high pressure and low pressure stages of the transducer (W). Device for producing a stressed working gas according to one of claims 1 to 10, characterized in that between the heat exchanger ( 8th ) and the converter (W) a memory ( 14 ) for the stressed working gas ( 9 ) is arranged. Device for generating a stressed working gas according to one of claims 1 to 11, characterized in that the working gas ( 9 ) drives an oscillating or rotating piston in the converter (W), provided that this engine ( 10 ) is trained. Device for generating a stressed working gas according to one of Claims 1 to 11, characterized in that the converter (W) comprises an electric generator ( 15 ) whose electric current is an electric motor ( 16 ) or a memory ( 14 ) is supplied for electrical energy. Device for generating a stressed working gas according to claim 13, characterized in that the electric motor ( 16 ) is a drive for an accessory of a vehicle or represents a drive motor for a hybrid vehicle.