KR102571777B1 - Battery cell case measuring apparatus - Google Patents

Abstract

The present invention is a battery cell case measuring device, in which a metal material is placed, and a pair of gripping parts disposed facing each other at a distance from each other; a first transfer unit for transporting a metal material placed on one gripping unit among the pair of gripping units to a lower portion of the measurement area; an elevating unit for elevating the metal material transported by the first transfer unit; a measuring unit contacting the outer surface of the metal material raised by the lifting unit to measure processing precision; and a second transfer unit for transferring the metal material measured by the measuring unit to the other gripping unit among the pair of gripping units.

Description

Battery cell case measuring device {BATTERY CELL CASE MEASURING APPARATUS}

The present invention relates to a battery cell case measuring device, and more particularly, to a measuring device for determining whether a metal case protecting a battery cell is manufactured under predetermined design conditions.

In general, a battery cell that stores electricity generated by a generator or supplied from an external power source and supplies electricity to other electrical systems is accommodated in a case made of a metal material such as aluminum.

For example, the case has a space in which a battery cell can be accommodated, and the front and rear sides in the longitudinal direction may have an open rectangular box shape, and the open front and rear are blocked by a separate cover. It can be.

Such a metal case may be manufactured by a known extrusion method. That is, by the extrusion method, the metal material may be processed into a hollow pipe having a rectangular cross section and drawn, and the drawn metal material may be cut into a predetermined length by a cutting device. Then, the metal material may have a shape shown in FIG. 10 .

In order to manufacture a case in which the battery cell can be accommodated, the metal material having the above shape must be processed to a length and thickness that meets the standard, and in addition, each side that divides the battery cell accommodation space must have tolerances. It must be processed to have satisfactory perpendicularity, flatness, and contour.

If the perpendicularity, flatness, and contour of the metal material have processing dimensions that do not satisfy the predetermined tolerance, a problem in that the heat dissipation efficiency or charging efficiency of the battery cell is lowered, and also may cause a voltage drop phenomenon. .

Therefore, it can be said that it is important that the case in which the battery cell is accommodated is manufactured based on design conditions that protect the battery cell and at the same time do not degrade the performance of the battery cell.

However, a problem arises in that surfaces partitioning the battery cell accommodating space are deformed in the process of transporting and processing the metal material in a number of processes.

In particular, when the metal material is made of aluminum, it is easily deformed by external conditions (temperature, humidity, etc.), and the area of each surface forming the battery cell accommodation space is made large depending on the size and use of the battery. If it is, there is a disadvantage that part of the surface is easily deformed. For reference, the size of a battery cell case used in a vehicle is several times larger than that of a battery cell case used in a small electronic device such as a smartphone, a laptop computer, or a camcorder.

Therefore, the present applicant, in order to solve the above problems, developed a measuring device for measuring a metal material whose longitudinal end is chamfered and chamfered.

However, the conventional measuring device has a problem in that it is difficult to obtain an accurate measurement value due to a phenomenon in which the metal material moves while the measuring probe contacts the outer surface of the metal material. That is, since the conventional measuring device has a configuration in which the outer surface of the metal material is contacted with a measuring probe in a state where the metal material is simply placed on the base, there is a problem in that the metal material is shaken during this process, making accurate measurement difficult.

Therefore, the present applicant has proposed the present invention in order to solve the above problems, and prior art documents related thereto include Korean Patent Publication No. 2020-0112079 'A method for manufacturing a battery cell case and a battery manufactured by this method There is a cell case.

The present invention is to solve the above problems, and to measure the battery cell case configured to prevent the flow of the metal material in the longitudinal direction and the width direction so that the processing precision of the metal material transferred after the chamfering and chamfering process can be accurately measured. The purpose is to provide a device.

The present invention is a battery cell case measuring device, in which a metal material is placed, and a pair of gripping parts disposed facing each other at a distance from each other; a first transfer unit for transporting a metal material placed on one of the pair of gripping units to a lower portion of the measuring area; an elevating unit for elevating the metal material transported by the first transfer unit; a measuring unit contacting the outer surface of the metal material raised by the lifting unit to measure processing precision; and a second transfer unit for transferring the metal material measured by the measuring unit to the gripping unit disposed on the other side of the pair of gripping units.

In addition, the gripping unit may include a gripper unit that rotates the metal material in a state in which both sides of the metal material are respectively gripped in the longitudinal direction of the metal material.

In addition, the gripper unit may include a first pressing member pressing a bottom surface of the metal material; a second pressing member disposed facing the first pressing member and pressing an upper surface of the metal material; and an adsorption member disposed between the first pressing member and the second pressing member to adsorb the other side of the metal material.

In addition, the first transfer unit supports a bottom surface of the metal material laid down by the gripper, and includes a pair of first forks disposed at a predetermined distance from each other; and a first suction member provided on the first fork and adsorbing a lower surface of the metal material.

In addition, the elevation unit may include a main plate disposed below the measurement area; auxiliary plates respectively disposed on both sides of the main plate; Measurement probes provided on the main plate and the auxiliary plate to contact the lower surface of the metal material; and a second suction member provided on the main plate or the auxiliary plate and adsorbing the lower surface of the metal material, wherein the main plate and the auxiliary plate are spaced apart so that the pair of first forks can be disposed. may be separated from each other.

In addition, the measuring unit is provided to be able to linearly reciprocate toward the upper surface of the metal material raised by the lifting unit, and a first measuring plate provided with a measuring probe contacting the upper surface of the metal material; a second measuring plate provided to be able to linearly reciprocate toward one side of the metal material raised by the lifting part and having a measuring probe contacting the one side of the metal material; and a third measuring plate provided to be able to linearly reciprocate toward the other side surface of the metal material raised by the lifting part and having a measuring probe contacting the other side surface of the metal material.

In addition, the second transfer unit is disposed to face the first transfer unit, a pair of second forks inserted into the gap between the main plate and the auxiliary plate to support the lower surface of the metal material for which the measurement is completed; and a third suction member provided on the second fork and adsorbing the lower surface of the metal material.

The controller may further include a control unit configured to receive measurement values in real time from measurement probes provided in the elevation unit and the measurement unit and analyze the measurement value distribution.

In addition, the control unit may transmit an abnormal signal to a worker when a measurement value measured by the measurement probe is transmitted at a predetermined frequency or more.

In addition, the measuring probes respectively provided in the lifting part and the measuring part may measure the total length of the metal material and the thickness, contour, perpendicularity, and flatness of each surface constituting the metal material.

The battery cell case measuring device according to the present invention provides a configuration in which the metal material is prevented from flowing by a vacuum adsorption method while the metal material is transferred to measure the processing accuracy of the metal material that has been chamfered and chamfered. The processing precision of the material can be accurately measured.

In addition, the battery cell case measuring device according to the present invention increases the reliability of measuring the processing accuracy of metal materials, enables accurate selection of good products and defective products, and thereby secures the stability and performance of the battery cell.

In addition, since the battery cell case measuring apparatus according to the present invention provides a configuration for simultaneously transporting a metal material to be measured and a metal material for which measurement is completed, the measurement operation can be quickly and accurately performed.

1 is a perspective view of a battery cell case measuring device according to an embodiment of the present invention.
Figure 2 is a perspective view showing the inside of the measuring device shown in Figure 1;
Figure 3 is a plan view of the measuring device shown in Figure 2;
Figure 4 is a right side view of the measuring device shown in Figure 2;
5 is a perspective view showing a state in which a metal material in an upright state is disposed on a holding part according to an embodiment of the present invention.
6 is a perspective view showing a state in which a metal material is placed in a first transfer unit with the metal material laid down by a grip unit according to an embodiment of the present invention;
7 is a perspective view showing configurations of a gripping unit and a first transfer unit according to an embodiment of the present invention;
8 is a plan view schematically showing a configuration of an elevation unit according to an embodiment of the present invention;
9 is a side view showing a state in which the measuring unit and the lifting unit measure the processing precision of a metal material according to an embodiment of the present invention.
10 is a perspective view of a metal material;

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below and will be implemented in various forms different from each other, only these embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention pertains. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims.

Hereinafter, a method of manufacturing a metal case and a battery cell case manufactured by the method according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 10 . In describing the present invention, detailed descriptions of related well-known functions or configurations are omitted in order not to obscure the subject matter of the present invention.

1 is a perspective view of a battery cell case measuring device according to an embodiment of the present invention, FIG. 2 is a perspective view showing the inside of the measuring device shown in FIG. 1, and FIG. 3 is a plan view of the measuring device shown in FIG. 4 is a right side view of the measuring device shown in FIG. 2, FIG. 5 is a perspective view showing a state in which a metal material in a standing state is disposed on the gripping part according to an embodiment of the present invention, and FIG. It is a perspective view showing a state in which the metal material is placed on the first transfer unit with the metal material laid down by the grip unit according to an embodiment of the present invention, and FIG. 7 is a perspective view showing the configuration of the grip unit and the first transfer unit according to an embodiment of the present invention. 8 is a plan view schematically showing the configuration of an elevation unit according to an embodiment of the present invention, and FIG. 9 is a plan view showing a measuring unit and an elevation unit measuring the processing precision of a metal material according to an embodiment of the present invention. It is a side view, and FIG. 10 is a perspective view of a metal material.

As shown in FIGS. 1 to 4, in the battery cell case measuring device 100 according to an embodiment of the present invention, a metal material 10 (see FIG. 12) is placed and disposed facing each other at a distance from each other. A pair of gripping parts 110 and 110'; a first transfer unit 130 for transporting the metal material 10 placed on one gripping unit 110 of the pair of gripping units 110 and 110' to a lower portion of the measurement area ar; a lifting unit 150 that lifts the metal material 10 transported by the first transfer unit 130; a measuring unit 170 that is in contact with the outer surface of the metal material 10 raised by the lifting unit 150 to measure processing accuracy; And a second transfer unit 190 for transferring the metal material 10 that has been measured by the measuring unit 170 to the other gripping unit 110' among the pair of gripping units 110 and 110'. can

First, the measuring device 100 according to an embodiment of the present invention, as shown in Figure 1, may be provided inside the rectangular casing (C).

The casing (C) serves to protect the device and prevent the measurement accuracy of the metal material 10 from being lowered from external environmental factors at the same time.

As shown in FIG. 1, an inlet D1 into which the metal material 10 is injected is provided on one side of the upper surface of the casing (C), and the metal introduced into the casing (C) is provided on the other side of the upper surface of the casing (C). A discharge port D2 through which the raw material 10 is discharged is provided.

Therefore, the material conveying device (not shown) provided on the ceiling side of the worker adsorbs the metal material 10 after the chamfering and chamfering process is completed, and then inserts it into the casing C through the inlet D1, Conversely, the metal material 10 on which the measurement is completed may be taken out of the casing C through the outlet D2.

As described above, the pair of gripping parts 110 and 110' may be disposed facing each other at a distance from each other. Of the pair of gripping parts 110 and 110', the gripping part 110 disposed on one side is disposed below the input port D1, and the gripping part 110' disposed on the other side is disposed below the discharge port D2. can be placed in

The gripping unit 110 disposed on one side may grip the metal material 10 being transferred through the inlet D1. Conversely, the gripper 110 disposed on the other side may grip the metal material 10' to be taken out through the outlet D1.

For reference, the metal material 10 injected into the casing C through the inlet D1 can be delivered to the gripper 110 disposed on one side in a standing posture, as shown in FIG. 5 . there is.

Here, the upright posture may be referred to as a posture in which two outer surfaces having a relatively small area among the four outer surfaces constituting the metal material 10 are respectively disposed on the upper and lower sides.

The reason why the metal material 10 is put into the casing C in the upright position described above is to prevent the metal material 10 from interfering with other devices in the process of transferring the metal material 10. am. That is, in the process of transporting the metal material 10, the volume area occupied by the metal material 10 is simplified, and in addition, the gripping parts 110 and 110' for gripping the metal material 10 and the material conveying device provided on the ceiling This is to ensure that the metal material 10 can be easily gripped or adsorbed.

If the metal material 10 is transferred in a lying position, an adsorption member for adsorbing the metal material 10 must be further provided in the material transport device, and the size of the inlet D1 and the outlet D2 is also expanded However, the size of the gripping parts 110 and 110' also increases, resulting in a problem in that the measuring device 100 becomes bloated as a whole.

Therefore, it can be said that it is important to transport the metal material 10 in a standing posture, and to insert it into the casing C or take it out of the casing 10 while maintaining the posture.

As shown in FIG. 7, the gripping parts 110 and 110' are gripper units 111 that turn the metal material 10 at an angle of 90 degrees while holding both sides of the metal material 10 in the longitudinal direction, respectively. ) may be included.

The gripper unit 111 turns the metal material 10 being transported in a standing position to transform it into a lying position, or turns the metal material 10 being transferred in a lying position to transform it into a standing position can make it

The gripper unit 111 includes a first pressing member 111a pressing the bottom surface of the metal material 10; a second pressing member 111b disposed to face the first pressing member 111a and pressurizing an upper surface of the metal material 10; and a suction member 111c disposed between the first pressing member 111a and the second pressing member 111b to absorb the other side of the metal material 10 .

The first pressing member 111a and the second pressing member 111b may be referred to as components in contact with the bottom or top surface having a relatively large area among the four outer surfaces constituting the metal material 10. .

The first pressing member 111a and the second pressing member 111b may linearly reciprocate toward the outer surface of the metal material 10 by receiving power from a known actuator.

Accordingly, the metal material 10 may be fixed while being pressed by the first pressing member 111a and the second pressing member 111b that linearly reciprocate.

The adsorption member 111c may be referred to as a component that vacuums the outer surface of the metal material 10 in contact with the outer surface of the metal material 10 that is not in contact with the first pressure member 111a and the second pressure member 111b.

Meanwhile, the gripper unit 111 configured as described above may be connected to the support bar (b) and rotated together with the support bar (b) by a driving source that rotates the support bar (b).

The metal material 10 in an upright position introduced through the inlet D1 may be gripped by the first pressing member 111a and the second pressing member 111b. At this time, the adsorption member 111c may adsorb the other side of the metal member 10 .

In the above state, when the gripper 111 is rotated at an angle of 90 degrees by the operation of the support bar (b), as shown in FIG. 6, the metal material 10 assumes a lying posture. Then, the metal The material 10 is placed on a first transfer unit 130 to be described later. At this time, the first pressing member 111a and the second pressing member 111b may be retracted in the direction of releasing the pressure on the outer surface of the metal material 10 .

The adsorption member 111c may maintain an adsorption state until the first adsorption member 132 of the first transfer unit 130 adsorbs the bottom portion of the metal material 10, which will be described later.

The first transfer unit 130 serves to receive the metal material 10 in a flat state and transfer it to the lifting unit 150 to be described later, and as shown in FIGS. 3 and 7, the gripper 111 A pair of first forks 131 that support the lower surface of the metal material 10 laid down by ) and are disposed at a predetermined distance from each other; and a first suction member 132 provided on the first fork 131 and adsorbing the lower surface of the metal material 10 .

The first fork 131 may be provided on a frame that is moved up and down and linearly reciprocated, and as described above, serves to support the lower surface of the metal material 10 whose position is changed by the gripper 111.

A plurality of first suction members 132 may be provided on one first fork 131 . For reference, in one embodiment of the present invention, it is shown on the drawing that each is provided on one side and the other side of the longitudinal direction of the first fork 131.

The first suction member 132 serves to prevent the metal material 10 from flowing while the metal material 10 is transferred toward the elevation part 150 by the first fork 131 . If the metal material 10 flows in the process of being transported toward the elevation unit 150, an accurate measurement operation cannot be performed in the measurement unit 170 to be described later.

In order to accurately measure the metal material 10 in the measuring unit 170, the metal material 10 having a lying position after being turned by the gripping unit 10 arrives at the measuring unit 170 It can be said that it is very important not to flow until the moment.

Therefore, the adsorption member 111c of the above-described gripper 111, until the first adsorption member 132 of the first transfer unit 130 adsorbs the bottom surface of the metal material 10, the metal material 10 ) is preferably adsorbed continuously.

The lifting unit 150 receives the metal material 10 transported by the first transfer unit 130 and transfers it to the measuring unit 170 to be described later, and at the same time measures the processing accuracy of the bottom surface of the metal material 10 can be considered a component.

As shown in FIGS. 8 and 9 , the elevation unit 150 includes a main plate 151 disposed under the measurement area ar; auxiliary plates 152 respectively disposed on both sides of the main plate 151; a measuring probe 153 provided on the main plate 151 and the auxiliary plate 152 to contact the lower surface of the metal material 10; and a second suction member 154 provided on the main plate 151 or the auxiliary plate 152 to absorb the lower surface of the metal material 10 .

The main plate 151 and the auxiliary plate 152 have a structure capable of moving up and down while being disposed under a measuring unit 170 to be described later. For example, it may be provided on top of an elevating frame (f) that is moved up and down by receiving power from a known actuator, and thus, it may be raised or lowered in conjunction with the elevation of the elevating frame (f).

The main plate 151 and the auxiliary plate 152 may maintain a lowered state when receiving the metal material 10 being transported by the first transfer unit 130 . Also, when the metal material 10 is transferred to the measuring unit 170, it may be raised.

Meanwhile, when the second transfer unit 190 to be described later transfers the metal material 10 that has been measured by the measurement unit 170, the main plate 151 and the auxiliary plate 152 may descend again.

As shown in FIG. 8 , the main plate 151 and the auxiliary plate 152 are a pair of first forks 131 of the first transfer unit 130 or a second fork of the second transfer unit 190. 192 can be spaced apart from each other with a gap that can be inserted and disposed.

The pair of first forks 131 of the first transfer unit 130 may be moved forward to a space between the main plate 151 and the auxiliary plate 152 while supporting the metal material 10 .

Then, the metal material 10 may be placed on the main plate 151 and the auxiliary plate 152 . To be precise, the metal material 10 may be placed on the measuring probes 153 respectively provided on the main plate 151 and the auxiliary plate 152 .

In this state, the second suction member 154 provided on the main plate 151 or the auxiliary plate 152 may adsorb the lower surface of the metal material 10 . For reference, in one embodiment of the present invention, although the second suction member 154 is shown in FIG. 8 as being provided only on the auxiliary plate 152, it is not limited thereto. That is, it may be provided on the main plate 151 . In addition, the number or position of the measurement probes 153 provided on the main plate 151 and the auxiliary plate 152 may also be set in various ways according to the area and measurement range of the metal material 10.

When the second suction member 154 adsorbs the lower surface of the metal material 10, the first suction member 132 of the first transfer unit 130 may release the suction of the lower surface of the metal material 10. In this state, the pair of first forks 131 may be reversed and returned to the original position in order to support another metal material 10 .

The measurement unit 170 may be referred to as a component for measuring processing accuracy of the upper surface, one side surface, and the other side surface of the metal material 10 .

As shown in FIG. 9 , the measuring unit 170 is provided so as to be capable of rectilinear reciprocating movement toward the upper surface of the metal material 10 raised by the lifting part 150, and the metal material 10 A first measuring plate 171 provided with a measuring probe 171a contacting an upper surface of the first measuring plate 171; A second measuring probe 172a is provided to be capable of linear reciprocating movement toward one side of the metal material 10 raised by the lifting part 150 and is in contact with one side of the metal material 10. measuring plate 172; and a measuring probe 173a which is capable of rectilinear reciprocating movement towards the other side of the metal material 10 raised by the lifting part 150 and which is in contact with the other side of the metal material 10. 3 measuring plate 173; may be included.

The first measurement plate 171, the second measurement plate 172, and the third measurement plate 173 each have a structure capable of linear reciprocating motion by receiving power from a known actuator (not shown). For reference, the configuration in which the first measurement plate 171 to the third measurement plate 173 are reciprocally reciprocated is a configuration that can be easily performed by those skilled in the art, so a detailed description of the configuration will be omitted.

The first measurement plate 171 to the third measurement plate 173 preferably have an area corresponding to the outer surface of the metal material 10 facing each other, and the above-described measurement probes 171a, 172, and 173a A plurality of may be provided, respectively.

The processing precision of the metal material 10 can be measured by the measuring unit 170 configured as described above and the lifting unit 150 described above. At this time, since the bottom surface of the metal material 10 maintains a state of adsorption to the adsorption member 154 provided on the elevation part 150, the measurement probes 171a, 172a, and 173c provided on the measurement unit 170 The flow of the metal material 10 can be prevented in the process of contacting the outer surface of (10). Accordingly, the measurement probes 171a, 172a, and 173c provided in the measurement unit 170 may be accurately adhered to the planar portion of the metal material 10 to be measured.

The measuring unit 170 and the lifting unit 150 determine the total length of the metal material 10 and the thickness, contour, perpendicularity, and flatness of each surface constituting the metal material 10. can be measured

On the other hand, in the measuring device 100 according to an embodiment of the present invention, measurement values are obtained from the measuring probes 171a, 172a, and 173a provided on the measuring unit 170 and the measuring probe 153 provided on the lifting unit 150. It may further include a control unit for receiving and analyzing the measurement value distribution.

The control unit may analyze a measurement value distribution based on the measurement values measured by the measurement unit 170 and the elevation unit 150 and display the data on the display unit.

Then, the operator can determine whether or not the metal material 10 is defective based on the data displayed on the display unit. In addition, the control unit may transmit an abnormal signal to a worker through a display unit or a known terminal when a measurement value measured by the measurement probe is transmitted at a predetermined frequency or more.

Meanwhile, as shown in FIG. 3 , the second transfer unit 190 may be disposed to face the first transfer unit 130 .

The second transfer unit 190 has substantially the same configuration as the first transfer unit 130 except for a different arrangement relationship. That is, the second transfer unit 190 includes a second fork 191 supporting the bottom surface of the metal material 10 passing through the measuring unit 170; and a third suction member 192 provided on the second fork 191 and adsorbing the lower surface of the metal material 10 .

The second transfer unit 190 configured as described above receives the metal material 10' that has been measured by the measuring unit 170 from the lifting unit 150 and is placed on the other side of the pair of gripping units 110 and 110' It serves to deliver to the gripping portion 110 '.

When the measurement is completed by the measuring unit 170, the main plate 151 and the auxiliary plate 152 of the lifting unit 150 are lowered. Then, the pair of second forks 191 of the second transfer unit 190 may be moved forward and disposed in a space between the main plate 151 and the auxiliary plate 152 .

In this state, the pair of second forks 191 are raised to come into contact with the lower surface of the metal material 10', which has been measured, and at the same time, the third suction member 192 adsorbs the lower surface of the metal material 10'. can do.

When the third adsorption member 192 adsorbs the bottom surface of the metal material 10', the adsorption member 154 of the elevation unit 150 adsorbs and releases the bottom surface of the metal material 10'.

Then, the pair of second forks 191 may be reversed and returned to the original position. Then, the metal material 10' in a laid state is moved in the direction in which the gripper 110' disposed on the other side is disposed.

The gripping unit 110' disposed on the other side may grip the metal material 10' in a laid state transported by the second transfer unit 190. At this time, the adsorption member of the gripper 110' disposed on the other side adsorbs one side of the metal material 10', and the third portion of the second transfer unit 190 adsorbing the bottom surface of the metal material 10'. The adsorption member 192 may release adsorption.

When the gripping part 110' is rotated in the above state, as shown in FIG. 5, the posture of the metal material 10' in a lying state can be changed to a standing state.'

The metal material 10' having a standing posture by the gripper 110' disposed on the other side may be taken out through the outlet D2) by a material transfer device (not shown) and then transferred to the next process. there is.

On the other hand, while the metal material 10' whose measurement has been completed by the measuring unit 170 is transferred to the holding unit 110' disposed on the other side via the lifting unit 150 and the second transfer unit 190, The metal material 10 may be transferred to the measurement unit 170 via the gripping unit 110 disposed on one side, the first transfer unit 130 and the elevation unit 150 sequentially. That is, since the measuring device 100 according to an embodiment of the present invention provides a configuration for simultaneously transporting the metal material 10 to be measured and the metal material 10' that has been measured, the measurement operation is performed quickly and accurately. can be done

Although specific embodiments according to the present invention have been described so far, various modifications are possible without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the described embodiments and should not be defined, but should be defined by not only the scope of the claims to be described later, but also those equivalent to the scope of these claims.

100: measuring device 110, 110 ': gripping part
111: gripper unit 111a: first pressing member
111b: second pressing member 120: first transfer unit
131: first fork 132: first adsorption member
150: lifting part 151: main plate
152: auxiliary plate 153: measuring probe
154: second adsorption member 170: measuring unit
171: first measuring plate 172: second measuring plate
173: third measurement plate 190: second transfer unit
191: second fork 193: third adsorption member
C: Casing D1: Inlet
D2: outlet 10, 10': metal material

Claims (10)

As a battery cell case measuring device,
A pair of gripping parts on which a metal material is placed and disposed facing each other at a distance from each other;
a first transfer unit for transporting a metal material placed on one of the pair of gripping units to a lower portion of the measuring area;
an elevating unit for elevating the metal material transported by the first transfer unit;
a measuring unit contacting the outer surface of the metal material raised by the lifting unit to measure processing accuracy; and
A second transfer unit for transferring the metal material measured by the measuring unit to the gripping unit disposed on the other side among the pair of gripping units;
The metal material has a space in which a battery cell can be accommodated, and has a rectangular box shape with open front and rear ends in the longitudinal direction,
The gripping unit includes a gripper unit for turning the metal material in a state in which both sides of the metal material are respectively gripped in the longitudinal direction,
The gripper unit may include: a first pressing member for pressing a bottom surface having a relatively large area among four outer surfaces constituting the metal material; a second pressing member disposed facing the first pressing member and pressing an upper surface having a relatively large area among four outer surfaces constituting the metal material; And a suction member disposed between the first pressing member and the second pressing member and adsorbing the other side of the metal material that is not in contact with the first pressing member and the second pressing member,
The first transfer unit may include a pair of first forks which support the lower surface of the metal material laid down by the gripper and are spaced apart from each other; And a first suction member provided on the first fork and adsorbing a bottom surface of the metal material;
The elevation unit may include a main plate disposed below the measurement area and raised or lowered in conjunction with the elevation of an elevation frame that is moved by receiving power from an actuator; auxiliary plates disposed on both sides of the main plate and rising or descending in conjunction with the elevation of the elevating frame; Measurement probes provided on the main plate and the auxiliary plate to contact the lower surface of the metal material; and a second suction member provided on the main plate or the auxiliary plate and adsorbing the lower surface of the metal material, wherein the main plate and the auxiliary plate are spaced apart so that the pair of first forks can be disposed. separated from each other,
The measuring unit may include a first measuring plate provided with a linear reciprocating movement toward the upper surface of the metal material raised by the lifting part and having a measuring probe contacting the upper surface of the metal material; a second measuring plate provided to be able to linearly reciprocate toward one side of the metal material raised by the lifting part and having a measuring probe contacting one side of the metal material; and a third measuring plate capable of rectilinear reciprocating movement towards the other side of the metal material raised by the lifting unit and provided with a measuring probe contacting the other side of the metal material. Cell case measuring device.
delete delete delete delete delete According to claim 1,
The second transfer unit is disposed facing the first transfer unit,
a pair of second forks inserted into the gap between the main plate and the auxiliary plate to support a lower surface of the metal material for which measurement is completed; and
A battery cell case measuring device comprising a; third suction member provided on the second fork and adsorbing the lower surface of the metal material.
According to claim 7,
The battery cell case measuring device further comprising a; control unit that receives measurement values in real time from measurement probes provided in the elevation unit and the measurement unit and analyzes the measurement value distribution.
According to claim 8,
The control unit,
Battery cell case measuring device characterized in that when the measured value measured from the measuring probe is transmitted at a predetermined frequency or more, an abnormal signal is transmitted to the operator.
According to claim 7,
The measuring probes provided respectively in the lifting part and the measuring part,
A battery cell case measuring device, characterized in that for measuring the overall length of the metal material, and the thickness, contour, perpendicularity, and flatness of each surface constituting the metal material.

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