Heat exchanger for temperature control of vehicle batteries

What is claimed is: 1. A heat exchanger for temperature controlling and fastening of battery units of a vehicle, the heat exchanger comprising: a plurality of continuously formed first multi-channel flat tubes passable by a heat carrier and forming a holding frame, the holding frame providing a structure that forms a plurality of substantially rectangular chambers for receiving the battery units, the plurality of first multi-channel flat tubes oriented substantially parallel to each other, the plurality of substantially rectangular chambers having narrow sides and longitudinal sides defined by the plurality of first multi-channel flat tubes, wherein the narrow sides of the plurality of substantially rectangular chambers formed by the plurality of first multi-channel flat tubes are arched outwardly causing the narrow sides of the plurality of substantially rectangular chambers to shorten and the longitudinal sides of the plurality of substantially rectangular chambers to approach each other to compensate for expansion of the battery cells due to a thermal load; a distributing tube for conducting the heat carrier to a first end of each of the plurality of first multi-channel flat tubes, wherein the distributing tube and the first ends of each of the plurality of first multi-channel flat tubes define a first one of the narrow sides of the plurality of substantially rectangular chambers; and a collecting tube for conducting the heat carrier from a second end of each of the plurality of first multi-channel flat tubes, wherein the collecting tube and the distributing tube are connected to each other by the plurality of first multi-channel flat tubes, wherein the collecting tube and the second ends of each of the plurality of first multi-channel flat tubes define a second one of the narrow sides of the plurality of substantially rectangular chambers; wherein the plurality of substantially rectangular chambers is disposed between the distributing tube and the collecting tube; and wherein an intermediate portion of each of the plurality of first multi-channel flat tubes defines at least one of the longitudinal sides of the plurality of substantially rectangular chambers so the plurality of substantially rectangular chambers is surrounded by the plurality of first multi-channel flat tubes; and wherein vertically adjacent ones of the plurality of first multi-channel flat tubes are mechanically and heat-conductively connected to each other by heat conducting sheets in a vertical direction so the plurality of substantially rectangular chambers is segmented for accommodating the battery units by the heat conducting sheets, and wherein each of the heat conducting sheets is oriented substantially vertical. 2. The heat exchanger according to claim 1 , wherein the plurality of first multi-channel flat tubes is oriented substantially horizontal to each other, and the collecting tube and the distributing tube are oriented substantially vertical, and wherein the connections for discharging the heat carrier are provided at the collecting tube and for charging the heat carrier are provided at the distributing tube. 3. The heat exchanger according to claim 1 , wherein the plurality of first multi-channel flat tubes encloses the battery units located in the plurality of substantially rectangular chambers. 4. The heat exchanger according to claim 1 , wherein the collecting tube and the distributing tube are established such that the heat carrier mass flow is dividable into partial flows among the plurality of first multi-channel flat tubes, and wherein all partial flows pass the plurality of first multi-channel flat tubes parallel in one direction. 5. The heat exchanger according to claim 1 , wherein the collecting tube and the distributing tube are established such that the heat carrier mass flow is dividable into partial flows among the plurality of first multi-channel flat tubes, and wherein the partial flows pass the plurality of first multi-channel flat tubes parallel in one direction and after redirection in one of the collecting tube and the distributing tube adjacent first multi-channel flat tubes are passed in countercurrent. 6. The heat exchanger according to claim 1 , further comprising a bracing frame disposed on an outer surface of the plurality of first multi-channel flat tubes and bracing struts disposed in the plurality of substantially rectangular chambers. 7. The heat exchanger according to claim 6 , wherein the bracing struts are passed between adjacent battery units and brace side walls of the bracing frame. 8. The heat exchanger according to claim 7 , wherein the bracing struts are established such that they are stretched on bracing, hence ensuring a prestress in order to brace the side walls of the bracing frame. 9. The heat exchanger according to claim 1 , wherein the narrow sides of the plurality of substantially rectangular chambers are arched outwards in a direction that the longitudinal sides of the plurality of substantially rectangular chambers extend. 10. The heat exchanger according to claim 1 , wherein the plurality of first multi-channel flat tubes all have substantially equal external geometries and dimensions and at least one of the first multi-channel flat tubes includes a different interior cross-section for directing flow of the heat carrier therethrough than does an adjacent one of the first multi-channel flat tubes. 11. The heat exchanger according to claim 1 , wherein the intermediate portion of each of the plurality of first multi-channel flat tubes defines a pair of opposing longitudinal outer sides of the plurality of substantially rectangular chambers, and wherein the heat exchanger further comprises a plurality of continuously formed second multi-channel flat tubes, the plurality of second multi-channel flat tubes longitudinally formed, wherein the distributing tube and the collecting tube are further connected to each other by the plurality of second multi-channel flat tubes, the plurality of the second multi-channel flat tubes forming an intermediate side of the plurality of substantially rectangular chambers, the intermediate side configured to segment the substantially rectangular chambers. 12. A heat exchanger for temperature controlling and fastening of battery units of a vehicle, the heat exchanger comprising: a plurality of spaced apart continuously formed multi-channel flat tubes for conducting a heat carrier and forming a holding frame with a plurality of chambers formed therein having a rectangular layout with narrow sides and longitudinal sides defined by the plurality of multi-channel flat tubes for receiving the battery units, wherein the multi-channel flat tubes are oriented substantially parallel to each other, and wherein the narrow sides of the plurality of substantially rectangular chambers formed by the multi-channel flat tubes are arched outwardly causing the narrow sides of the plurality of substantially rectangular chambers to shorten and the longitudinal sides to approach each other to compensate for expansion of the battery cells due to a thermal load, vertically adjacent ones of the plurality of multi-channel flat tubes mechanically and heat-conductively connected to each other by heat conducting sheets, each of the heat conducting sheets oriented substantially vertical; a distributing tube for conducting the heat carrier to a first end of each of the plurality of multi-channel flat tubes, wherein the distributing tube and the first ends of each of the plurality of multi-channel flat tubes define a first one of the narrow sides of the plurality of substantially rectangular chambers; and a collecting tube for conducting the heat carrier from a