DE102008048002A1 - Energy converting assembly for use in vehicle, has heat transfer medium moving from one aggregation condition into another aggregation condition to independently interact with heat transfer surface of heat sink - Google Patents

Abstract

The assembly has multiple functional cells (3) i.e. energy storage cells such as electrical-lithium-ion batteries, a heat transfer medium (5), and a housing (2) surrounding the functional cells and the heat transfer medium. The housing accommodates a heat sink (1) whose heat transfer surface (1a) is arranged at a distance from the heat transfer medium in an aggregation condition. The heat transfer medium moves into another aggregation condition at operating temperature of the functional cells to independently interact with the heat transfer surface.

Description

Field of the invention

The Invention is in the field of mechanical engineering and electrical engineering, in particular concerning the construction of complex, energy implementing Apparatuses.

The The invention more specifically relates to the production of optimized thermal Conditions for a complex facility with function cells.

It are from the prior art, a variety of facilities for Controlling the temperature of an aggregate known, in particular cooling devices, the aggregates, which themselves heat produce or produce surplus heat as waste product, in a certain operating temperature range.

To are known as active systems in which a mobile cooling medium by means of pumps, as far as it is a liquid medium, or by means of fans, if it is a gaseous cooling medium trades, to be moved by the material transport simultaneously Heat from one to be cooled Transporting element away. Alternatively, they are also passive Elements are known in which a transport of waste heat through heat conduction, radiation of Heat or Convection is going on.

moreover closed and open systems are distinguished, with closed ones Systems a closed housing provide that does not allow material exchange with the housing exterior, while open Systems in particular a gas or liquid transport between the exterior of the housing and the inside of the housing or from and to the to be cooled Allow element.

It is also it is known that when using a liquid as a heat exchange medium these at least partially vaporize and when using a closed Systems can precipitate elsewhere by condensation again.

Of the The present invention is based on the prior art Technique the task is based, an aggregate with a possible simple and efficient device for controlling the temperature to create functional cells.

The Task is according to the invention solved with the features of claim 1.

there has an inventive aggregate Function cells, the temperature within an operating temperature range should be regulated. The functional cells can be used, for example, as energy storage cells be trained for an efficient function in a specific temperature range operated Need to become and the self-waste heat produce, which usually leads to a temperature increase. The Energy storage cells can be formed for example as lithium-ion batteries. however are as function cells still other exothermic working element conceivable. A heat exchange medium, which at least partially surrounds the functional cells, provides for a heat exchange and therefor, that the individual functional cells at a substantially common temperature being held. The heat exchange medium is chosen like this and / or set that by supplying heat constantly Part of the medium is transferred to another state of aggregation. If the first state of aggregation is the liquid state, it is constantly on Part of the liquid evaporated. The latent heat energy used for the phase transition is taken from the functional cells and thereby causes additional cooling.

Of the vaporized or gasified part of the heat exchange medium is inside of the housing of the Aggregates very mobile and interacts with a cooling surface, the in turn, for example, with a heat sink on the outside of the housing can be connected. There, the medium gives off heat and falls into the first state of aggregation back. So has the heat exchange medium as part of its movement the latent heat of the phase transition transported to the cooling surface and delivered there. As a result, a particularly efficient cooling is given. The advantages of the invention are therefore on the one hand in a homogenization of Temperature between the functional cells in the context of the first state of aggregation of the heat exchange medium and in an efficient heat dissipation due to the phase transition and the higher mobility of the heat exchange medium.

Basically alternatively to a liquid and evaporable heat exchange medium as well a solid medium conceivable by the effect of Wärmeein the functional elements partially liquefied becomes and in liquid Form flows to a heat exchange surface / cooling surface.

These is either connected to a heat sink or with a refrigeration unit, for example, by electrical cooling as a Peltier element or by other known cooling effects chilled becomes.

Thus, the described heat transfer, which is associated with a mass movement in gaseous or liquid form, not to a loss leads of parts of the heat exchange medium, the housing of the unit is advantageously carried out dense or gas-tight. It is important to note the stability to pressure changes when a part of the heat exchange medium is evaporated and thus the pressure rises.

Incidentally, can advantageous to be provided a pressure control, for example is realized by gas pumps and adjustable by a pressure range is that which leads that at the prevailing temperature, a part of the heat exchange medium evaporated.

moreover can also be provided advantageously a heating device to the Heat exchange medium to a desired Temperature to bring, on the one hand, the cooling process works, and on the other hand, the functional elements are operational. For example, are lithium ion battery storage elements, so a temperature window between 20 and 60 ° C is to be maintained in order to achieve an optimum To ensure the function of the energy storage cells. For this purpose, the Operation of a heater will be helpful.

Also the operation of an additional Cooling the Heat exchange medium in the first state of aggregation is conceivable, for example by the Use of Peltier elements. This cooling can be done by cooling partial transition support the second state of aggregation.

The Invention relates except on an aggregate of the type indicated above also on a temperature control device for at least a functional cell with a housing in which the functional cell is arranged, a heat exchange medium, that at least to a first part in a first state of aggregation is present and in the first state of aggregation, the functional cell at least partially surrounds, with one of the first part of the heat exchange medium with spaced heat exchange surface as well with a controllable heater.

A Such temperature control device is suitable for functional cells not just efficient to cool, but using the auxiliary heater their temperature within a temperature control window in which an optimized Operation of the cells possible is.

in the The following is the invention with reference to an embodiment in a drawing shown and then described.

there shows

1 schematically an inventive unit,

2 an aggregate with an additional heating or cooling device and

3 schematically the function of the temperature control device.

1 shows an example of an aggregate with some electrically connected lithium-ion energy storage cells 3 in a housing 2 are arranged, which on its upper side a heat sink 1 with a heat exchange surface 1a wearing.

The housing 2 is typically designed gas-tight, for example, of a ceramic material, which is soldered gas-tight. The electrical connections 6a . 6b are electrically insulating also gas-tight through the housing wall of the housing 2 carried out. Electric lines 4 connect in the interior of the housing, the individual cells together in a meaningful interconnection.

At least part of the case 2 is with a liquid cooling medium 5 filled the individual cells 3 flows around and thus minimizes any occurring temperature gradient. About the cells 3 is a vaporous heat exchange medium 7 formed from the vapor phase of the cooling medium 5 consists. This medium is chosen so that it is at the operating temperature of the cells 3 , ie in the temperature range between 20 and 60 ° C in the case of the use of lithium-ion batteries, its boiling point. The medium should also be electrically non-conductive and non-corrosive and have sufficient heat content. Optionally, in order to establish a suitable state or to control a suitable point in the state diagram, a pressure control device may be provided for setting a suitable gas pressure above the liquid.

The 2 shows a similar arrangement as the 1 additionally with an electric heating and / or cooling device 8th in the area of the liquid heat exchange medium 5 , via which a suitable working temperature can be adjusted. It may be, for example, a PTC resistor or a Peltier element, which may optionally be used as a cooling element in this case.

The function of the unit according to the invention is based on 3 schematically shown in detail. The same parts are provided with the same reference numerals as in the 1 and 2 , It is exemplary only a single lithium-ion cell 3 represented by the liquid cooling / heat exchange medium 5 in the case 2 is surrounded. By means of a temperature sensor 10 becomes the temperature of the liquid medium 5 measured and the detected measured value to a control device 11 passed.

Through a current sensor 12 is connected to a connecting cable 6a . 6b the silicon cell whose operating state is typically measured by the supplied current and also to the controller 11 passed. This control unit and / or cooling element 8th possibly appropriate to a desired temperature of the liquid medium 5 for optimal operation.

Part of the cooling capacity takes place via the so-called boiling water cooling, in which parts of the liquid medium 5 be evaporated and in the free space of the housing 2 ascend, as by the arrow 13 shown schematically. The vaporous components of the heat exchange medium reach the outer wall of the housing 2 or ideally a heat sink 1 with a corresponding heat exchange surface 1a There, by condensation, they release their latent heat, and after passing into the liquid state, they enter the liquid 5 drip back, as indicated by the arrow 14 symbolizes. The heat is passing through the heat sink 1 emitted outside, as indicated by the arrows 15 is indicated.

On this way is with the unit according to the invention and a corresponding Temperature control device in a simple way an efficient passive Cooling, for example, an electric battery module reached.

This can be particularly advantageous when using the stored Energy must be handled very sparingly, z. B. in the Use as drive battery for a vehicle.

1

heatsink

1a

Heat exchange surface

2

casing

3

Energy storage cells

4

cables

5

cooling medium

6a, 6b

connections

7

Heat exchange medium

8th

Heating / cooling device

10

temperature sensor

11

control device

12

current sensor

13 14, 15

arrows

Claims (11)

Aggregate with several functional cells ( 3 ), in particular energy storage cells, a heat exchange medium at least partially surrounding them in a first state of aggregation ( 5 ) and a housing surrounding the functional cells and the heat exchange medium ( 2 ) having a heat exchange surface (17) spaced from the heat exchange medium in its first state of aggregation ( 1a ), wherein the heat exchange medium is designed such that it at least partially merges at the operating temperature of the functional cells in a second, fluid state in which it interacts independently with the heat exchange surface. Unit according to claim 1, characterized in that the first state of aggregation of the heat exchange medium ( 5 . 7 ) is liquid. Unit according to claim 2, characterized in that the second state of aggregation of the heat exchange medium ( 5 . 7 ) is gaseous or vaporous. Unit according to Claim 1 or one of the following, characterized in that the heat exchange surface ( 1a ) with a cooling element, in particular with a heat sink ( 1 ), connected is. Unit according to Claim 1 or one of the following, characterized in that the housing ( 2 ) is gas-tight. Unit according to Claim 1 or one of the following, characterized by a heating device ( 8th ). Aggregate according to Claim 1 or one of the following, characterized by an electrical cooling device. Aggregate according to Claim 1 or one of the following, characterized in that the functional cells ( 3 ) are electric lithium-ion batteries. Aggregate according to Claim 1 or one of the following, characterized in that the operating temperature of the functional cells between 20 and 60 ° C lies. Unit according to Claim 1 or one of the following, characterized in that a pressure control device for controlling the gas pressure in the housing ( 2 ) is provided. Temperature control device for at least one functional cell ( 3 ) with a housing ( 2 ), in which the functional cell is arranged, a heat exchange medium ( 5 . 7 ), which is present at least to a first part in a first state of aggregation and in the first state of aggregation the Funkti onszelle at least partially, with a spaced from the first part of the heat exchange medium heat exchange surface ( 1a ) and with a controllable heating and / or cooling device ( 8th ).