EP2340581A2

EP2340581A2 - Battery and method for the production thereof

Info

Publication number: EP2340581A2
Application number: EP09725389A
Authority: EP
Inventors: Günther C. BAUER
Original assignee: IQ Power Licensing AG
Current assignee: IQ Power Licensing AG
Priority date: 2008-03-26
Filing date: 2009-03-26
Publication date: 2011-07-06
Also published as: WO2009117997A3; CN102099945A; WO2009117997A2; RU2010143850A; DE102008015625A1

Abstract

The invention relates to a battery, especially an electrochemical battery, such as a lead-acid battery, and a method for producing same. Said battery comprises a housing for receiving electrochemical components, and a heat-insulating jacket (2, 3, 5). The jacket contains electronic components (6, 7) which are in thermal contact with the housing. The invention also relates to a method for producing such a battery.

Description

A

Battery and method of manufacture

The invention relates to a battery, in particular an electrochemical battery, such. As a lead-acid battery and a method for producing a battery.

From the prior art electrochemical batteries are known, which are used as starter batteries for vehicles. It is well known that the performance and life of such batteries are highly temperature dependent.

In order to increase the efficiency and the service life, it has hitherto been proposed to thermally insulate and temper the batteries. For this purpose, it is necessary to clothe the battery case with a thermal insulation material and to attach a surface heating to the battery case.

References to these measures are preferably taken from the literature, since such batteries are not yet manufactured in series, at least not as starter batteries.

The technology for the production of electrochemical batteries is very mature, since it is usually a large-scale production. Accordingly low are the production costs and the price. It is necessary for market penetration of novel energy storage systems, which have both a thermal insulation and an electronically controlled heating, also to use a highly effective manufacturing technology in order to keep the manufacturing costs low. A lead-acid battery has a housing made of an acid-resistant plastic. So far, the trial and small series production frame, the electronic components such as heating, temperature sensors and the electronic control circuit were glued to the battery case. This ensures good heat transfer. However, this adhesive technology requires a lot of effort in the maintenance of individual parameters, such. As the constant composition of the adhesive, the purity of the bond, but also the humidity and the ambient temperature during bonding. If the optimum parameters are not met, the bond may come off. This causes the heat transfer between the film heater and the battery case to deteriorate.

There is therefore a need to design the manufacturing technology for the production of heat-insulated and electronically controlled batteries so that the optimum heat transfer between the electronic components, such. B. the heating and the temperature sensors is guaranteed and still the cost of these manufacturing steps are reduced, from which the task of the invention is derived.

This object is achieved with a battery according to claim 1 and with a manufacturing method according to claim 6.

The battery according to the invention consists of a conventional battery housing, in which the known electrochemical components are arranged. A typical battery of this type is a lead-acid battery. For thermal or cold insulation, the battery is surrounded by a heat-insulating housing. The material for such a housing consists of a foamed plastic. In contrast to the prior art, in which the electronic components are fixed to the battery case, in the invention according to claim 1, the electronic components are arranged in or on the inside of the heat-insulating housing. This is especially true for the components that must be in thermal contact with the housing, ie, the heater that is provided to heat the battery and the sensors that sense the temperature of the battery housing. The invention has a number of advantages, which are also in connection with the process invention according to claim 6 and are therefore described together:

The cost of attaching the electronic components is low because the material of the heat-insulating housing is sufficiently thick, so that the components are pressed into recesses and thus already held by clamping. It is up to the skilled person to additionally secure the components by means of adhesive, if that should be necessary. Furthermore, the person skilled in the art can select such an insulating material which has the required elastic properties in order to clamp the components securely in the recesses. Another advantage of the invention is that the components can be connected to the insulating material with various highly effective technologies. So it is z. B. possible to use the electronic components by means of a robot to make the wiring also automatically and make the contacting of the lines with the electronic components by means of a soldering robot.

Other technologies can be used to connect the electronic components to the insulating material. So it is z. B. possible to arrange the complete electronic circuit with all components on a thin, flexible film which is wound on a drum. On a second drum of the insulating material is wound. To connect the electronic circuit to the insulating material, the flexible film and the insulating material are jointly guided through the nip of two rolls and pressed together. Subsequently, the insulating material is cut out so that the base of the battery case and the 4 side surfaces as a unit area arise. In further steps, the cut-out insulating material with the electronic circuit pressed or glued thereon is placed around the battery housing, which also takes place automatically.

This explanation of some possible technologies shows by way of example that an invention according to claim 1 and 6, a battery production with high Ef fectivity without creating particularly difficult technological problems.

It is only necessary to ensure that the automatic production steps are carried out so that at least the heater and the temperature sensors are in thermal contact with the battery housing.

In order to ensure this thermal contact, a resilient intermediate layer is arranged in an advantageous development of the invention according to claim 2 between the material of the heat-insulating housing and the electronic component. This elastic intermediate layer presses the heater and the temperature sensors to the battery case.

A further improvement of the heat transfer is achieved if according to claim 3 between the electronic components and the housing of the battery an elastic or soft plastic heat conduction layer is provided.

According to claim 6, the method of manufacturing the battery according to claim 1 is claimed, the method comprising the steps of:

Providing parts of the heat-insulating housing with integrated and at least partially interconnected electronic components. If the battery is constructed so that the heater is to be arranged on one longitudinal side of a starter battery and the temperature sensors including the control electronics on the opposite longitudinal side, then the respective insulation plates must be previously equipped with these components and kept ready.

Now follows the steps of inserting the electrochemical components, ie the electrode packages, into the battery housing, which is then sealed. These steps correspond to the conventional production technology and therefore need not be explained in detail. When the battery is sealed, that is, when a conventional, non-insulated battery is present, this battery is surrounded with the thermal insulation in which the electronic components are already arranged.

According to claim 7, the insulating parts for the bottom surface and the four side surfaces of the battery form a unit. This means that the bottom surface and the four side surfaces have either been cut together or cut out one at a time and then joined together. This can z. B. be done by arranging the individual insulating parts in a plane in a predetermined position and then coated with a self-adhesive film. It is clear to the person skilled in the art that there are other technological alternatives for this purpose.

According to claim 8, the parts for the bottom surface and the four side surfaces are connected to each other by means of foil joints. These foil joints are particularly necessary when the insulating material is relatively thick and otherwise can not be bent by 90 degrees. The preparation of such joints can be done by pressing heated stamp, etc. If, as described above, the individual cut-out insulating parts are adhesively bonded to a self-adhesive film, the desired foil joints also result.

Further measures and advantages of the invention will become apparent from the following description of an embodiment in conjunction with the accompanying schematic drawings.

Fig. 1a and b show cut Isoliermaterialplatten, wherein

Fig. 1a shows the plate for the bottom surface and the side surfaces and

Fig. 1b, the plate for the top of the battery.

Fig. 2 shows a conventional battery. Fig. 3 shows the process steps in the isolation of the battery.

1a shows cut-out insulation material 1 for insulating the bottom 2 and the side surfaces 3 of a battery 4 according to FIG. 2. FIG. 1b shows the insulation material 5 for covering the battery. Reference numeral 6 denotes a recess for receiving the heater and 7 are recesses for receiving temperature sensors.

FIGS. 3 a, b show the method step of applying the insulation to the side walls of the battery. The portions between the bottom insulation 2 and the side surfaces 3 are formed as joints 8. The application of isolation can be done manually or automatically z. B. by means of controllable pressure plates. Likewise, the insulation material 5 can be placed to cover the battery by hand or automatically.

Fig. 3c shows schematically the completely insulated battery. This example of making a battery shows just one of several possibilities. The insulation can also consist of 6 individual plates, which are attached by suitable means to the battery. The decisive features for the application of the technical teaching according to the invention is that in at least one of these plates a recess for receiving at least one electronic component is provided and this component is arranged in this plate before the plate is attached to the battery.

On the basis of the described embodiments, the expert can completely remove the technical teaching of the present invention. It is clear that these embodiments can be further developed and modified or combined by a person skilled in the art with the aid of the teaching according to the invention. Therefore, these, not explicitly mentioned or shown further embodiments fall within the scope of the following claims.

Claims

claims

A battery (4) having a housing for receiving electrochemical components, a heat-insulating enclosure (2, 3, 5) and electronic components in thermal contact with the housing, characterized in that the electronic components (6, 7) on or in the heat-insulating housing (2, 3, 5) are arranged.

2. Battery according to claim 1, characterized in that between the material of the heat-insulating housing (2, 3, 5) and the electronic component (6, 7) a resilient intermediate layer is arranged.

3. Battery according to claim 1 or 2, characterized in that between the electronic components (6, 7) and the housing of the battery an elastic or soft plastic heat conduction layer is provided.

4. Battery according to one of the preceding claims, characterized marked, that the electronic component is an electric surface heating.

5. Battery according to one of the preceding claims, characterized in that the electronic component is a sensor.

6. A method of manufacturing a battery having a housing for receiving electrochemical components, a heat-insulating housing (2, 3, 5) and with electronic components (6, 7) in thermal contact with the housing, the method comprising the steps of : a. Providing the parts for the heat-insulating housing (2, 3, 5), wherein in these parts electronic components (6, 7) are integrated and at least partially interconnected, b. Inserting the electrochemical components into the housing, c. Sealing the case and d. Arranging the parts of the heat-insulating housing (2, 3, 5) on the housing and making contact with the intended terminals of the electronic components (6, 7) with the battery poles.

7. The method according to claim 6, characterized in that the parts form a unit for the bottom surface and the four side surfaces of the battery.

8. The method according to claim 7, characterized in that the parts for the bottom surface and the four side surfaces are connected to each other by means of foil joints.