DE202019101393U1 - Calorimeter and measuring arrangement with such a calorimeter - Google Patents

Abstract

Calorimeter (12) for determining a heat flow between an accumulator (14), in particular a pouch cell or a prismatic cell, and its surroundings, with (a) a first calorimeter unit (12.1) comprising (i) a first receptacle (16.1) for the Accumulator (14), (ii) a first temperature control device (18.1), which is designed for tempering to a predeterminable temperature (T), and (iii) a first heat flow meter (20) for measuring a heat flow between the first receptacle (16.1) and the first temperature control device (18.1), and (b) at least one second calorimeter unit (12.2), (i) a second receptacle (16.2) for the accumulator (14), (ii) a second temperature control device (18.2) which is formed for tempering to a predeterminable temperature (T), and (iii) a second heat flow meter (20) for measuring a second heat flow between the second receptacle (16.2) of the second temperature control device (18.2).

Description

The invention relates to a calorimeter for determining a heat flow between an accumulator, in particular a pouch cell or a prismatic cell, and its surroundings. Such calorimeters are used to determine the properties of accumulators.

Accumulators, in particular those used for electric vehicles, must be protected against so-called thermal runaway. Thermal runaway refers to the process of failure of a galvanic cell of the battery, which causes the galvanic cell to become highly hot. As a result of this heating, adjacent galvanic cells of the accumulator fail, so that the number of failing galvanic cells increases with time. There is therefore a chain reaction that releases large parts of the energy content stored in the accumulator within a short time. In this case, the accumulator is at least partially destroyed. Depending on the structure of the accumulator, it may also lead to the release of toxic gases. Consequently, this scenario must be prevented with the greatest possible probability.

In order to avoid thermal runaway, the operating parameters are determined in preliminary tests, in which the accumulator works safely. For this purpose, the accumulator is charged or discharged, for example, with a predetermined current and measured the heat output of the accumulator to its environment. For this purpose, calorimeters are used.

Since it is to be tested, for example, up to which charging and / or discharging currents an accumulator can be safely operated, it can lead to the destruction of the accumulator. Therefore, calorimeters have been proposed that are built so robust that even a damaged accumulator does not lead to the destruction of the calorimeter. However, sufficiently robust calorimeters have the disadvantage that the achievable measurement accuracy is lower.

The invention has for its object to propose an improved calorimeter for accumulator.

The invention solves the problem by a calorimeter for determining a heat flow between an accumulator, in particular a pouch cell or a prismatic cell, and its surroundings with (a) a first calorimeter unit comprising (i) a first receptacle for the accumulator, (ii) a first tempering device, which is aligned for tempering to a predeterminable temperature, and (iii) a first heat flow meter for measuring a heat flow between the first receptacle and the first temperature control, and (b) at least a second calorimeter unit, which (i) a second receptacle for the accumulator, (ii) a second tempering device, which is designed for tempering to a predeterminable temperature, and (iii) a second heat flow meter for measuring a second heat flow between the second receptacle and the second tempering device.

An advantage of such a calorimeter is that it can be modular, so that accumulators of different sizes can be easily measured with it. By juxtaposing two or more calorimeter units, a large intake for the accumulator can be made.

The modularization in turn allows mass production, which makes the calorimeter particularly favorable. It can therefore be accepted if batteries are at risk, as the concomitant loss of the calorimeter is easier to tolerate. Despite the modularization, a high measurement accuracy is usually achievable.

It is also advantageous that the modular design allows the accumulator to be measured, which is, for example, a pouch cell, to be arranged between the two calorimeter units with thermal contact to both. In other words, the accumulator is then sandwiched between the two calorimeter units. As a result, higher measurement accuracy can be achieved in many cases.

It is also advantageous that the size of the recording can be adjusted by combining three or more calorimeter units to the size of the accumulator. Since any mismatch can cause measurement errors, a high measurement accuracy can often be achieved with the calorimeter according to the invention.

In the context of the present description, the feature that the calorimeter is designed to determine the heat flow between the accumulator and its surroundings means that the calorimeter is not only theoretically capable of doing so, but constructed in such a way that such a measurement can be made with a measurement accuracy of preferably better than 3%.

The recording is understood to mean, in particular, a structure which is designed for bringing it into contact with the accumulator. Preferably, the receptacle has a receiving surface which extends along a plane. Under the feature that In particular, if the support surface extends along the plane, it is understood that it is possible, but not necessary, for the receiving surface to extend along the plane in a strictly mathematical sense. Rather, it is possible that the receiving surface is not ideal flat, but has a shape deviation. For example, deviations of up to 1 millimeter from ideal flatness are possible.

The tempering device is understood to be a device by means of which a part of the calorimeter unit can be brought to a predeterminable temperature. The heat flow meter is arranged in the heat flow between the receptacle and the temperature control device. If, for example, the accumulator discharges heat to its surroundings, it flows - at least predominantly - through the heat flow meter into the temperature control device. It should be noted that in the following the case is usually treated that heat from the accumulator flows into the temperature control. Of course, in any case, the measurement of the heat flow in the reverse direction is possible and meant.

It is favorable if the first calorimeter unit is identical in construction to the second calorimeter unit. By this is meant in particular that both have the same structure.

It is cheap, but not necessary, if both calorimeter units are constructed identically. However, it is also possible that the two calorimeter units differ in technically not relevant features and / or that they differ insignificantly in technically relevant features. Thus, two calorimeter units, which are identically constructed but have different colors, are considered identical. In addition, it is possible that two identical Kalorimetereinheiten differ in the location of the connecting cables. It is only relevant that the calorimeter units can be produced in a technically identical manufacturing process.

Preferably, the first calorimeter unit and the second calorimeter unit are mechanically connected to one another, so that the first receptacle and the second receptacle complement one another to form an overall receptacle. It is possible, but not necessary, for the calorimeter units to be connected directly adjacent to one another. Alternatively, it is possible that a spacer is arranged between two adjacent calorimeter units. The spacer is preferably designed such that a heat flow through it is at most 3%, in particular at most 1%, of the total heat flow.

The overall receptacle preferably extends along a plane. In this way, two, three, four or more calorimeter units can be combined to form a total unit or part of a total unit so that the size of the total receptacle is greater than a cross-sectional area of the accumulator to be measured, and preferably less than twice as large.

Preferably, the first calorimeter includes a heater for heating the first receptacle. With this heater it is possible to simulate the heat emanating from the accumulator. The heating is preferably an electric heater. For electric heaters, it can be determined with high accuracy what heat they emit, so that the calorimeter unit can be easily calibrated.

It is particularly favorable if the first heater has a heating foil which has a substrate foil and a metallization applied thereon. It is possible and represents a preferred embodiment that this heater is firmly connected to the recording, but this is not necessary. If the heater is designed as a heating foil, it impedes the heat flow from the accumulator in the tempering only insignificantly. It is therefore easily possible to calibrate the calorimeter by means of these heating foils.

The calorimeter preferably has an evaluation unit which is designed for automatic time-dependent detection of heat flow data of the heat flow meters and for calculating a heat flow based on the heat flow data. It is possible, but not necessary, that the heat flow meters are interconnected, so that a common measurement result is obtained from all heat flow meters. It is also possible that the heat flow meters are operated individually, so that separate heat flow data are obtained for each heat flow meter, from which then the total heat flow is calculated, which flows from the accumulator into the calibration or vice versa.

It is advantageous if the heat flow meter has a measuring surface which is at least 0.8 times a recording surface area of the recording surface of the recording. It is particularly favorable when the receiving surface of the receptacle is completely formed by an area of the heat flow meter. This ensures that heat emanating from the accumulator must flow through the heat flow meter in order to reach the temperature control unit.

Preferably, the heat flow meter comprises a Peltier element. Peltier elements have a high measuring accuracy and are also easy to manufacture.

Preferably, the calorimeter includes a thermometer for measuring a temperature of the accumulator. It is then possible to perform the calorimetric measurements at different temperatures. It is known that, for example, the internal resistance of galvanic elements is temperature-dependent. For this reason, the heat flow, which causes a loading or unloading at the same charging or discharging current. The temperature can be detected by the thermometer.

Preferably, the calorimeter comprises a tempering unit, which is connected to the tempering with a tempered fluid, in particular a tempered liquid. In particular, the tempering unit is designed to supply the tempering device with an aqueous liquid, for example with water. Water has a high heat capacity, so that a heat flow in the tempering leads to a relatively small increase in temperature.

Preferably, the evaluation unit is designed to carry out a method automatically with the steps of (i) energizing the first heater, (ii) time-dependent detection of the heat flow data of the first heat flow meter, (iii) calculating a first heat flow based on the heat flow data and (iv) storing a calibration factor, by means of which the first heat flow can be calculated from the heat flow data. Preferably, the evaluation unit is also designed to carry out the same method for all heat flow meters of the calorimeter. Preferably, the receptacle has a rectangular base, in particular a square base. The side lengths of the rectangular base are preferably between 30 and 100 millimeters.

The calorimeter preferably has a third calorimeter unit and at least a fourth calorimeter unit, all of which are identical. As described above, in this way calorimeters for accumulators of various sizes can be easily manufactured.

According to the invention is also a measuring arrangement with a calorimeter according to the invention and an accumulator, which is arranged between the first receptacle and the second receptacle and is in thermal solid state contact with them.

Preferably, the measuring arrangement comprises a third calorimeter unit and a fourth calorimeter unit, wherein all calorimeter units are preferably of identical construction. It is advantageous if the first calorimeter unit and the third calorimeter unit are connected to one another and form a first calorimeter module. Vorzugseise also the second calorimeter unit and the third calorimeter unit are connected together and form a second calorimeter module. The accumulator is disposed between the first calorimeter module and the second calorimeter module and is in solid state contact therewith.

• 1 eine Ansicht einer erfindungsgemäßen Messanordnung mit zwei erfindungsgemäßen Kalorimetern und
• 2 zeigt ein Kalorimeter-Modul erfindungsgemäßen Kalorimeters gemäß einer zweiten Ausführungsform der Erfindung.

In the following the invention will be explained in more detail with reference to the accompanying drawings. It shows

• 1 a view of a measuring arrangement according to the invention with two calorimeters according to the invention and
• 2 shows a calorimeter module according to the invention calorimeter according to a second embodiment of the invention.

1 shows a measuring arrangement according to the invention 10 which is a first calorimeter according to the invention 12.1 and a structurally identical second calorimeter 12.2 having. Between the two calorimeters 12.1 . 12.2 is an accumulator 14 arranged, which is a pouch cell. It is particularly favorable if the accumulator - as shown in the present embodiment - is a lithium accumulator. A lithium accumulator is understood to mean accumulators in which the energy-storing electrochemical reaction is based on lithium.

The first calorimeter 12.1 has a first shot 16.1 for the accumulator 14 and a first tempering device 18.1 for tempering a temperature-side side S ₁₈ a first heat flow meter 20.1 , The temperature side S ₁₈ of the first heat flow meter 20.1 is an accumulator side S ₁₄ across from. On the accumulator side S ₁₄ is a heater 22.1 arranged.

The heating system 22.1 comprises a heating foil which is a substrate foil 24.1 and a metallization applied thereto 26.1 having. Such heating foils are known from the prior art. For example, the substrate film is made of a polyimide such as Kapton. The metallization 26 For example, is made of copper, silver or other alloy of an electrically conductive material, it is usually a metal or a metal alloy.

The heating system 22.1 has two connecting wires 28a.1 . 28b.1 that come with an evaluation unit 30 are connected. By means of the evaluation unit 30 can the heater 22 be subjected to a heating current of known current and voltage, so that the heater known with high accuracy performance P _heating emits. To increase the measuring accuracy, a connection by means of four connecting wires is possible, which is a separate Allow voltage measurement. In thermal contact with the heater 22 is the accumulator 14 ,

In the present case alone forms the first calorimeter 12.1 a calorimeter module 32.1 , But it is also possible that the calorimeter module 32.1 has more calorimeters, which is next to the first calorimeter 12.1 are arranged that their shots 16 to complete a total intake. The calorimeters are preferably arranged in a plane next to one another. This is in 2 shown. Preferably, then the heating extends 22 in the form of the heating foil over the total admission.

The heat flow meter 20 in the present case comprises a Peltier element 34.1 that has two connection cables 36a.1 . 36b.1 with the evaluation unit 30 are connected. The evaluation unit 30 is designed to automatically measure a voltage U caused by a temperature difference between the two sides S ₁₈ and S ₁₄ of the heat flow meter 20 will cause. Out of this tension U _20.1 calculates the evaluation unit 30 the heat flow through the heat flow meter 20.1 ,

The tempering device 18 has a first connection 38 .a1 and a second connection 38.b1 , which, as schematically drawn, with a tempering unit 40 are connected. The temperature control unit 40 comprises a pump and a thermostat, by means of which a fluid, in the present case water, with a predetermined temperature T ₁ in the connection 38a.1 is initiated, which consequently serves as an inflow. Through the second connection 38b.1 , which acts as a drain, the optionally temperature-variable fluid, in the present case the water, withdrawn and the temperature control unit 40 directed where it is to the specified temperature T ₁ brought and again in the tempering 18.1 is pumped.

The calorimeter 12.2 is identical to the calorimeter 12.1 , However, it is possible that, for example, the connections 38a.2 . 38b.2 could be located at a different location than the calorimeter 12.1 , The connections of the second calorimeter 12.2 to the evaluation unit 30 are not shown for clarity.

For measuring the accumulator 14 will this, as in 1 shown between the two calorimeters 12.1 . 12.2 arranged. These are then moved towards each other, preferably stretched towards each other, so that the accumulator 14 the contact with the two calorimeters 12.1 . 12.2 Has. The evaluation unit leads to calibration 30 the following procedure programmed into it. First, the heater 22.1 energized and the heat flow data of the heat flow meter 20.1 detected. From the heating power P _heating the heater 22 on the one hand and the measured heat flow on the other hand, a calibration factor is determined.

Hereinafter, the accumulator whose contacting lines 42a.1 . 42b.1 also with the evaluation unit 30 are connected, acted upon by a predetermined current, which therefore from the accumulator 14 discharged heat flow flows from the accumulator 14 through the heat flow meter 20 to tempering device 18 and is from the heat flow meter 20 measured and by the evaluation unit 30 detected. In addition, another heat flow flows through a second heat flow meter 20.2 to a second temperature control device 18.2 the second calorimeter 12.2 , The heat flow data of the second heat flow meter 20.2 are also from the evaluation unit 30 automatically detected. The evaluation unit calculates from all heat flow data 30 the heat flow coming from the accumulator 14 is delivered.

2 shows a second embodiment of a calorimeter module 32.1 a calorimeter according to the invention, consisting of six identical calorimeters 12.i (i = 1, ... 6) is constructed. The second calorimeter 32.2 , this in 1 above is also from six calorimeters 12.i +6 built and identical to the in 2 shown first calorimeter module 32.1 , It can be seen that the calorimeter 12.i mechanically interconnected. The respective connections 38a.1 . 38b.1 (see. 1 ) for the cooling fluid are connected to each other and have all calorimeters 12.i respective, not shown sockets in which the connectors 38a.1 . 38b.i can be inserted, so that a fluid connection between the respective calorimeter is made. It is then possible to use cooling fluid through the port 38a.1 feed it through all the calorimeters 12.i the first calorimeter module 32.2 flows and through the connection 38b .1 comes out again.

The respective recordings 16.i the single calorimeter 12.i complement each other to a total intake on which the heater 22.1 is arranged. On the heater 22 will, as above for the calorimeter 12.1 . 12.2 described, the accumulator 14 arranged. The calorimetric measurement of the accumulator 14 done with the help of calorimeter modules 32.1 . 32.2 as above for the calorimeter 12.1 . 12.2 described. In other words, the calorimeter modules 32.1 . 32.2 regardless of whether they consist of only one calorimeter, as in 1 shown, or made several, as in 2 shown.

1 also shows a thermometer 44 of the calorimeter 12 , which has not drawn cables with the evaluation unit 30 connected is.

LIST OF REFERENCE NUMBERS

10

measuring arrangement

12

calorimeter

14

accumulator

16

admission

18

tempering

20

Heat flow meter

22

heater

24

substrate film

26

metallization

28a, b

Lead wire

30

evaluation

32

Calorimeter module

34

Peltier element

36

connection cable

38

connection

40

temperature control

42

contact-

44

thermometer

S ₁₈

temperature side

S ₁₄

Accumulator side

P _heating

heating capacity

U

tension

T ₁

vorgebbareTemperatur

Claims (16)

Calorimeter (12) for determining a heat flow between an accumulator (14), in particular a pouch cell or a prismatic cell, and its surroundings, with (a) a first calorimeter unit (12.1) comprising (i) a first receptacle (16.1) for the Accumulator (14), (ii) a first temperature control device (18.1) which is designed for tempering to a predeterminable temperature (T ₁ ), and (iii) a first heat flow meter (20) for measuring a heat flow between the first receptacle (16.1) and (b) at least one second calorimeter unit (12.2) having (i) a second receptacle (16.2) for the accumulator (14), (ii) a second tempering device (18.2) being formed is for tempering to a predetermined temperature (T ₁ ), and (iii) a second heat flow meter (20) for measuring a second heat flow between the second receptacle (16.2) of the second temperature control device (18.2). Calorimeter (12) after Claim 1 , characterized in that the first calorimeter unit (12.1) is identical to the second calorimeter unit (12.2). Calorimeter (12) according to one of the preceding claims, characterized in that the first calorimeter unit (12.1) and the second calorimeter unit (12.2) are connected to one another such that the first receptacle (16.1) and the second receptacle (16.2) form a total Supplement recording. Calorimeter (12) after Claim 3 , characterized in that the overall receptacle extends along a plane. Calorimeter (12) according to one of the preceding claims, characterized in that the first calorimeter unit (12.1) has a first heater (22.1) for heating the first receptacle (16.1). Calorimeter (12) after Claim 5 , characterized in that the first heater (22.1) comprises a heating foil comprising a substrate foil (24) and a metallization (26) applied thereto. Calorimeter (12) according to one of the preceding claims, characterized by an evaluation unit (30), which is designed for automatic (i) time-dependent detection of heat flow data of the heat flow meter (20) and (ii) calculating a heat flow based on the heat flow data. Calorimeter (12) according to one of the preceding claims, characterized in that the heat flow meter (20) has a measuring surface which is at least 0.8 times a recording area size of the receptacle (16). Calorimeter (12) according to one of the preceding claims, characterized in that the heat flow meter (20) comprises a Peltier element (34). Calorimeter (12) according to one of the preceding claims, characterized in that the first calorimeter unit (12.1) has a first thermometer (44) for measuring a first temperature (T ₁ ). Calorimeter (12) according to one of the preceding claims, characterized by a temperature control unit (40) which is connected to the temperature control devices (18) for supplying a temperature-controlled fluid, in particular a tempered liquid is connected. Calorimeter (12) according to one of the preceding Claims 7 to 11 , characterized in that the evaluation unit (30), is designed for automatic (i) energizing the first heater (22.1), (ii) time-dependent detection of the heat flow data of the first heat flow meter (20.1), (iii) calculating a first heat flow based on the heat flow data and (iv) storing a calibration factor by which the first heat flow from the heat flow data is calculable. Calorimeter (12) according to one of the preceding claims, characterized in that the receptacle (16) has a square base. Calorimeter (12) according to one of the preceding claims, characterized by (a) a third calorimeter unit (12.3) and (b) at least a fourth calorimeter unit (12.4), (c) wherein all calorimeter units (12.i) are constructed from the same components , in particular are identical. Measuring arrangement (10) with (A) a calorimeter (12) according to any one of the preceding claims and (B) an accumulator (14) which is arranged between the first receptacle (16.1) and the second receptacle (16.2) and is in thermal solid contact with these. Measuring arrangement (10) according to Claim 15 , characterized by (a) a third calorimeter unit (12.3) and (b) at least a fourth calorimeter unit (12.4), (c) wherein all calorimeter units (12.i) are identical, (d) wherein the first calorimeter unit (12.1) and the third calorimeter unit (12.3) are interconnected and form a first calorimeter module (32.1), (e) wherein the second calorimeter unit (12.2) and the fourth calorimeter unit (12.4) are interconnected and form a second calorimeter module (32.2), and (f) wherein the accumulator (14) is disposed between and in thermal solid contact with the first calorimeter module (32.1) and the second calorimeter module (32.2).

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