KR101077070B1 - Secondary battery material characteristic evaluation device - Google Patents

Abstract

The present invention relates to a secondary battery material property evaluation apparatus, and includes a lower plate (10) disposed below and provided with an upward support bar (15); An upper plate 20 supported by the support bar 15 while being spaced apart from the upper portion of the lower plate 10; A gap sensor 30 in which a body is gripped by the upper plate 20 in a state in which a sensing unit 31 sensing a separation distance to the sensing unit 55 faces downward; A housing 40 provided on an upper surface of the lower plate 10 and having an internal space in which a secondary battery specimen T which is a target of evaluation is inserted and settled; An operation part 50 having a lower contact portion 51 in contact with an upper surface of the secondary battery specimen T and an upper sensing part 55 spaced apart from the lower part of the sensing part 31; It is related with the secondary battery material characteristic evaluation apparatus characterized by including.

Description

Secondary battery material characteristic evaluation device {secondary battery material characteristic evaluation device}

The present invention relates to an apparatus for evaluating material properties of a secondary battery for measuring a change in volume during charging and discharging of a secondary battery.

In general, a lot of researches on the production process of a battery and a battery used as a power source of electronic products by the structure of electronic products such as automobiles, portable telephones, video cameras, portable PCs, etc. are lightened or highly functional. Such a battery can be used continuously by charging / discharging.

Generally, nickel cadmium batteries, nickel hydride batteries, nickel zinc batteries, lithium secondary batteries, and the like are used as power sources for electronic products. Among them, lithium secondary batteries have been widely used in consideration of their lifespan and capacity.

The lithium secondary battery is classified into a lithium metal battery, a lithium ion battery, and a lithium polymer battery using a high-volume solid electrolyte according to the type of electrolyte. The lithium secondary battery has a structure in which a unit cell or a bi-cell is stacked, wherein the unit cell has a positive plate / separator / negative plate structure, and the bi-cell has a positive plate / separator / negative plate / separator / positive plate structure.

Generally, a lithium ion secondary battery (henceforth a secondary battery) is manufactured largely by a pole plate manufacturing process, an assembly process, and a chemical conversion process. In the electrode plate manufacturing process, a positive electrode plate and a negative electrode plate are manufactured. First, the positive electrode plate is mainly manufactured by coating an active material on both surfaces of an aluminum foil in a predetermined pattern and thickness, and then drying them under high temperature and vacuum. Here, the active material is mainly lithium cobalt oxide (for example, LiCoO 2), which has a form in which a small amount of a conductive agent and a binder are mixed. In addition, the negative electrode plate is mainly produced by coating the active material on both sides of the copper foil in a predetermined pattern and thickness, and then drying at high temperature and vacuum. In this case, the active material is graphite or carbon, in which a small amount of an additive and a binder are mixed.

Recently, development of a lithium ion polymer battery system is being progressed as a power source of a hybrid electric vehicle (HEV) or an electric vehicle. Such lithium ion polymer batteries are known to have a voltage three times higher than that of Ni-MH (nickel-metal hydride) batteries, and have a very high output at room temperature. Therefore, a lithium ion polymer battery, which is a high power and high density battery, is being developed as a battery capable of supplementing automotive packaging and output characteristics. Looking at the configuration of the electrode plate assembly, which is one of the main components of such a lithium ion polymer battery, the electrode plate assembly includes a positive electrode plate and a negative electrode plate. Looking at the configuration of the electrode plate assembly, which is one of the main components of such a lithium ion polymer battery, the electrode plate assembly includes a positive electrode plate and a negative electrode plate, the positive electrode plate, and the negative electrode plate is usually prepared by mixing the active material, the conductive material and the binder by a wet method. do.

2 is a graph showing a change in volume of a typical secondary battery material according to charging and discharging. As shown in FIG. 2, the secondary battery is known to change in volume due to changes in physical properties during charging and discharging.

A typical secondary battery is known to change in volume depending on the degree of charging and discharging, but the reality is that there is a lack of a device capable of quantitatively measuring a change in characteristics of a battery including a volume according to a parameter change. Change in the characteristics of the battery itself due to the discharge of the rechargeable battery when the multi-stage stacking design of the secondary battery or the housing design and fabrication of the plurality of laminated secondary batteries is in progress without being aware of the volume change due to the temperature change or the charging or discharging state. According to the present invention, there is a problem in that poor contactability or deformation and collapse of the battery occur. This problem may cause a larger problem than in the case of a vehicle secondary battery in which the size of the battery is large and the stacking amount is large.

It is an object of the present invention to provide an apparatus for evaluating secondary battery material properties that can easily, accurately and repeatedly evaluate the characteristics of a battery including a volume change of secondary battery material.

 The present invention in the secondary battery material property evaluation device,

A lower plate 10 positioned below and provided with an upward supporting bar 15;

An upper plate 20 supported by the support bar 15 while being spaced apart from the upper portion of the lower plate 10;

A gap sensor 30 in which a body is gripped by the upper plate 20 in a state in which a sensing unit 31 sensing a separation distance to the sensing unit 55 faces downward;

A housing 40 provided on an upper surface of the lower plate 10 and having an internal space in which a secondary battery specimen T which is a target of evaluation is inserted and settled;

An operation part 50 having a lower contact portion 51 in contact with an upper surface of the secondary battery specimen T and an upper sensing part 55 spaced apart from the lower part of the sensing part 31; It is related with the secondary battery material characteristic evaluation apparatus characterized by including.

According to the present invention, there is provided an apparatus for evaluating the characteristics of a secondary battery material which can evaluate the characteristics of a battery including the volume change of the secondary battery material in a simple, precise and repeatable manner.

1 is a block diagram of a secondary battery material characteristic evaluation apparatus according to an embodiment of the present invention.
2 is a graph showing a change in volume of a typical secondary battery material with charge and discharge.

Hereinafter, a secondary battery material property evaluation apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 1 is a configuration of a secondary battery material characteristic evaluation apparatus according to an embodiment of the present invention.

As shown in FIG. 1, the secondary battery material property evaluation apparatus according to an embodiment of the present invention includes a lower plate 10, an upper plate 20, a gap sensor 30, a housing 40, and an operation unit 50. It is configured to include.

The lower plate 10 is located at the bottom and is provided with an upward support bar 15. The lower plate 10 forms a lower structure and may have a plate shape. A space is formed between the upper plates 20 so as to contain the housing 40. The upper plate 20 is supported by the support bar 15 while being spaced apart from the upper portion of the lower plate 10.

In the gap sensor 30, the body is gripped by the upper plate 20 while the sensing unit 31 sensing the separation distance to the sensing unit 55 faces downward. The gap sensor 30 of the present invention can relatively measure the separation distance to the object to be detected, that is, detect and decrease the distance from the reference point (initial value) and transmit it to a controller (not shown). The concept includes all known means. Typically, the output of the gap sensor 30 may be a current, a voltage, an amount of charge, and the like, and has a characteristic of being linearly proportional to the amount of change in the separation distance GAP.

The housing 40 is provided on the upper surface of the lower plate 10 and is provided with an inner space in which the secondary battery specimen T, which is to be attached and detached, is placed and placed therein. Although the housing 40 is preferably comprised in circular cylindrical shape, the shape is not limited. In combination with the auxiliary housing 60 may be formed in a shape surrounding the space where the secondary battery specimen (T) is located.

The operation part 50 is positioned such that the lower contact portion 51 is in contact with the upper surface of the secondary battery specimen T, and the upper sensing part 55 is spaced below the sensing part 31. The operation unit 50 moves up and down by the same distance as the secondary battery specimen T expands and contracts in the vertical direction. The vertical movement distance of the operation unit 50 is sensed by the gap sensor 30.

As shown in FIG. 1, in the secondary battery material property evaluation apparatus according to an embodiment of the present invention, the housing 40 is open at an upper portion thereof, and an auxiliary housing 60 at an upper portion of the opened housing 40. ) Is attached and detached, the operation unit 50 is installed to allow the lifting operation to penetrate the auxiliary housing 60, the sensing unit 55 to the upper portion of the auxiliary housing (60). It is preferable to protrude.

As shown in FIG. 1, in the secondary battery material property evaluation apparatus according to an embodiment of the present invention, the housing 40 is open at an upper portion thereof, and the connecting rod 53 is connected to the contact portion 51. The sensing unit 55 is connected, and the sensing unit 55 has a plate shape having a width larger than that of the connecting rod 53, and the first elastic body S1 has an inner surface portion 51 of the auxiliary housing 60. Located between the upper side of the contact portion 51 and the contact portion 51 is configured to press the secondary battery specimen (T).

As shown in Figure 1, in the secondary battery material characteristic evaluation apparatus according to an embodiment of the present invention, the top plate 20 is supported by the support bar 15 through a height adjusting means 70, the height The adjusting means 70 preferably adjusts the distance between the upper plate 20 and the lower plate 10 to increase or decrease the distance between the sensing unit 55 and the sensing unit 31. When the housing 40 is pulled out from the lower plate 10 for specimen replacement, the upper plate 20 is raised by the height adjusting means 70 to increase the distance between the sensing unit 55 and the sensing unit 31. After the housing 40 can be taken out from the lower plate 10 so as not to interfere. In addition, the height adjustment means 70 performs a function that can make the initial separation distance at the time of setting the initial value.

As shown in Figure 1, in the secondary battery material characteristic evaluation apparatus according to an embodiment of the present invention, the height adjusting means 70 is rotated by adjusting the adjustment bolt 71 and the top plate 20, the top plate 20 ) And a second elastic body S2 interposed between the support bar 15. The second elastic body S2 may be a compressed spring.

As shown in Figure 1, in the secondary battery material characteristic evaluation apparatus according to an embodiment of the present invention, the secondary battery specimen (T) to prevent the edge of the secondary battery specimen (T) is extended in the horizontal direction It is preferable that the rigid side wall body 80 is further provided at the edge of. The side wall body 80 prevents the secondary battery specimen T from expanding horizontally and expands upward to implement an environment such as an actual product state in which the secondary battery is placed. The side wall body 80 may be made of metal or hard plastic material.

In the battery material characteristic evaluation apparatus according to an embodiment of the present invention, a space shielded from the outside is formed by the combination of the housing 40 and the auxiliary housing 60, and heat is applied to the space to reach a predetermined temperature. It is preferable that a heating means to be further provided. The heating means may change the temperature of the space in which the secondary battery specimen T is located so as to perform a physical property test to parameterize the temperature.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, the scope of the present invention is not limited to these embodiments, and the scope of the present invention is defined by the following claims, and equivalent scope of the present invention. It will include various modifications and variations belonging to.

The reference numerals set forth in the claims below are merely to aid the understanding of the present invention, not to affect the interpretation of the scope of the claims, and the scope of the claims should not be construed narrowly.

10: lower plate 15: support bar
20: top plate 30: gap sensor
31: sensing unit 40: housing
50: operating part 51: folding part
53: connection rod 55: the sensing part
60: auxiliary housing 70: height adjustment means
71: adjusting bolt 80: side wall body
S2: second elastomer T: secondary battery specimen

Claims (7)

delete In the secondary battery material characteristic evaluation apparatus,
A lower plate 10 positioned below and provided with an upward supporting bar 15;
An upper plate 20 supported by the support bar 15 while being spaced apart from the upper portion of the lower plate 10;
A gap sensor 30 in which a body is gripped by the upper plate 20 in a state in which a sensing unit 31 sensing a separation distance to the sensing unit 55 faces downward;
A housing 40 provided on an upper surface of the lower plate 10 and having an internal space in which a secondary battery specimen T which is a target of evaluation is inserted and settled;
An operation part 50 having a lower contact portion 51 in contact with an upper surface of the secondary battery specimen T and an upper sensing part 55 spaced apart from the lower part of the sensing part 31; Configured to include,

The housing 40 is open at the top,
Auxiliary housing 60 is attached to the upper portion of the open housing 40, detachably coupled,
The operation unit 50 is installed to allow the lifting operation to penetrate through the auxiliary housing 60, and the secondary battery material is characterized in that the sensing unit 55 protrudes above the auxiliary housing 60. Characteristic evaluation device. The method of claim 2,
The connecting rod 53 connects the contact portion 51 and the sensing unit 55,
The sensing unit 55 has a plate shape having a width larger than that of the connecting rod 53.
The first elastic body (S1) is located between the inner surface portion 51 of the auxiliary housing 60 and the upper side of the contact portion 51 is configured to press the secondary battery specimen (T) the contact portion 51 Secondary battery material characteristic evaluation apparatus characterized by the above-mentioned. The method of claim 2,
The upper plate 20 is supported by the support bar 15 through the height adjusting means 70,
The height adjusting means 70 adjusts the distance between the upper plate 20 and the lower plate 10, thereby increasing or decreasing the distance between the sensing unit 55 and the sensing unit 31. Secondary battery material characteristic evaluation apparatus. The method of claim 4, wherein
The height adjusting means 70 is the adjustment bolt 71 and the protrusion length is adjusted by rotating,
The secondary battery material characteristic evaluation apparatus which consists of a 2nd elastic body (S2) interposed between the upper board (20) and the support bar (15). The method of claim 2,
Secondary battery material characteristic evaluation apparatus, characterized in that the side wall 80 is further provided on the edge of the secondary battery specimen (T) to prevent the edge of the secondary battery specimen (T) to extend in the horizontal direction . The method of claim 2,
Secondary battery material characteristics, characterized in that the space is formed outside and shielded by the combination of the housing 40 and the auxiliary housing 60, the heating means for applying a heat to the space to reach a predetermined temperature Evaluation device.

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