DE102018214748A1 - Battery system with fans in the battery cell holder and method for homogeneous temperature distribution within the battery system - Google Patents

Abstract

Battery system (200) with a battery housing, which comprises a base body (201), a first cover element (202) and a second cover element (203), the first cover element (202) closing a first open end face of the base body (201) and the second Covering element (203) closes a second open end face of the base body (201), a battery cell holder (204) which has battery cell receiving spaces for a plurality of battery cells (205), the battery cell holder (204) having the plurality of battery cells (205) and the battery cell holder (204) is arranged within the battery housing, and a battery management system (109), which is set up to monitor the plurality of battery cells (205) and to record temperatures of the individual battery cells (205), characterized in that the battery cell holder (204) at least a first fan receiving space with a first fan (206) and a second fan receiving room with a second fan (207), the first fan (206) and the second fan (207) having different flow directions, the first fan and the second fan depending on a threshold value violation of the temperature of the individual battery cells (205) by the battery management system (109) can be controlled.

Description

State of the art

The invention relates to a battery system with fans within a battery cell holder and a method for homogeneous temperature distribution within the battery system.

Batteries for mobile applications usually include a large number of battery cells. These battery cells are limited in terms of voltage and permissible currents. In order to achieve the total voltage and total capacity of the battery required for a given application, the individual battery cells are connected in a certain way. A serial connection increases the required total voltage and a parallel connection increases the required total capacity as well as the permissible total currents.

To achieve the highest possible energy density, individual battery cells are arranged close together in a battery cell network. During operation, each individual battery cell has a certain power loss. This power loss is given off in the form of waste heat in the interior of the battery housing. Since the waste heat can be dissipated to the environment at different locations in the battery, there is an inhomogeneous temperature distribution within a closed battery housing.

The disadvantage here is that the performance of the battery and its lifetime are impaired.

The individual battery cells can only be operated safely up to a certain temperature. The individual battery cells must not exceed this specific temperature neither for the charging process nor for the discharging process in order to ensure the safety of the battery. If the certain temperature is reached by a battery cell during the discharge process, the discharge current of the battery is throttled. If the battery is in charging mode, the charging process is only started if the current temperature of the battery cells is below the specified temperature.

Due to the inhomogeneous temperature distribution, only individual battery cells are in the range of the limit temperature of the permissible operation, while other battery cells have moderate operating temperatures. However, the battery management system throttles the performance of the entire battery as soon as a battery cell is in the critical range of the limit temperature.

The disadvantage here is that the battery power is reduced early.

The operating temperature also plays an important role in the life of a battery cell. A battery cell ages very quickly at high operating temperatures. Due to the inhomogeneous temperature distribution within the closed battery housing, the battery cells that have a lower operating temperature age significantly more slowly than battery cells that have a high operating temperature. Since the battery cells in such a battery cell group are not exchangeable or are exchangeable, the entire battery is put out of operation as soon as a certain number of battery cells have reached the end of their life. At this point, however, all other or further battery cells could still be operated safely for a while.

Various types of cooling are known in order to overcome these disadvantages. In most cases, air cooling or liquid cooling is used. For this purpose, air is drawn in from the surroundings with the aid of a blower and passed over the battery cells. The sucked-in air is heated by the waste heat from the individual battery cells and, after passing through the battery cell assembly, exits the battery housing through an outlet opening. The heat is thus released to the environment.

The document US 2003198864 A1 describes an electrochemical battery that includes a battery case with a plurality of battery cells and a central fan. With the help of the fan, an air flow is generated between an air inlet opening of the battery housing and an air outlet opening of the battery housing, which is passed over the battery cells, thereby regulating the battery cell temperature.

The document US 2013149583 A1 discloses a battery system with a plurality of electrical cells, a battery case and a fan. A region of the battery housing, which is arranged below the battery cells, comprises an inlet opening for air. The side walls and an area of the battery housing above the battery cells have outlet openings for the air.

It is disadvantageous in both documents that inlet openings and outlet openings for the air have to be inserted into the battery housing. Another disadvantage is that the battery case will leak.

The object of the invention is to overcome these disadvantages.

Disclosure of the invention

A battery system comprises a battery housing with a base body, a first cover element and a second cover element. The first cover element closes a first open end face of the base body and the second cover element closes a second open end face of the base body. In other words, the battery housing is hermetically sealed from the environment. The battery system comprises a battery cell holder which has battery cell receiving spaces for a plurality of battery cells, the battery cell holder having the plurality of battery cells and the battery cell holder being arranged within the battery housing. The battery system comprises a battery management system which is set up to monitor the large number of battery cells and to record temperatures of the individual battery cells. According to the invention, the battery cell holder has at least one first fan receiving space with a first fan and at least one second fan receiving space with a second fan, the first fan and the second fan having different flow directions. The first fan and the second fan are controlled by the battery management system as a function of the temperature of the individual battery cells being exceeded. In other words, the temperature redistribution takes place within the closed battery housing by a circulating air movement of the heat generated in the battery or the battery system.

The advantage here is that the waste heat generated by the operation of the battery cells is homogeneously redistributed within the battery and the homogeneously distributed heat is released to the environment through the surface of the housing, so that the individual battery cells age evenly and the battery power is only throttled after a longer operating time . This means a medium-fast heating of all battery cells instead of a rapid heating of the battery center and a slow heating in the peripheral areas. In addition, an improved temperature distribution or rapid cooling of the battery leads to the battery quickly entering a charge-capable state. Furthermore, it is advantageous that no openings for the inlet and outlet of a cooling fluid are required. In addition, neither evaporators nor condensers are required, which means that the overall system is light and inexpensive. The battery system is therefore also suitable for small battery applications such as 48V systems. Furthermore, it is advantageous that the arrangement is space-neutral compared to a battery housing with a battery cell holder without a fan, since the fans are arranged within the battery cell holder.

In one development, the first fan is arranged in the vicinity of the first cover element and the second fan is arranged in the vicinity of the second cover element.

It is advantageous here that the air circulation within the battery housing takes place from the front cover area, which has a high temperature, to the rear area of the battery housing, which has cooler temperatures, and as a result, the hot air is redistributed from front to back inside the battery housing. This means that the warm air can circulate well within the battery housing.

In one development, the first fan and the second fan are each an axial fan.

It is advantageous here that the fans fit snugly into the receiving spaces of the battery cell holder.

In a further embodiment, the battery cell receiving spaces and the at least one first fan receiving space and the at least one second fan receiving space have the same dimensions.

The advantage here is that the battery cell holder for the fans does not have to be changed.

In a further embodiment, the second cover element has at least one further fan. In other words, the at least one further fan is arranged on the second cover element within the battery housing.

The advantage here is that the at least one additional fan is limited only by the size of the second cover element. Large volume flows can therefore be generated.

In one development, the base body is a continuous cast element.

It is advantageous here that the battery housing is manufactured in a simple and inexpensive manner.

In a further embodiment, the battery housing comprises metal, in particular aluminum.

The advantage here is that the homogeneously distributed heat within the battery housing quickly through the thermally conductive surface of the base body to the outside, ie. H. outside the battery housing, can be dissipated.

The inventive method for homogeneous temperature distribution within a Battery system, the battery system having a battery housing, a battery cell holder with battery cell receiving spaces for a plurality of battery cells and a battery management system which is set up to monitor the plurality of battery cells and to record temperatures of the individual battery cells, and the battery cell holder has at least one first fan receiving space with a first one Has fan and at least one second fan receiving space with a second fan, that the first fan and the second fan are controlled by the battery management system as a function of a threshold value violation of the temperature of the individual battery cells.

The use of the battery system according to the invention takes place in an electric vehicle, in particular an electrically operated two-wheeler.

The vehicle according to the invention, in particular an electrically operated two-wheeler, has the battery system according to the invention.

Further advantages result from the following description of exemplary embodiments or the dependent patent claims.

Figure list

• 1 eine Draufsicht auf eine Temperaturverteilung eines Batteriesystems mit einer Vielzahl von Batteriezellen, die seriell und parallel zueinander verschaltet sind,
• 2 ein erstes Ausführungsbeispiel eines Batteriesystems mit mindestens zwei Lüftern,
• 3 ein zweites Ausführungsbeispiel eines Batteriesystems mit sechs Lüftern, und
• 4 ein Verfahren zur homogenen Temperaturverteilung innerhalb eines Batteriesystems mit mindestens zwei Lüftern.

The present invention is explained below on the basis of preferred embodiments and attached drawings. Show it:

• 1 1 shows a plan view of a temperature distribution of a battery system with a large number of battery cells which are connected in series and in parallel with one another,
• 2 a first embodiment of a battery system with at least two fans,
• 3 a second embodiment of a battery system with six fans, and
• 4 a method for homogeneous temperature distribution within a battery system with at least two fans.

1 shows a top view of an exemplary temperature distribution of a 48 V supplying battery system 100 with a variety of battery cells 105 , The battery system comprises thirteen rows of fifteen battery cells each connected in parallel 105 that form a battery cell network. Every battery cell 105 supplies a voltage of approx. 3.6 V, so that the battery can supply a total voltage of 48 V. Due to the tight arrangement of the battery cells 105 result from the operation of the battery system 100 due to the waste heat emitted by the individual battery cells, different temperature ranges within the 1 battery housing, not shown.

Examples are in 1 first temperature ranges 120 , a second temperature range 121 , a third temperature range 122 and fourth temperature ranges 123 shown. The first temperature ranges 120 have a lower temperature than the second temperature range 121 and the third temperature range 122 , The fourth temperature ranges 123 are the coldest. The reason for this is that the battery cells 105 , which are arranged at the edge of the battery cell assembly, can release the waste heat to the battery housing faster than the battery cells 105 , which are arranged inside the battery cell network. The battery management system 109 also acts as a heat source.

2 shows a battery system 200 with a battery case that has a main body 201 , a first cover element 202 and a second cover element 203 includes. The first cover element 202 closes a first open face of the base body 201 and includes a battery management system, not shown here, the second cover element 203 closes a second open face of the base body 201 , The battery housing thus forms a closed space, which serves as a receiving space for a battery cell holder 204 acts. The battery housing is thus sealed from the environment or sealed airtight. The battery cell holder 204 does not completely fill the receiving area of the battery housing. That means the battery case and the battery cell holder 204 are spaced from each other parallel to the end faces. In other words, there are empty spaces or cavities above and below the battery cell holder accommodated in the battery housing. The battery cell holder 204 has battery cell receiving spaces for a variety of battery cells 205 on, with a variety of battery cells 205 are arranged in the battery cell receiving spaces. The battery cell holder 204 has at least a first fan receiving space for first fans 206 and at least one second fan receiving space for second fans 207 on. The first fan 206 is inside the first fan receiving space and the second fan 207 arranged within the second fan receiving space. The first fan 206 and the second fan 207 are, for example, axial fans. The first fan 206 and the second fan 207 have different flow directions, so that the heat or warm air through the battery cell holder 204 can circulate. A circulation of the warm air is thus made possible by the fact that the air is mainly through the fans themselves through the battery cell holder 204 flow from top to bottom and back. This can also support circulation be that between the first cover member 202 and the battery cell holder 204 , as well as between the battery cell holder 204 and the second cover element 203 There is free space for air circulation through damping materials arranged at this point. The circulating air movement within the battery housing can thus be optimized. The air flow represents a pure circulation of the air inside the battery. As a result, the warm air inside the battery is exchanged between areas of high and low temperature, so that the different temperature areas within the battery are equalized. In other words, the waste heat from the battery cells 205 is redistributed within the battery. In order to be able to improve the distribution of the heat, additional battery cell receiving spaces of the battery cell holder are provided 204 released, ie no battery cells are inserted into these battery cell receiving areas. These are, for example, battery cell receptacles that are spatially close to the first fan 206 and the second fan 207 are located. As an alternative or in addition, the battery cell holder can have air channels between the individual battery cells 205 in the battery cell holder 204 are arranged so that an optimal flow around the individual battery cells 205 he follows. These air ducts can only be used at the locations of the battery cell holder 204 be present at which the operating temperature of the battery cells 205 is very high, for example in the 1 shown third temperature range 122 , Alternatively or additionally, a further fan can be placed on the second cover element 203 be arranged.

The circulation is in with arrows 2 inside the battery case by the battery cell holder 204 and along the body 201 shown. The temperatures within the battery housing are recorded, for example, by means of NTCs at various points in the battery cell network. The first fan 206 and the second fan 207 are from the battery management system 209 depending on whether the temperature of the battery cells is exceeded 205 controlled. Due to the circulation, the air is guided along the base body of the battery housing, so that the redistributed heat is passively emitted via the surface of the battery housing.

3 shows a second embodiment of a battery system 300 , The structure of the battery system 300 is the structure of the battery system 200 out 2 similar. Functionally identical components 3 have the same two rear positions of the reference symbols as the reference symbols 2 , The battery system 300 shows a battery cell holder 304 with battery cell receptacles for a variety of battery cells 305 and first fan receiving spaces for a variety of first fans 306 . 308 and 309 and second fan receiving spaces for a plurality of second fans 307 . 310 and 311 , In 3 six fans are shown, with the first fans 306 . 308 and 309 and the second fan 307 . 310 and 311 have a different flow direction.

In one exemplary embodiment, the battery cell receiving spaces, the first fan receiving spaces and the second fan receiving spaces have the same dimensions. This means that instead of battery cells, fans are arranged at some points on the battery cell holder. Due to this design, the volume flows of the warm air are low and the dimensions of the fans are comparable to the size of a battery cell 305 , A plurality of battery cell receiving areas are therefore preferably left free, ie without a battery cell 305 and the first fan instead 306 . 308 and 309 and second fan 307 . 310 and 311 used. In one embodiment, there are first fans 306 . 308 and 309 and a second fan 307 . 310 and 311 arranged in pairs along the base body at a distance within a battery cell series circuit, the first fan is preferably arranged in the vicinity of the first cover element and the second fan is arranged in the vicinity of the second cover element. The direction of circulation of the warm air is on the top of the battery cell holder using arrows 304 shown. The removal of individual battery cells 305 from a parallel row leads to a higher load on the other battery cells 305 within the parallel row, since the same total current is on fewer battery cells 305 distributed. Furthermore, ohmic losses increase due to the internal resistance of the battery cells to the battery cell current squared, so that the heat development in the remaining battery cells increases. This effect is stronger the shorter the parallel row.

To reduce this effect, a first fan is used in a further exemplary embodiment 306 . 308 and 309 and a second fan 307 . 310 and 311 arranged in different battery cell series connections. This means that there is only one battery cell per parallel row 305 away.

The basic body 201 and 301 The battery housing is designed in one piece and tubular and has a metal. The metal can comprise aluminum or manganese, for example. The basic body 201 and 301 can be manufactured using a continuous casting process.

The invention can also be used at the module level, with the battery cells being replaced by battery modules. The fan is arranged within the individual battery modules, each of which has its own housing.

Another embodiment includes the installation of a fan at the battery pack level, which homogenizes the temperature of the individual battery modules. In this case, the battery cell holder must be replaced by a receiving element for battery modules or be configured in such a way that it can accommodate battery modules.

The battery system is used, for example, in an electrically operated two-wheeler. Furthermore, the battery system can also be used in stationary devices, e.g. B. in house buffers.

4 shows a process 400 for homogeneous temperature distribution within a battery system with at least one first fan and at least one second fan, which are arranged inside the battery cell holder instead of battery cells. The procedure 400 starts with the step 410 in that the battery management system detects temperatures between the individual battery cells. In a subsequent step 420 it is checked whether one of the temperatures of the battery cells exceeds a certain threshold. The determined threshold value is, for example, a maximum permissible operating temperature or limit temperature of the battery cell specified by the manufacturer of the battery cell. Alternatively, it can also be specified by the battery management system for the current operating state of the battery, ie charging or discharging. The specific threshold value for the charging process is 40 ° C and the specific threshold value for the unloading process is approximately 60 ° C. If the certain threshold is reached, a subsequent step will be taken 440 the first fan and the second fan are driven with different flow directions. If not, the process continues with the step 410 continued.

If the battery system has more than two fans, in one step 430 on the crotch 420 follows that determines the area of the battery cell network affected by the temperature threshold being exceeded. In the next step 440 All fans are activated that are closest to this affected area or that can redistribute the waste heat as quickly as possible. Here, fans are operated simultaneously in both the hotter and the colder areas, so that a high temperature gradient is created, which leads to rapid cooling or homogenization of the temperature distribution within the battery system.

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• US 2003198864 A1 [0010]
• US 2013149583 A1 [0011]

Claims (10)

Battery system (200) with • a battery housing, which comprises a base body (201), a first cover element (202) and a second cover element (203), the first cover element (202) closing a first open end face of the base body (201) and the second cover element (203) closes a second open end face of the base body (201), • a battery cell holder (204) which has battery cell receiving spaces for a plurality of battery cells (205), the battery cell holder (204) having the plurality of battery cells (205) and the battery cell holder (204) is arranged within the battery housing, and • a battery management system (109), which is set up to monitor the plurality of battery cells (205) and to record temperatures of the individual battery cells (205), characterized in that • the battery cell holder (204) at least a first fan receiving space with a first fan (206) and a two th fan receiving space with a second fan (207), the first fan (206) and the second fan (207) having different flow directions, the first fan and the second fan depending on a threshold value exceeding the temperature of the individual battery cells (205) from Battery management system (109) can be controlled. Battery system (200) after Claim 1 , characterized in that the first fan (206) is arranged in the vicinity of the first cover element (202) and the second fan (207) is arranged in the vicinity of the second cover element (203). Battery system (200) according to one of the Claims 1 or 2 , characterized in that the first fan (206) and the second fan are axial fans (207). Battery system (200) according to one of the preceding claims, characterized in that the battery cell receiving spaces and the at least one first fan receiving space and the at least one second fan receiving space have the same dimensions. Battery system (200) according to one of the preceding claims, characterized in that the second cover element (203) has at least one further fan. Battery system (200) according to one of the preceding claims, characterized in that the base body (201) is a continuous casting element. Battery system (200) according to one of the preceding claims, characterized in that the battery housing comprises metal, in particular aluminum. Method (400) for homogeneous temperature distribution within a battery system, the battery system having a battery housing, a battery cell holder with battery cell receiving spaces for a plurality of battery cells and a battery management system, the battery cell holder having the plurality of battery cells and the battery cell holder being arranged within the battery housing and the battery management system The plurality of battery cells is set up to monitor and to record temperatures of the individual battery cells, characterized in that the battery cell holder has at least one first fan receiving space with a first fan and at least one second fan receiving space with a second fan, the first fan and the second fan depending on whether the temperature of the individual battery cells is exceeded by the battery management system. Use of a battery system (400) according to one of the Claims 1 to 7 in an electric vehicle, especially an electrically operated two-wheeler. Vehicle, in particular an electrically operated two-wheeler, with a battery system (400) according to one of the Claims 1 to 7 ,

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