DE102013001088B4 - Battery dummy - Google Patents

Abstract

Battery dummy, comprising a housing (2) which has the same dimensions as a comparison battery, characterized in that in this housing (2) at least one cell dummy (3), the dimensions of which correspond to a comparison cell, and at least one of the simulation of one by the The force generating element (14) and / or at least one heating element (7) serving to simulate a heating power generated by the operation of the comparison cell is arranged.

Description

The invention relates to a dummy battery comprising a housing which has the same dimensions as a comparative battery.

High-performance batteries are becoming increasingly important in the development of motor vehicles. This is particularly the case for the use of high-voltage batteries in hybrid vehicles and electric vehicles. Numerous test procedures are necessary as part of the development of these vehicles and batteries. Frequently, these test processes can only be carried out poorly when using conventional batteries, because on the one hand it is difficult to measure temperatures or pressures inside a battery and, moreover, the use of real batteries is dangerous when testing extreme situations.

The pamphlet U.S. 5,718,987 A describes a lead-acid battery with a housing and several cells. The battery comprises at least one electrochemically inactive cell, which is connected in series with the electrochemically active cells and is arranged between the electrochemically active cells. This allows a different voltage to be provided than is typically provided by batteries of the same size.

A test bench for electrical energy storage systems for vehicles is from the publication AT 509 249 A1 known. In order to be able to test energy storage systems as close to the application as possible, an actuator is provided for mechanical excitation of the energy storage system.

The pamphlet WO 2011/073426 A1 discloses an accumulator that has at least two cells that adjoin a cooling or heating element.

A battery with cooling of the battery cells according to the heat pipe principle is from the publication DE 10 2009 040 067 A1 known.

The pamphlet U.S. 3,822,585 A describes a test device to check the tightness of batteries.

A device for examining parts made of plastic, in particular battery housings, is disclosed in the publication EP 2 108 970 A1 disclosed.

The DE 10 2010 028 862 A1 suggests using a filler in a dummy battery cell instead of an electrolyte for test purposes which does not contain an electrolyte that is effective for the battery cell type. Although this can minimize dangers in test operation, it is still not possible to directly measure the pressure or temperature in the battery, and it is not possible to simulate the battery heating up or the exertion of force due to the work of the cell winding in the battery.

The invention is therefore based on the object of specifying a dummy battery which is improved in comparison.

The object is achieved according to the invention by a dummy battery of the type specified above, with at least one dummy cell, the dimensions of which correspond to a comparison cell, as well as at least one of the simulation of a force generated by the work of a cell coil of the comparison cell and / or at least one of the Simulation of a heating element generated by the operation of the comparison cell is arranged.

The invention is based on the idea of using one or more dummy cells in the battery. The geometric dimensions of these dummy cells correspond to a comparison cell. This makes it easy to replace individual cells or all cells of a battery with such dummy cells. It is essential here that the actual components of the dummy cell are initially insignificant for test purposes. The only important thing is that this dummy cell can behave outwardly like a real cell would. The most important property of a real battery, namely the storage of electricity, is not important for an installation experiment. It is therefore not necessary in the case of a dummy cell according to the invention that it can also store energy. Rather, it is essential that the heating output of a real battery, such as that generated when charging or discharging, can be simulated. At the same time or as an alternative, it is also advantageous if the forces that act inside a real battery are simulated. Above all, the work of the cell wrap should be mentioned here. A battery according to the invention can thus simulate the thermal behavior of a real existing battery and / or the forces generated in a real battery. The essential elements of the dummy battery according to the invention are therefore one or more force-generating elements for simulating a force generated by the work of a cell coil of the comparison cell and / or heating elements, which are used to simulate a heating output generated by the operation of the comparison cell.

It is particularly advantageous if the force-generating element or at least one of the force-generating elements is integrated into the dummy cell, and / or when the heating element or at least one of the heating elements is integrated into the dummy cell or is attached to this on the outside. This makes it particularly easy to produce different dummy batteries by replacing the cells of the real battery with dummy cells. If force-generating elements and / or heating elements are already integrated into the dummy cell, the dummy cell can also be used to test the structure of the comparison battery. This makes it easy to test whether the housing of the comparison battery can withstand the forces occurring in the battery and whether, for example, material fatigue occurs due to a large number of heating cycles.

It is also advantageous if at least one temperature sensor and / or at least one force sensor is arranged on the housing of the dummy battery. In this case, the thermal loads which act on the battery during the operation or the manufacture and maintenance of the motor vehicle can be easily measured. In this case it is also easily possible to measure the forces that act on the battery from the outside, for example during a crash test.

Here, too, it can be advantageous to integrate the temperature or force sensors into the individual cell mock-ups. When using normal batteries, no temperature or force measurements are possible, especially within cells. However, when working on the motor vehicle, such as welding, hot riveting or curing sealants, temperature increases can occur, which act on the battery from the outside. In this case it is important to measure the temperature that occurs inside the battery and especially the cell. For example, with lithium-ion batteries, too high a temperature can lead to outgassing, which leads to the risk of explosion. Thus, with the dummy battery according to the invention, potential temperature or force loads can be recognized and quantified as early as the test stage.

It is possible for the force exerted by the force-generating element to be adjustable. The power generation elements in the dummy battery serve to simulate the work of one or more cell rolls. The work that a cell coil does, however, depends on a number of factors. In order to be able to simulate a large number of load situations on the battery, it is therefore advantageous to be able to adjust the force generated.

In particular, the force exerted by the force-generating element can be adjustable by external hydraulic, pneumatic, electrical or mechanical control or radio control. With such an external control it is possible, for example, to test cyclical loads within a long-term measurement. In particular, if several force-generating elements are integrated in at least one of the dummy cells, any desired pressure points can be generated on the outer cell housing by different controls of the individual force-generating elements. Such different forces occur, for example, at the beginning of the life cycle of the cell (begin of life), at the end of the life cycle (end of life), in the event of thermal instability or when the cell is breathing during normal operation. In this case, it is possible to simulate limit loads on the cell, the battery and the surroundings of the battery, for example in a motor vehicle, as well as the effect of long-term loads caused by, for example, breathing of the cells during normal operation.

The control of the force generating elements is possible in many ways. If, for example, hydraulic force-generating elements are used, it can be advantageous to control them directly through hydraulic lines leading to the outside. The hydraulic lines can, for example, be arranged at the location of the pole pieces of the battery or, if the force-generating elements are integrated in dummy cells, at the locations of the poles of the dummy cell. The hydraulic control is particularly advantageous when the dummy battery is also to be used for thermal simulation and high temperatures, such as those reached in the event of thermal instability, are to be simulated. In this case it can be advantageous not to arrange any electronics inside the dummy battery, since very high temperatures are reached here. Alternatively, in such cases, mechanical control can also take place, for example via rotating rods and spreading elements. An electrical or radio control is particularly flexible, since no direct access from the outside is necessary or the control only takes place via a few signal lines.

The force generating element can be, for example, a spring element, a lifting cylinder or a piezo element. A mixture of different force-generating elements is of course also possible. Force generation by spring elements is particularly simple and allows simple mechanical adjustment. Lifting cylinders can be controlled particularly easily via hydraulics or pneumatics, but electromechanical lifting cylinders can also be used. Hydraulic or pneumatic lifting cylinders, in particular, can apply very high forces. If a particularly fine spatial resolution of the exertion of force is to be achieved and the depth of the stroke is not too great, it can also be advantageous to use piezo elements.

The dummy battery can have connections on the housing side for energizing the force-generating element or hydraulic connections of the Have force generating element. In this case, the connection and control of the force generating element is particularly simple.

When using a heating element in the dummy battery according to the invention, it is advantageous if the heating element is designed for external control of the temperature or the heating power of the heating element. In this case, temperature profiles that can occur when operating a real battery can easily be simulated. For example, long-term tests are conceivable that simulate a cyclical temperature load on the battery over several days, but also those that simulate the heat development of a battery during real driving loads in a certain motor vehicle on a certain route, for example when driving on a pass. Even with simulations of extreme situations, such as thermal instability, the development of the temperature over time can be simulated better in this case.

It is possible, for example, for the heating element to be designed as a flat heating element. In this case, the heating element can be glued onto the outside of at least one dummy cell, for example. However, it is also possible to integrate such a flat heating element into the walls of a dummy battery or into the walls of a dummy cell that is built into the dummy battery. With surface heating elements it is possible to heat the dummy battery evenly in a certain area. The flat heating element can be designed, for example, as a resistive surface that is energized or a meandering line that is integrated into a material with good thermal conductivity and that is energized.

In order to be able to simulate local heating of the dummy battery, it is advantageous if the heating element has several, in particular four, separate heating areas which are designed for separate energization. In this case, the advantages of a flat heating element, in particular the ease with which it can be integrated into or onto a dummy cell or a wall of the dummy battery, can still be used, with more differentiated heating of the dummy battery being possible.

It is advantageous if the heating element is designed to heat the dummy battery to an operating temperature of the comparison battery or to temperatures which the comparison battery reaches in the event of thermal instability. A real battery can reach very high temperatures, particularly in the event of thermal instability. The behavior of the battery and the effect on the environment of the battery, for example in a motor vehicle, are safety-relevant information that must be taken into account when developing a motor vehicle or a battery. It is therefore particularly advantageous if the dummy battery can also be used to simulate thermal instability in addition to heating to normal operating temperatures of a battery. High temperatures and pressures can occur here. So a powerful heating element is necessary.

It is possible for the dummy battery to have connections on the housing side for energizing the heating element. The poles of the dummy battery can be used particularly easily here. In this case, the heating element can be supplied for simulation purposes inside a motor vehicle, for example, by cables that are already present. Even in the case in which several connections are necessary, for example in order to separately energize a plurality of heating elements, leading the connections out to the housing of the dummy battery facilitates the connection of the same.

In many cases, the dummy battery according to the invention is intended to simulate strong temperature changes within a short period of time. For example, a battery should be manageable relatively soon after the simulation of a thermal instability. It can also be useful, especially for material tests, to simulate rapid changes between heating up by the battery and cooling down again. It is therefore advantageous if the housing comprises at least one cooling device which is designed to cool the dummy battery. To simulate the temperature behavior of individual cell rolls, it is also possible for the cooling device or at least one of the cooling devices to be arranged in the dummy cell or at least one of the dummy cells.

This makes it possible, for example, to test the thermal instability of individual cells within a short time interval. In addition, cyclical tests with different temperature behavior of the individual cells can be carried out here.

High-performance batteries, which in particular require rapid charging and discharging, and thus generate a lot of heat, are used primarily in motor vehicles. The use of high-density energy stores, especially in motor vehicles, is also particularly relevant to safety. It is therefore advantageous if the dummy battery is designed to replace the comparison battery of a motor vehicle, in particular a high-voltage battery.

• 1 ein Ausführungsbeispiel einer erfindungsgemäßen Batterieattrappe,
• 2 eine Zellattrappe eines weiteren Ausführungsbeispiels einer erfindungsgemäßen Batterieattrappe,
• 3 eine geschnittene Ansicht der Zellattrappe aus 2,
• 4 eine schematische Darstellung eines Heizelements einer Zellattrappe eines dritten Ausführungsbeispiels einer erfindungsgemäßen Batterieattrappe,
• 5 eine schematische Darstellung einer Zellattrappe eines vierten Ausführungsbeispiels einer erfindungsgemäßen Batterieattrappe,
• 6 eine geschnittene Ansicht der Zellattrappe aus 5,
• 7 eine Detailansicht der Zellattrappe aus 5, und
• 8 eine Zellattrappe eines fünften Ausführungsbeispiels einer erfindungsgemäßen Batterieattrappe.

Further advantages and details of the present invention emerge from the im Embodiments described below and with reference to the drawings. Show:

• 1 an embodiment of a dummy battery according to the invention,
• 2 a dummy cell of another embodiment of a dummy battery according to the invention,
• 3 a sectioned view of the dummy cell 2 ,
• 4th a schematic representation of a heating element of a dummy cell of a third embodiment of a dummy battery according to the invention,
• 5 a schematic representation of a dummy cell of a fourth embodiment of a dummy battery according to the invention,
• 6th a sectioned view of the dummy cell 5 ,
• 7th a detailed view of the dummy cell 5 , and
• 8th a dummy cell of a fifth embodiment of a dummy battery according to the invention.

1 shows a schematic representation of a dummy battery. The battery dummy 1 has a battery case 2 that has the same dimensions as a comparison battery. Here is as a battery case 2 the battery dummy 1 a case of a comparison battery used. The cells of the comparison battery are made up of four dummy cells 3 replaced. The connections are at the points at which the comparison cells of the comparison battery have their poles 4th the cooling of the individual cell mockups arranged. This can be used to cool the dummy cell, for example using compressed air. This enables particularly rapid changes in the temperature of the cell. This can, for example, reduce the thermal instability of various dummy cells within a short time interval 3 inside the battery case 2 can be simulated. Furthermore, the cell dummies show 3 one connection each 5 on. About the connection 5 the force-generating elements and heating elements, not shown, are energized and controlled.
In this case, the force generating elements are designed as piezo elements and the heating elements as in the vicinity of the cell wall 6th arranged resistive heating elements.

2 shows a sectional view of one of the dummy cells 1 . To improve the overview, in 2 and 3 only the heating and cooling system of the dummy cell 3 shown. The piezo elements arranged between the walls for generating forces are not shown.

The dummy cell 3 is like that in the battery case 2 arranged that the connections of the cooling system 4th which correspond to the poles of a conventional cell are led to the outside. In the battery case 2 is also an opening for the cable to pass through 9 that is about the connector 5 the heating elements 7th and energizes and controls the piezo elements, not shown. The heating elements 7th are via the power supply lines 8th with the connector 5 connected. The heating elements 7th are designed as surface heating elements and on the cell wall 6th arranged. In addition to the connections 4th The openings are also used for cooling 10 the cooling. This is in 3 shown in detail.

3 shows schematically the structure of the cooling device of the dummy cell 3 .
The cooling device is as a system of piping 11 formed inside the dummy cell. As already described, there are connections at the positions of the poles 4th arranged for compressed air. To efficiently cool the dummy cells 3 Accessible from inside and outside includes the dummy cell 3 also openings of the cooling device 10 to the inside of the battery case 2 . So gets cool air over the connector 4th supplied, it runs through the pipelines on the one hand 11 to the housing of the dummy cell 3 to cool, and thus cools the heating elements 7th from behind. On the other hand, the cool air is also in the housing 2 the battery swirls and cools the one on the wall 6th the dummy cell 3 arranged heating elements 7th also directly.

4th shows a further exemplary embodiment of a dummy battery in which the heating element is designed as a sheet-like surface heating element with four heating areas. The battery dummy 1 contains a dummy cell here 3 . On each of the two cell walls 6th is a heating element 7th glued. The heating element 7th is made here separately in the form of a thin film with several power connections and then on the walls 6th the dummy cell 3 glued. The foil-like heating element 7th has four heating areas 12th on. Each of these heating areas is a conductive area on the overall non-conductive carrier material of the heating element 7th upset. The four heating areas 12th each of the two heating elements 7th are each separate by the power supply 13th can be energized. The dummy cell 3 thus has a total of eight heating areas, each of which is separately energized and thus separately heatable.

5 shows schematically the arrangement of five force generating elements 14th in a dummy cell 3 that are in a battery case 2 is arranged. The five force generating elements 14th are designed here as electromechanical force generating elements. Through the control lines 16 can through the force generating elements 14th perpendicular to the cell wall 6th forces exercised 15th for each of the force generating elements 14th can be set separately. The control takes place here via a radio control. The force generating elements 14th are fed from an energy source integrated in the dummy cell and can be controlled by receiving Bluetooth signals, for example. With this type of control and energy supply, using a dummy battery that is constructed from dummy cells of this type is particularly simple.

6th shows a sectioned view of the dummy cell 5 . The dummy cell 3 has several force generating elements in its interior 14th on. These are designed here as electromechanical lifting cylinders. The control of the electromechanical lifting cylinder 14th is done by the control device 23 , which receives control instructions by radio and receives the electromechanical lifting cylinder via an integrated energy supply 14th feeds. You can also click on the surface 6th the dummy cell 3 still heating elements 7th be applied, also by the control device 23 can be fed and controlled. In the cell wall 6th Temperatures and force sensors (not shown) are also integrated.

This is in 7th , a detailed view of a wall section of the dummy cell 6th shown. The heating element is on the outside of the cell wall 7th arranged, which is formed on a film as a carrier material and comprises a plurality of heating areas that can be powered independently. On the inside of the cell wall 6th there are also two additional, flat components. On the one hand there is a temperature measuring foil 17th arranged that has multiple areas that can measure temperatures. This can be used as an alternative to or at the same time as the heating foil 7th be used. Simultaneous use with the heating foil allows, above all, the determination of the actual temperature reached. In addition, the temperature measuring film 17th can also be used to detect the heat input from external processes, such as welding near the battery. Next to the temperature measuring foil 17th is on the cell wall 6th also a pressure measuring film 18th arranged the forces between the cell wall 6th and the plate 19th detected. Also this pressure measuring film 18th has a double meaning. On the one hand, the forces generated by the lifting cylinder 14th on the plate 19th exerted, can be measured, on the other hand, external forces that act on the cell dummy can be detected.

If a dummy battery is built from the dummy cells described here, it is possible to simultaneously or alternatively control the temperature for several areas of a dummy cell, to measure the temperature in several areas, and to exert and measure forces on or through the dummy cells. It is therefore possible both to simulate the forces and temperatures generated by the operation of the battery and to detect the forces exerted on a battery and the effects of external temperatures. This means that a large number of measurement and test scenarios can be carried out with such a dummy battery.

8th Figure 3 shows an alternative embodiment of a dummy cell of a dummy battery. Here is the force acting on the cell wall 6th the dummy cell 3 is exercised, hydraulically controlled. About the connection 23 can be the pressure inside the pressure vessel 21st can be varied. Will the pressure in the pressure vessel 21st so increases the pole 22nd to the right towards the cell wall 6th pushed. This creates a force between the first plate 19th and the second plate 20th exercised. In this case, this can be done by simply varying the air pressure at the connection 23 those on the cell wall 6th applied force can be varied. The connection 23 is here again in the same place as a pole would be in a conventional cell.

Claims (15)

Battery dummy, comprising a housing (2) which has the same dimensions as a comparison battery, characterized in that in this housing (2) at least one cell dummy (3), the dimensions of which correspond to a comparison cell, and at least one of the simulation of one by the Force generating element (14) and / or at least one heating element (7) serving to simulate a heating power generated by the operation of the comparison cell is arranged. Battery dummy after Claim 1 , characterized in that the at least one force-generating element (14) is arranged in the housing (2), the force-generating element (14) or at least one of the force-generating elements (14) being integrated into the dummy cell (3), and / or that in the Housing (2) the at least one heating element (7) is arranged, the heating element (7) or at least one of the heating elements (7) being integrated into the dummy cell (3) or being attached to the outside of the latter. Battery dummy after Claim 1 or 2 , characterized in that at least one temperature sensor (17) and / or at least one force sensor (18) is arranged in or on the housing (2). Battery dummy according to one of the preceding claims, wherein the at least one force-generating element (14) is arranged in the housing (2), characterized in that the exerted force of the force generating element (14) is adjustable. Battery dummy after Claim 4 , characterized in that the force exerted by the force-generating element (14) can be adjusted by external hydraulic, pneumatic, electrical or mechanical control or radio control. Battery dummy according to one of the preceding claims, the at least one force-generating element (14) being arranged in the housing (2), characterized in that the force-generating element (14) is a spring element, a lifting cylinder or a piezo element. Battery dummy according to one of the preceding claims, wherein the at least one force-generating element (14) is arranged in the housing (2), characterized in that the battery dummy (1) has connections for energizing the force-generating element (14) or hydraulic connections of the force-generating element (14) on the housing side . Battery dummy according to one of the preceding claims, wherein the at least one heating element (7) is arranged in the housing (2), characterized in that the heating element is designed for external control of the temperature or the heating power of the heating element (7). Battery dummy according to one of the preceding claims, wherein the at least one heating element (7) is arranged in the housing (2), characterized in that the heating element (7) is designed as a flat heating element. Battery dummy after Claim 8 , characterized in that the heating element (7) has several, in particular four, separate heating areas (12) which are designed for separate energization. Battery dummy according to one of the preceding claims, wherein the at least one heating element (7) is arranged in the housing (2), characterized in that the heating element (7) for heating the battery dummy (1) to an operating temperature of the battery to be replaced or to temperatures , which reaches the comparison battery in the event of thermal instability, is formed. Battery dummy according to one of the preceding claims, wherein the at least one heating element (7) is arranged in the housing (2), characterized in that the battery dummy (1) has connections on the housing side for energizing the heating element (7). Battery dummy according to one of the preceding claims, characterized in that the housing (2) comprises at least one cooling device which is designed to cool the battery dummy (1). 14. Battery dummy after Claim 13 , characterized in that the cooling device or at least one of the cooling devices is arranged in the dummy cell (3) or at least one of the dummy cells (3). Battery dummy according to one of the preceding claims, characterized in that the battery dummy (1) is designed to replace the comparison battery of a motor vehicle, in particular a high-voltage battery.

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