Patent Description:
The present disclosure relates to a contact device and a characteristic measuring device including the same, and more particularly, to a contact device, which is used to measure cell characteristics necessary for manufacturing of a secondary battery, and a characteristic measuring device including the contact device.

Recently, as prices of energy sources rise due to depletion of fossil fuels and interests about environmental pollution are amplified, a need for eco-friendly alternative energy sources is indispensable for life in the future. Accordingly, research continues on various power generation technologies using sunlight, wind power, tidal power, and so on, and there is also a continuing great interest in power storage systems, such as batteries, for more efficiently using electrical energy generated through the technologies.

Moreover, as the technical development of and a demand for mobile electronic devices and electric vehicles using batteries increase, a demand for batteries as energy sources rapidly increases. Accordingly, much research is conducted on batteries that can meet the various needs.

Batteries that store electrical energy may be generally classified into primary batteries and secondary batteries. While the primary batteries are disposable consumable batteries, the secondary batteries are rechargeable batteries manufactured using a material in which a redox process between a current and a substance is repeatable. That is, when a reduction reaction is performed on the material by the current, power is charged, and when an oxidation reaction is performed on the material, power is discharged. Such a charging-discharging is repeatedly performed to generate electricity.

In particular, in terms of materials, lithium secondary batteries such as lithium-ion batteries and lithium-ion polymer batteries, which have advantages such as high energy density, discharge voltage, and output stability, are in high demand.

Secondary batteries are rechargeable unlike primary batteries, and classified into a coin type cell, a cylinder type cell, a prismatic type cell, and a pouch type cell according to the shape of cases.

In a manufacturing process for secondary batteries, assembling of a cell is completed and then, a voltage is measured between a metal layer, which is exposed to an outer circumferential end of a battery case such as a pouch of the pouch type cell, and an electrode terminal of the cell, to check a defect of insulation resistance that is resistance between the metal layer and the electrode terminal. The insulation resistance and the like of the cell are measured using a characteristic measuring device, and a contact device of the characteristic measuring device is in contact with an outer circumference of the battery case to measure the insulation resistance or the like.

The document <CIT> discloses a rotatable platform on which is placed a pouch cell for evaluation thereof. Evaluation of the battery cell includes measuring the impedance of the battery cell while applying a longitudinal pulling force or a transverse bending force to an electrically conductive terminal of the cell and to a solid electrical and mechanical joint connecting electrically conductive components of the cell.

As the outer circumference of the battery case may have a rectangular shape and also have a chamfered shape, the contact device requires a motion such as rotation. Thus, a contact device according to the related art has a rotatable portion and has a rotated and fixed shape.

Such a shape has problems that when the cell is set to be biased, the contact device is not in contact with the cell or is in contact with only a portion of the cell to cause a contact failure, and accordingly, efficiency of the overall process is deteriorated.

In order to solve the problems above, a way to minimize the contact failure of the contact device and thus increase the efficiency of the process is needed.

The present invention has been devised to solve the problems as above and an object of the present invention is to a contact device and a characteristic measuring device including the same, which may minimize a contact failure of the contact device and increase accuracy and efficiency of a process by adding a motion such as rotation, to the contact device of the characteristic measuring device, which measures insulation resistance or the like of a cell, so that all surfaces of the contact device are in contact with the cell.

A contact device of a characteristic measuring device, which measures characteristics of a cell, according to the present invention includes: a body part in which a connection hole having a shape passing through the body part from one surface toward the other surface is defined; a connection part including a first shaft provided at one side and connected to the connection hole, and a second shaft provided to be parallel to the first shaft at the other side; and a contact part having one side at which a coupling hole is defined, wherein the coupling hole has a shape passing through the contact part from one surface toward the other surface so that the second shaft is coupled therethrough, and the other side provided with a terminal in contact with the cell, wherein the connection part is rotatable with respect to the body part by the first shaft, and the contact part is rotatable with respect to the second shaft.

The coupling hole may have a cross section of which a length is greater than a width so that the second shaft is movable in a longitudinal direction.

The contact device may further include a pair of elastic members, each of which has one end connected to the connection part and the other end connected to the contact part. The elastic member may provide an elastic force so that the contact part of which a position has changed returns to an initial position.

The elastic members may be disposed parallel to each other.

The connection part may further include a pair of connection pillars extending to be parallel to each other at both sides of the first shaft in a longitudinal direction, and the pair of elastic members may be fitted into the pair of connection pillars, respectively.

The body part may have an outer circumference on which an angle is displayed, and the connection part may further include an indicator disposed at one end of the second shaft so as to indicate the angle while rotating with respect to the body part.

The contact device may further include a controller connected to the connection part and the contact device, and the controller may rotate the connection part and the contact device depending on a preset value of the cell.

A characteristic measuring device that measures characteristics of a pouch cell includes a base on which the pouch cell is disposed, a pressing device that is disposed above the base and presses and fixes the pouch cell disposed on the base, and a contact device that is in contact with the pouch cell so as to approach the pouch cell and measure the characteristics thereof. The contact device includes: a body part in which a connection hole having a shape passing through the body part from one surface toward the other surface is defined; a connection part including a first shaft connected to the connection hole at one side and a second shaft provided to be parallel to the first shaft at the other side; and a contact part having one side in which a coupling hole is defined, the coupling hole having a shape passing through the contact part from one surface toward the other surface so that the second shaft is coupled therethrough, and the other side provided with a terminal in contact with the cell, wherein the connection part is rotatable with respect to the body part by the first shaft, and the contact part is rotatable with respect to the second shaft.

The contact device of the characteristic measuring device according to the present invention, which measures the characteristics of the cell, includes the body part, in which the connection hole having the shape passing through the body part from the one surface to the other surface is defined, the connection part, which includes a first shaft provided at the one side and connected to the connection hole, and the second shaft provided to be parallel to the first shaft at the other side, and the contact part, which has the one side at which the coupling hole is defined, the coupling hole having the shape passing through the contact part from the one surface toward the other surface so that the second shaft is coupled therethrough, and the other side provided with the terminal in contact with the cell. The connection part is rotatable with respect to the body part by the first shaft, and the contact part is rotatable with respect to the second shaft.

Accordingly, the contact failure of the contact device may be minimized and the accuracy and efficiency of the process may increase by adding the motion such as the rotation, to the contact device of the characteristic measuring device, which measures the insulation resistance or the like of the cell, so that the all surfaces of the contact device are in contact with the cell.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings to enable those skilled in the art to which the present invention pertains to easily carry out the present invention. The present invention may, however, be embodied in different forms and should not be construed as limited by the embodiments set forth herein.

The parts unrelated to the description, or the detailed descriptions of related well-known art that may unnecessarily obscure subject matters of the present invention, will be ruled out in order to clearly describe the present invention. Like reference numerals refer to like elements throughout the whole specification.

Moreover, terms or words used in this specification and claims should not be restrictively interpreted as ordinary meanings or dictionary-based meanings, but should be interpreted as meanings and concepts conforming to the scope of the present invention, as defined by the claims, on the basis that an inventor can properly define the concept of a term to describe and explain his or her invention in the best ways.

The present invention provides a contact device <NUM> as Embodiment <NUM>.

<FIG> is a perspective view schematically illustrating the contact device <NUM> according to Embodiment <NUM> of the present invention. <FIG> and <FIG> are a front view and a side view schematically illustrating the contact device <NUM> according to Embodiment <NUM> of the present invention when viewed from a front side and a side, respectively.

The contact device <NUM> according to Embodiment <NUM> of the present invention may be used in a characteristic measuring device <NUM> that measures characteristics of a cell <NUM>, such as insulation resistance. The contact device <NUM> of the characteristic measuring device <NUM> may be in contact with an outer circumference of a battery case to measure the characteristics of the cell <NUM>. Representative examples of the cell <NUM> of which the characteristics are measured include a pouch type cell, and so on.

Referring to <FIG>, the contact device <NUM> may include a body part <NUM>, a connection part <NUM>, and a contact part <NUM> for efficient contact with the cell <NUM>. The body part <NUM>, the connection part <NUM>, and the contact part <NUM> may be disposed in order from a lower side of the contact device <NUM>, and connected to each other through specific components so as to be rotatable independently of each other. The components connected to each other will be described later in detail.

<FIG> is a plan view schematically illustrating the body part <NUM> of the contact device <NUM> according to Embodiment <NUM> of the present invention.

The body part <NUM> may be disposed at the lowest side of the contact device <NUM>. Referring to <FIG>, the body part <NUM> according to Embodiment <NUM> may have a cross section of which an upper portion has a semicircular shape and a lower portion has a rectangular shape when viewed from a front side. When the upper portion of the body part <NUM> has a semicircular shape when viewed from a front side, there may be an effect that an angle displayed on an upper outer circumference is easily recognized. The angle displayed on the outer circumference will be described later in detail. Such a shape of the cross section is just one example, and is not necessarily limited thereto.

A connection hole <NUM> may be defined in the body part <NUM>. The connection hole <NUM> is a hole defined to cross from one surface to the other surface of the body part <NUM>, and may be a space to which a first shaft <NUM> of the connection part <NUM> to be described later is coupled.

The connection hole <NUM> may be defined in the middle with respect to a left-right direction, and may be defined at a boundary between the upper portion having a semicircular shape and the lower portion having a rectangular shape with respect to an upward-downward direction when the body part <NUM> is viewed from a front side.

The first shaft <NUM> of the connection part <NUM> is coupled to the connection hole <NUM> to allow for left-right rotation of the connection part <NUM>. Thus, in order for the connection part <NUM> to easily rotate, the connection hole <NUM> may be defined so as to have a cross section having, preferably, a circular shape. However, the shape is not necessarily limited thereto.

When both the connection hole <NUM> and the first shaft <NUM> have a circular cross section, the connection hole <NUM> of the body part <NUM> may have a circular cross section of which a diameter is greater than the diameter of a cross section of the first shaft <NUM> so as to allow for easy left-right rotation of the connection part <NUM>.

An empty space may be defined inside an upper portion of the body part <NUM> with respect to the connection hole <NUM>, so that a rotational motion of the connection part <NUM> is not interrupted by the body part <NUM> when the connection part <NUM> rotates in the left-right direction. That is, as the connection part <NUM> passes through the empty space defined inside the body part <NUM> while rotating in the left-right direction, the connection part <NUM> may not be in contact with the body part <NUM>. The empty space defined inside the body part <NUM> is sufficient as long as the connection part <NUM> is rotatable in the empty space.

An additional component such as a member for receiving an electric power supply, may be coupled to the lower portion of the body part <NUM>.

<FIG> is a plan view schematically illustrating the connection part <NUM> of the contact device <NUM> according to Embodiment <NUM> of the present invention.

The connection part <NUM> may be disposed above the body part <NUM>. Referring to <FIG>, the connection part <NUM> of the contact device <NUM> may include the first shaft <NUM> and a second shaft <NUM> so as to allow for the left-right rotation of the connection part <NUM> and the contact part <NUM>. The first shaft <NUM> and the second shaft <NUM> may be provided to be parallel to each other at a lower side and an upper side of the connection part <NUM>, respectively, and may each have a shape extending in the left-right direction when viewed from a side.

The first shaft <NUM> and the second shaft <NUM> of the connection part <NUM> may each have, preferably, a cylindrical shape so as to allow for easy left-right rotation of the connection part <NUM> and the contact part <NUM>, but the shape is not necessarily limited thereto.

As described above, the first shaft <NUM> may be coupled to the connection hole <NUM> of the body part <NUM> to allow for the left-right rotation of the connection part <NUM>. As one example of a method of coupling the first shaft <NUM> and the connection hole <NUM> to each other, the first shaft <NUM> of the connection part <NUM> may be fitted into the connection hole <NUM> of the body part <NUM> and then, a member such as a cap, may be coupled to each of both ends of the first shaft <NUM> so that the first shaft <NUM> is not movable in a longitudinal direction.

The second shaft <NUM> may be coupled to a coupling hole <NUM> of the contact part <NUM> to allow for the left-right rotation of the contact part <NUM>. As one example of a method of coupling the second shaft <NUM> and the coupling hole <NUM> to each other, like the method of coupling the first shaft <NUM> and the connection hole <NUM> to each other described above, the second shaft <NUM> of the connection part <NUM> may be fitted into the coupling hole <NUM> of the contact part <NUM> and then, a member such as a cap, may be coupled to each of both ends of the second shaft <NUM> so that the second shaft <NUM> is not be movable in a longitudinal direction.

In the present invention, both the connection part <NUM> and the contact part <NUM> are rotatable. In this regard, when the contact device <NUM> approaches and is in contact with the cell <NUM>, it is advantageous in measuring the characteristics of the cell <NUM> that the rotation of the connection part <NUM> and the rotation of the contact part <NUM> may be performed independently of each other and smoothly follow each other. Therefore, the first shaft <NUM> and the second shaft <NUM> of the connection part <NUM> may be disposed on the same line in front of the connection part <NUM> in the upward-downward direction.

<FIG> is a plan view schematically illustrating the contact part <NUM> of the contact device <NUM> according to Embodiment <NUM> of the present invention.

The contact part <NUM> may be disposed above the connection part <NUM>. Referring to <FIG>, the contact part <NUM> may have a lower side at which the coupling hole <NUM> is defined, and an upper side including a terminal <NUM> that may be in contact with the cell <NUM>. The lower side at which the coupling hole <NUM> is defined may have a cross section having a convex outer circumference so as not to be in contact with the connection part <NUM> during the rotation of the contact part <NUM>.

As described above, the second shaft <NUM> of the connection part <NUM> may be coupled to the coupling hole <NUM>. The coupling hole <NUM> may be a hole defined to cross from one surface to the other surface of the contact part <NUM>.

The second shaft <NUM> of the connection part <NUM> is coupled to the coupling hole <NUM> to allow for the left-right rotation of the contact part <NUM>. Thus, in order for the contact part <NUM> to easily rotate, the coupling hole <NUM> may be defined so as to have a cross section having, preferably, a circular shape. However, the shape is not necessarily limited thereto.

When both the coupling hole <NUM> and the second shaft <NUM> have a circular cross section, the coupling hole <NUM> of the contact part <NUM> may have a circular cross section of which a diameter is greater than the diameter of a cross section of the second shaft <NUM> so as to allow for easy left-right rotation of the contact part <NUM>.

The terminal <NUM> is a portion that is in contact with the cell <NUM> in order to measure the characteristics of the cell <NUM>. Thus, one of the purposes of the present invention is to maximize an area in which the terminal <NUM> of the contact part <NUM> and the cell <NUM> are in contact with each other.

The terminal <NUM> may have a rectangular parallelepiped shape, and the terminal <NUM> may have a top surface having a rectangular shape when the contact device <NUM> is viewed from an upper side. A surface, which is in contact with the cell <NUM> in order to measure the characteristics of the cell <NUM>, may be the top surface of the terminal <NUM>.

When the contact device <NUM> is in contact with the cell <NUM> in order to measure the characteristics of the cell <NUM>, the contact device <NUM> may be pressed and stressed by the cell <NUM> and thus, the cell <NUM> and the contact device <NUM> may not be smoothly in contact with each other. Here, when the contact device <NUM> is movable in a pressing direction, the stress exerted on the contact device <NUM> may be reduced. In one example to reduce the stress exerted on the contact device <NUM>, the coupling hole <NUM> defined in the contact part <NUM> of the contact device <NUM> according to Embodiment <NUM> of the present invention may have a cross section of which a length is longer than the diameter of the second shaft <NUM> so that the second shaft <NUM> is movable in a longitudinal direction of the coupling hole <NUM>. Specifically, in the cross section, the length may be greater than the width. Here, the longitudinal direction of the coupling hole <NUM> may be an upward-downward direction in <FIG>. Thus, when the cell <NUM> is in contact with the terminal <NUM> of the contact part <NUM>, the contact part <NUM> may move in the upward-downward direction.

As a brief introduction to an example of the shape in which the coupling hole <NUM> has the cross section of which the length is longer than the diameter of the second shaft <NUM>, the cross section of the coupling hole <NUM> may have an oval shape with a major axis provided in the upward-downward direction, and may have a shape in which an upper portion and a lower portion each have a semicircular shape and extend in the upward-downward direction while maintaining a certain width. All of the shapes may be the shape of the coupling hole <NUM> defined so that the contact part <NUM> is movable in the upward-downward direction.

When the cross section of the coupling hole <NUM> has a vertical length longer than the diameter of the second shaft <NUM>, the stress exerted on the contact device <NUM> may be reduced when the contact device <NUM> is in contact with the cell <NUM>, so that there may be effects that damage and abrasion of the contact device <NUM> is minimized and the cell <NUM> and the contact device <NUM> are efficiently in contact with each other.

When the contact device <NUM> measures the characteristics of one cell <NUM> and the contact part <NUM> is fixed in a changed state by the rotation and movement, there may be a problem that when measuring the cell <NUM> having a different contact surface, contact efficiency is deteriorated. Thus, in one example to return the contact part <NUM> in the changed state to an initial position, the contact part <NUM> according to Embodiment <NUM> of the present invention may further include a pair of elastic members 140a and 140b.

Each of the pair of elastic members 140a and 140b may have one end connected to the connection part <NUM> and the other end connected to the contact part <NUM>. The elastic members 140a and 140b may be provided in a pair to be disposed at left and right sides of the second shaft <NUM>, respectively, when the contact device <NUM> is viewed from a front side.

When the contact part <NUM> rotates leftward, the elastic member 140a at the left side of the second shaft <NUM> may contract and the elastic member 140b at the right side may expand. In contrast, when the contact part <NUM> rotates rightward, the elastic member 140b at the right side of the second shaft <NUM> may contract and the elastic member 140a at the left side may expand. When the contact part <NUM> moves downward, the pair of elastic members 140a and 140b may all contract.

The pair of elastic members 140a and 140b may be generally used springs, but are not necessarily limited thereto.

As the elastic members 140a and 140b return, to the initial position, the contact part <NUM> that has moved or rotated leftward or rightward with respect to the connection part <NUM>, the contact efficiency of the contact device <NUM> and the cell <NUM> may increase and accordingly, there may be an effect that the efficiency of measuring the characteristics of the cell <NUM> increases. As the contact part <NUM> may maintain the initial state even though measuring the characteristics of the cell <NUM>, the contact device <NUM> may be used regardless of whether the battery case of the cell <NUM> has a chamfered shape or a rectangular shape and thus, the efficiency of the process may increase.

The elastic members 140a and 140b of the contact device <NUM> according to Embodiment <NUM> of the present invention may be provided to be parallel to each other. That is, when the first shaft <NUM> and the second shaft <NUM> of the connection part <NUM> are disposed parallel to each other, the elastic members 140a and 140b may be provided to be parallel to a straight line that connects a center of the first shaft <NUM> and a center of the second shaft <NUM>.

When the pair of elastic members 140a and 140b are parallel to each other, bilateral symmetry may be maintained. Thus, there may be an effect that the contact part <NUM> that has rotated leftward or rightward with respect to the connection part <NUM> easily returns to the initial position.

In order to return the elastic members 140a and 140b to the initial position, a temporal change in shape may occur. When the temporal change in shape is repeated several times, the elastic members 140a and 140b may be deformed. In one example to prevent the deformation of the elastic members 140a and 140b and maintain outer appearances of the elastic members 140a and 140b, the connection part <NUM> of the contact device <NUM> according to Embodiment <NUM> of the present invention may further include a connection pillar <NUM>.

When the connection part <NUM> is viewed from a front side, the connection pillar <NUM> may be provided in a pair to be disposed at sides of the first shaft <NUM>, respectively, while extending to be parallel to each other in the upward-downward direction. The elastic members 140a and 140b may be fitted into the connection pillars <NUM> disposed at the both sides of the first shaft <NUM>, respectively.

When each of the elastic members 140a and 140b has a circular cross section, the connection pillar <NUM> may have a cylindrical shape. However, the shape of the connection pillar <NUM> is not necessarily limited thereto, and the shape of the connection pillar <NUM> may change according to the shape of the elastic members 140a and 140b.

When the length of the connection pillar <NUM> in the upward-downward direction is equal to the length of the elastic members 140a and 140b in the upward-downward direction, the shape of the elastic members 140a and 140b may hardly change according to the rotation and movement of the contact part <NUM>. Thus, the connection pillar <NUM> may have the length in the upward-downward direction shorter than the length of the elastic members 140a and 140b in the upward-downward direction so that the shape of the elastic members 140a and 140b may easily change.

The connection pillar <NUM> may produce effects that the deformation of the elastic members 140a and 140b caused by the repeated changes in shape may be prevented and the outer appearances of the elastic members 140a and 140b may be maintained despite long time use of the contact device <NUM>.

In the contact device <NUM> according to Embodiment <NUM> of the present invention, an angle may be displayed on the outer circumference of the body part <NUM>, and the connection part <NUM> may further include an indicator <NUM>.

As described above, when the body part <NUM> has the cross section of which the upper portion has a semicircular shape when viewed from a front side, the angle displayed on the upper outer circumference may be easily recognized.

Angles between <NUM> degree and <NUM> degrees may be displayed, and angles between <NUM> degree and <NUM> degrees may be displayed at each of left and right sides so as to easily check the degree at which the connection part <NUM> rotates leftward or rightward with respect to the body part <NUM>.

The indicator <NUM> may be provided at one end of the first shaft <NUM>, and may indicate the angle displayed on the outer circumference of the body part <NUM> when the connection part <NUM> rotates leftward or rightward with respect to the body part <NUM>.

The indicator <NUM> may a needle shape having a narrow width so as to easily indicate the angle, and preferably, may have a shape in which a cross section has a width gradually decreasing from top to bottom when viewed from a front side.

There is an effect that when the connection part <NUM> rotates with respect to the body part <NUM> in the left-right direction, a rotation angle of the connection part <NUM> may be checked according to the type of the cell <NUM>. Accordingly, the rotation angle of the connection part <NUM> according to the type of the cell <NUM>. Accordingly, the rotation angle of the connection part <NUM> according to the type of the cell <NUM> may be accumulated as data to be utilized in automation of the contact device <NUM>.

The contact device <NUM> according to Embodiment <NUM> of the present invention may further include a controller in order to automate the contact device <NUM> on the basis of the data accumulated in regard to the rotation angle of the connection part <NUM> according to the type of the cell <NUM>.

The controller may be connected to and operate with the connection part <NUM> and the contact part <NUM> and thus, rotate the connection part <NUM> and the contact part <NUM> according to preset values previously collected. A servo motor that controls the connection part <NUM> and the contact part <NUM> on the basis of a command of the controller may be added.

When an operation of the contact part <NUM> is automatically controlled according to the type of the cell <NUM>, there may be an effect that the efficiency of the process of measuring the characteristics of the cell <NUM> increases.

<FIG> is a plan view schematically illustrating a state in which the cell <NUM> is in contact with the contact device <NUM> according to Embodiment <NUM> of the present invention.

In order to increase the accuracy of the process of measuring the characteristics of the cell <NUM>, it is important that the terminal <NUM> of the contact device <NUM> is in contact with the entirety of the contact surface of the cell <NUM> like the configuration illustrated in <FIG>. In the contact device <NUM> according to Embodiment <NUM> of the present invention, as the connection part <NUM> and the contact part <NUM> rotate independently of each other and the contact part <NUM> moves, the likelihood that the terminal <NUM> of the contact device <NUM> is in contact with the entirety of the contact surface of the cell <NUM> may increase to improve the accuracy of the process of measuring the characteristics of the cell <NUM>.

As the contact part <NUM> is in contact with the cell <NUM> and then restored to the initial shape due to the elastic members 140a and 140b, the contact part <NUM> may be in contact with the cell <NUM> having various shapes without replacement of the contact device <NUM>. Thus, the efficiency of the process of measuring the characteristics of the cell <NUM> may be improved.

The present invention provides a characteristic measuring device <NUM> as Embodiment <NUM>.

<FIG> is a perspective view schematically illustrating the characteristic measuring device <NUM> according to Embodiment <NUM> of the present invention.

The characteristic measuring device <NUM> may measure the characteristics of a pouch type cell <NUM>, such as insulation resistance. Referring to <FIG>, the characteristic measuring device <NUM> according to Embodiment <NUM> of the present invention may include a contact device <NUM>, a base <NUM>, and a pressing device <NUM> as components to fix the pouch type cell <NUM> and measure the characteristics thereof.

A space on which the pouch type cell <NUM> is disposed is necessary to measure the characteristics of the pouch type cell <NUM>. As one example of such a component, the characteristic measuring device <NUM> according to Embodiment <NUM> of the present invention may include the base <NUM>.

The base <NUM> is a component on which the pouch type cell <NUM> of which the characteristics are measured is disposed, and a portion on which the pouch type cell <NUM> is disposed may have a flat top surface for stable arrangement. The base <NUM> may have a rectangular shape including a flat plate so as to minimize factors such as vibration, which reduces stability during the measurement of the characteristics of the pouch type cell <NUM>. However, the base <NUM> is not necessarily limited thereto and may have various shapes as necessary.

A component capable of fixing the pouch type cell <NUM> disposed on the top surface of the base <NUM> during the measurement of the characteristics is required. As one example of such a component, the characteristic measuring device <NUM> according to Embodiment <NUM> of the present invention may include the pressing device <NUM>.

The pressing device <NUM> may be disposed on an upper portion of the base <NUM>, and may press and fix the pouch type cell <NUM> disposed on the base <NUM>. The pressing device <NUM> may have a flat bottom surface so as to fix the pouch type cell <NUM>.

When the pouch type cell <NUM> is disposed on the base <NUM>, the pressing device <NUM> may move from above the base <NUM> toward the pouch type cell <NUM> while a distance between the bottom surface of the pressing device <NUM> and the top surface of the base <NUM> decreases. The pressing device <NUM> may move to the pouch type cell <NUM> disposed on the base <NUM> and then, press the pouch type cell <NUM> to fix the pouch type cell <NUM> during the measurement of the characteristics.

When the measurement of the characteristics of the pouch type cell <NUM> is completed, the pressing device <NUM> may return to an initial position while the distance between the bottom surface of the pressing device <NUM> and the top surface of the base <NUM> increases. When the measurement of the characteristics is completed and the press by the pressing device <NUM> is released, the pouch type cell <NUM> may be removed from the top surface of the base <NUM>.

A component such as a cylinder, for movement of the pressing device <NUM> in the upward-downward direction may be additionally coupled to the pressing device <NUM>.

A component capable of being in contact with the pouch type cell <NUM> is necessary to measure the characteristics of the pouch type cell <NUM>. As one example of such a component, the characteristic measuring device <NUM> according to Embodiment <NUM> of the present invention may include the contact device <NUM>.

Hereinafter, the detailed descriptions of the same components as the components of the contact device <NUM> according to Embodiment <NUM> of the present invention will be omitted.

The contact device <NUM> may include a body part <NUM> in which a connection hole <NUM> is defined, a connection part <NUM> which includes a first shaft <NUM> and a second shaft <NUM>, and a contact part <NUM> in which a coupling hole <NUM> is defined and which includes a terminal <NUM>.

When the contact device <NUM> is in contact with the pouch type cell <NUM> for the measurement of the characteristics of the pouch type cell <NUM>, the connection part <NUM> and the contact part <NUM> of the contact device <NUM> may be rotatable independently of each other in the left-right direction so as to increase the likelihood that the entirety of the contact surface of the pouch type cell <NUM> may be in contact with the terminal <NUM> of the contact device <NUM>. Thus, the accuracy of the process may be improved.

In the contact device <NUM> of the characteristic measuring device <NUM> according to Embodiment <NUM> of the present invention, the coupling hole <NUM> defined in the contact part <NUM> may have a cross section of which a vertical length is longer than the diameter of the second shaft <NUM>. Accordingly, when the pouch type cell <NUM> is in contact with the contact part <NUM>, the contact part <NUM> may be movable, and stress exerted on the contact device <NUM> may be reduced to minimize damage and abrasion of the contact device <NUM>.

The contact device <NUM> of the characteristic measuring device <NUM> according to Embodiment <NUM> of the present invention may further include elastic members 140a and 140b that provide an elastic force so that the contact part <NUM>, which has rotated leftward or rightward with respect to the connection part <NUM>, returns to the initial position. Accordingly, the characteristics of the pouch type cell <NUM> having various shapes may be measured without replacement of the characteristic measuring device <NUM>.

In addition, the characteristic measuring device <NUM> may further include a transfer device such as a conveyor, which is capable of moving the pouch type cell <NUM> to the top surface of the base <NUM>.

The characteristic measuring device <NUM> according to Embodiment <NUM> of the present invention, which measures insulation resistance or the like of the pouch type cell <NUM>, may produce the effects that the contact failure occurring during the measurement of the characteristics may be minimized to improve the accuracy and efficiency of the process of measuring the characteristics the pouch type cell <NUM>.

Claim 1:
A contact device (<NUM>) of a characteristic measuring device (<NUM>) configured to measure characteristics of a cell (<NUM>), the contact device comprising:
a body part (<NUM>) in which a connection hole (<NUM>) having a shape passing through the body part from one surface toward the other surface is defined; characterised by:
a connection part (<NUM>) comprising a first shaft (<NUM>) connected tc the connection hole at one side and a second shaft (<NUM>) provided tc be parallel to the first shaft at the other side; and
a contact part : (<NUM>) having one side at which a coupling hole (<NUM>) is defined, the coupling hole having a shape passing through the contact part from one surface toward the other surface so that the second shaft is coupled therethrough, and the other side provided with a terminal (<NUM>) in contact with the cell,
wherein the connection part is rotatable with respect to the body part by the first shaft,
wherein the contact part is rotatable with respect to the second shaft.