DE102011090152A1 - thermogenerator - Google Patents

Abstract

The invention relates to a thermogenerator for converting heat into electrical energy, comprising a top layer and a bottom layer of thermally conductive material, and an intermediate layer disposed between the top layer and bottom layer, the intermediate layer comprising first metal thermocouples, second metal thermocouples, and elements having a non-heat conductive material.

Description

The invention relates to a thermogenerator for converting heat into electrical energy having a top layer and a bottom layer of a thermally conductive material and an intermediate layer, wherein the intermediate layer of thermocouples consists of two different metals and disposed between the metals elements of non-thermal conductive material.

To convert parts of a heat flow into electrical energy and thus to partial energy recovery, for example in automobiles with internal combustion engine, more and more heat generators are used. These consist of a plurality of pairs of thermocouples, with a first thermocouple of a first material and a second thermocouple of a second material, which is different from the first material. For example, in the prior art, at temperatures up to 570 ° C, Bi2Te3 thermocouples are combined with PbTe thermocouples. The materials for these thermocouples are very expensive. At even higher temperatures even more expensive materials must be used, so that the use of thermal generators at temperatures above 570 ° C economically not worthwhile.

It is an object of the invention to provide a thermogenerator which can be adapted to different installation situations and can be produced inexpensively and can be used economically even at temperatures above 570 ° C.

This object is achieved by the thermogenerator according to claim 1, claim 2 and claim 3.

The invention relates to a thermogenerator having a superstructure, an underlayer and an intermediate layer disposed between these two layers, comprising first metal thermocouples, second metal thermocouples and non-thermally conductive material elements.

As a rule, the upper side of the upper layer of the thermal generator faces a heat source, while the underside of the lower layer is connected to the environment or a cooling circuit in order to dissipate residual heat from the thermal generator. Just as well, the lower layer of the heat source may be facing and serve the upper layer of the derivative of the residual heat.

Upper and lower layers of the thermal generator may for example consist of a thermally conductive ceramic or have such. The ceramic can be the same for both sides, but it can also be used depending on the temperatures ceramics with different Wärmeleitfaktor for the upper layer and the lower layer. The thickness of the ceramic layers for the upper layer and the lower layer of the thermal generator may be the same or different. The ceramic layer may be homogeneously structured or a ceramic composite, with layers of ceramic of different composition.

The thermocouples of the thermogenerator are formed of different metals, wherein each preferably two thermocouples of different metals are at least in a section touching next to each other. The metals are preferably not precious metals or special alloys but good to be processed, inexpensive metals of the periodic table, as used for example in mechanical engineering.

According to claim 1, the first metal is an iron (Fe), while the second metal may be any other metal, for example an alloy or a bimetal.

According to claim 2, the first metal is an aluminum (Al), while the other metal may be any other metal, for example an alloy or a bimetal.

According to claim 3, the first material is iron (Fe) and the second material is aluminum (Al).

The iron and the aluminum preferably have a purity of at least 95%. That is, the metals contain at most 5% of impurities and / or admixtures.

The thermocouples have, for example, a waveform, a Z-shape or a similar shape, in which the ends of two preferably largely identically shaped thermocouples can be connected to each other across the cross-section surface, that is, butt-to-joint. The shape and / or size of successive thermocouples may also be different, if required by the installation conditions.

The space of the intermediate layer, which is not filled with thermocouples, is filled by elements made of a non-heat-conducting material. That is, in a cavity remaining between the two adjacent thermocouples due to the shape of the thermocouples, elements made of a non-heat-conducting material, preferably a non-thermally conductive ceramic, form the thermogenerator.

The thermoelements forming the thermogenerator can be electrically connected in series and / or in parallel. The design and shape of the thermal generator can be chosen freely as far as possible and may depend on the installation location, the available space at the installation site and other conditions prevailing there.

A thermogenerator can have thermocouples of the same shape and size or of different shape and size in order to adapt the thermogenerator to different installation situations. For example, the thermal generator may have a round, trough-shaped outer shape to be installed near a cylinder head of an internal combustion engine, or it may be an annular or tubular body fitted in the exhaust line of an internal combustion engine.

In principle, the thermal generator can be installed anywhere in a machine, for example an internal combustion engine, where a sufficient excess of heat is generated, which makes a conversion of the heat energy into electrical energy economically sensible. Due to its structure, the thermogenerator is high temperature resistant, robust, inexpensive and adaptable in shape and size to the respective application. This allows economical use of thermal generators also in places and under conditions that were previously considered difficult or unsuitable. Thus, the thermal generator can also be installed in places where the upper layer is exposed to temperatures above 570 ° C.

In the following, the thermogenerator is explained in more detail with reference to two figures. Features and combinations of features, which can only be seen in the figures, can advantageously further develop the thermogenerator and belong to the scope of the invention. The invention is not limited to the exemplary embodiments shown.

In detail, the figures show:

1 basic structure of a planar thermogenerator

2 Thermogenerator for attachment to a cylinder head

The 1 shows a section through a flat thermal generator 1 , The thermogenerator 1 has an upper class 2 on, with an upper side facing a heat source, not shown. The upper class 2 is formed of a thermally conductive material, for example a thermally conductive ceramic and conducts the heat of the heat source into the interior of the thermal generator 1 ,

The thermogenerator 1 also has an undercoat 3 on, the heat from inside the thermogenerator 1 can deliver to the environment or a cooling system, not shown. Also this lower class 3 is formed of a thermally conductive material, preferably a thermally conductive ceramic.

The inside of the thermogenerator is made by thermocouples 4 . 5 and elements 6 built up. The thermocouples 4 . 5 have an identical shape in the embodiment and are arranged so that they abut with opposite ends. Here are the thermocouples 4 made of a first material, a metal, for example, iron and the thermocouples 5 from a second material, for example aluminum.

The Elements 6 are formed of a non-heat conductive material, for example a ceramic, and prevent the surface passage of the heat coming from the heat source through the thermogenerator 1 ,

The thermogenerator 1 converts it through the thermocouples 4 . 5 flowing heat flow using the Seebeckeffekts in electrical power. The voltage of the thermogenerator 1 depends on the material properties and the number of interconnected thermocouples 4 . 5 from and of the temperature difference between those at the top layer 2 or the lower layer 3 adjacent thermocouple legs 7 ,

The 2 shows a thermogenerator 1 , to the cylinder head 8th an internal combustion engine can be grown. The thermogenerator 1 has a round, bowl-shaped formation with an outer surface that at least partially the lower layer 3 of the thermogenerator 1 forms and an annular inner surface, which faces the heat source and therefore the upper layer 2 forms. To recognize is a connection 9 for dissipating in the thermogenerator 1 generated electrical energy to a consumer or a battery.

Claims (12)

Thermogenerator ( 1 ) for converting heat into electrical energy, with a top layer ( 2 ) and an underclass ( 3 ) of thermally conductive material, and one between the upper layer ( 2 ) and sublayer ( 3 ), wherein the intermediate layer thermocouples ( 4 ) of a first metal, thermocouples ( 5 ) of a second metal and elements ( 6 ) Made of a thermally non-conductive material, characterized in that Fe) is that the first metal, an iron (. Thermogenerator ( 1 ) for converting heat into electrical energy, with a top layer ( 2 ) and an underclass ( 3 ) of thermally conductive material, and one between the upper layer ( 2 ) and sublayer ( 3 ), wherein the intermediate layer thermocouples ( 4 ) of a first metal, thermocouples ( 5 ) of a second metal and elements ( 6 ) of a non-heat-conducting material, characterized in that the first metal is an aluminum (Al). Thermogenerator ( 1 ) for converting heat into electrical energy, with a top layer ( 2 ) and an underclass ( 3 ) of thermally conductive material, and one between the upper layer ( 2 ) and sublayer ( 3 ), wherein the intermediate layer thermocouples ( 4 ) of a first metal, thermocouples ( 5 ) of a second metal and elements ( 6 ) of a non-heat-conducting material, characterized in that the first metal is an iron (Fe) and the second metal is an aluminum (Al). Thermogenerator according to one of claims 1 to 3, wherein the upper layer ( 2 ) faces a heat source and the lower layer ( 3 ) serves to dissipate the residual heat, or vice versa. Thermogenerator according to one of the preceding claims, wherein the upper layer ( 2 ) and / or the lower layer ( 3 ) is formed of a thermally conductive ceramic / are. Thermogenerator according to one of the preceding claims, wherein at least the first metal has a degree of purity of at least 95%. A thermal generator according to any one of the preceding claims, wherein the first metal and the second metal have a purity of at least 95%. Thermogenerator according to one of the preceding claims, wherein between the thermocouples ( 4 . 5 ) arranged elements ( 6 ) consist of a non-heat conductive ceramic. Thermogenerator according to one of the preceding claims, wherein the thermocouples ( 5 . 6 ) are connected in series and / or in parallel. Thermogenerator according to one of the preceding claims, wherein the thermal generator ( 1 ) Thermocouples ( 4 . 5 ) of different shape and size. Thermogenerator according to one of the preceding claims, wherein the thermal generator ( 1 ) on a cylinder head ( 8th ) and / or can be arranged in an exhaust line. Thermogenerator according to the preceding claim, wherein the thermogenerator ( 1 ) is annular and at the upper end of the cylinder in the cylinder head ( 8th ) is arranged.

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