Patent Description:
A secondary battery is a chemical battery that can be used semi-permanently by continuously repeating charging and discharge using an electrochemical reaction, which is classified into a lead-acid battery, a nickel-cadmium battery, a nickel-hydrogen battery, and a lithium secondary battery. Among them, a lithium secondary battery has superior voltage and energy density characteristics compared to other batteries, thereby leading the market for secondary batteries, which is divided into a lithium-ion secondary battery using a liquid electrolyte and a lithium-ion polymer secondary battery using a solid electrolyte, according to the type of electrolyte. This lithium secondary battery is composed of a positive electrode, a negative electrode and an electrolyte, and also the separator is generally positioned between the positive electrode and the negative electrode to prevent a short circuit between the positive electrode and the negative electrode due to their direct contact.

In this separator, various resins comprising a polyolefin-based polymer resins such as polyethylene and polypropylene are used as raw materials, and the raw material is mainly supplied in the form of a roll. When supplying a new raw material due to the exhaustion of the raw material in use, in general, the raw material is continuously supplied by bonding the end portion of the raw material in use and the end portion of the new raw material. An automated bonding device that bonds the raw material in use and the new raw material is already known as a related art as in Patent Document <NUM> below. However, supplied raw material in the form of a roll is initially supplied by attaching a tape to an end portion so as to prevent the roll from unwinding, and there is inconvenience that the tape is manually removed and a part of the roll should be released and inserted into a raw material supply location of the automated bonding device in order to apply the supplied raw material in the form of a roll to the automated bonding device. Further, when the roll is released by the manual work, it is difficult to maintain a tension in the supplied raw material in the form of a roll as it is, and thus a quality of the raw material of the corresponding portion deteriorates.

Therefore, the present inventor studies the roll type raw material supply device capable of automating even a process of removing the tape in the supplied raw material in the form of a roll and supplying the supplied raw material in the form of a roll, corresponding to the automated bonding device, and has completed the present invention in order to solve the above-described problem.

(Patent Document <NUM>) <CIT>
<CIT> discloses a peeling device wherein a first adhesive layer to be adhered to a web terminal part and a second adhesive layer to be adhered to a surface of a paper roll are provided on the rear surface of a mount, the terminal part of the rolled paper is temporarily fixed by sticking a tab having an adhesive layer for paper slicing formed on the surface of the mount, an ear part extending outward from one side of the outer periphery of the adhesive layer is provided on the separator for protecting the adhesive layer for paper slicing.

<CIT> discloses an apparatus for automatically threading the leading end of web spooled on the reel into one end of the conveying passage including a draw-out lever having a web support surface and movable to a first position at which the support surface engages the web spooled on the reel. A nipping finger is provided which is actuatable to trap the leading end of the web against surface when the lever is in its first position. The lever is movable to a second position at which the support surface is spaced from the web spooled on the reel for unspooling the web from the reel. A feed mechanism is made effective after the lever is moved to a second position, and after the nipping finger has been deactuated, for engaging the unspooled web and feeding the leading end thereof into the conveying passage.

In order to solve the above problems, it is an object of the present invention to provide a roll type raw material supply device capable of automatically removing a tape attached to a raw material in the form of a roll and moving so as to supply the end portion of the raw material to a subsequent device.

The present invention provides a roll type raw material supply device including: a raw material mounting unit <NUM> for introducing a roll type raw material R to which a tape T for fixation to an end portion of a raw material is attached; a tape removal unit <NUM> clamping a non-bonding portion B of the tape and separating the tape from the raw material; and a raw material conveying unit <NUM> attaching and moving the raw material.

In one embodiment of the present invention, the raw material mounting unit <NUM> includes a support <NUM> and a first roller <NUM>, wherein the support supports the first roller, and the first roller fixes and rotates the roll type raw material R.

In one embodiment of the present invention, the tape removal unit <NUM> includes a clamp member <NUM> and a first conveying cylinder <NUM>, wherein the clamp member includes a first clamp member 21A and a second clamp member 21B, and the first clamp member is positioned at an outer side than the second clamp member to be in contact with the raw material R and the tape T when driving the device, and when the first clamp member and the second clamp member are spaced apart from each other and then the nonbonding portion B of the tape is positioned between the first clamp member and the second clamp member, the first clamp member and the second clamp member are close to each other to clamp the non-bonding portion of the tape, and the first conveying cylinder moves the clamp member.

In one embodiment of the present invention, the raw material conveying unit <NUM> includes an attachment pad <NUM> and a second conveying cylinder <NUM>, wherein the attachment pad attaches and fixes the end portion of the raw material, and the second conveying cylinder moves the attachment pad.

In one embodiment of the present invention, the non-bonding portion B of the tape T attached to the roll type raw material R has a different color from the raw material and is coated with a film F having greater rigidity than the tape, and the first clamp member 21A includes a color sensor <NUM> for identifying the film.

In one embodiment of the present invention, the first clamp member 21A includes an air eruption hole H2 for erupting air to separate the non-bonding portion B of the tape T from the roll type raw material R.

In one embodiment of the present invention, a portion in the tape that is coated with the film has one or more holes H1 through which air can pass.

In one embodiment of the present invention, the attachment pad <NUM> has a shape in which an attachment surface is in contact with a corner of the end portion of the raw material and is not in contact with the tape when attaching and fixing the end portion of the raw material.

In one embodiment of the present invention, the raw material conveying unit <NUM> further includes a supplementary member <NUM> for supplementing the attachment pad <NUM> so that the attachment surface is in contact with the entire area of the end portion of the raw material after the tape is removed.

In one embodiment of the present invention, the raw material conveying unit <NUM> further includes a support member <NUM> for supporting the other surface of the attachment surface when unwinding the roll type raw material after attaching the raw material.

In one embodiment of the present invention, the roll type raw material supply device further includes one or more second rollers <NUM> for adjusting a tension of the raw material and determining a movement path of the raw material.

The roll type raw material supply device according to the present invention can automatically and effectively remove the tape attached to a roll type raw material, and can cause the end portion of the raw material to move to a desired location without damage such as warping.

In the drawings, the size of each component or a specific part constituting the component is exaggerated, omitted, or schematically illustrated for convenience and clarity of description. Therefore, the size of each component does not fully reflect the actual size. If it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, such description will be omitted.

The present invention relates to a roll type raw material supply device, and in order to describe such a device, <FIG> provides a view schematically showing a roll type raw material supply device according to an embodiment of the present invention.

The roll type raw material supply device according to an embodiment of the present invention may include a raw material mounting unit <NUM>, a tape removal unit <NUM>, and a raw material conveying unit <NUM>, and may include additional components as necessary.

The raw material mounting unit <NUM> is a device for introducing a roll type raw material R, and a tape (not shown in <FIG>) for fixing to the end portion of the raw material is attached to the roll type raw material so as to prevent the roll from unwinding. Here, the "end portion" means the area from a start line (or end line) in the direction (when applied to a device, a machine direction (MD)) of a raw material R, to a line spaced apart by a certain distance and the certain distance is determined by the line in the width direction (when applied to the device, a transverse direction (TD)), where the attachment pad <NUM> and the raw material R are in contact with each other. The width of the tape is sufficient as long as the roll does not unwind, and may be much shorter than the width of the raw material. One tape is attached to a portion around a center of the width of the raw material. The raw material mounting unit <NUM> includes a support <NUM> and a first roller <NUM>, and may include additional components as necessary. The support <NUM> is a device for supporting a first roller <NUM> so that the roll type raw material R may be introduced into the first roller. The first roller <NUM> is a device for fixing and rotating the roll type raw material R.

The raw material R may be supplied while one or more layers of fabrics are rolled in a roll type. When the raw material R is formed of two or more layers of fabrics, the fabric may be a state in which respective layers are attached by an electrostatic attraction. When conveying the raw material R formed of two or more layers of fabrics, it is advantageous to apply in subsequent processes only when the raw material R is conveyed in a state in which each layer is not separated from each other.

The tape removal unit <NUM> is a device for clamping the non-bonding portion of the tape and separating the tape from the raw material. The tape removal unit <NUM> may include a clamp member <NUM> and a first conveying cylinder <NUM>, and may include additional components as necessary. The clamp member <NUM> is a device for clamping the non-bonding portion of the tape. The clamp member <NUM> includes a first clamp member 21A and a second clamp member 21B, wherein the first clamp member 21A is positioned at the outer side than the second clamp member 21B, and is in contact with the raw material R and the tape when driving the device. When the first clamp member 21A and the second clamp member 21B are spaced apart from each other and then the non-bonding portion of the tape is positioned between the first clamp member 21A and the second clamp member 21B, the first clamp member 21A and the second clamp member 21B are in contact with each other to clamp the non-bonding portion of the tape. The first conveying cylinder <NUM> is a device for moving the clamp member <NUM>. The first conveying cylinder <NUM> may achieve the purpose of removing the tape only by causing the clamp member <NUM> to contact the roll type raw material R and move in a direction away from the roll type raw material (a left-right direction in <FIG>), but it also causes the clamp member <NUM> to move in a direction perpendicular thereto (an up-down direction in <FIG>) if necessary.

The raw material conveying unit <NUM> is a device for attaching and moving the raw material. The raw material conveying unit <NUM> includes an attachment pad <NUM> and a second conveying cylinder <NUM>. The attachment pad <NUM> is a device for attaching and fixing the end portion of the raw material. The attachment pad <NUM> attaches and fixes the end portion of the raw material, thereby effectively removing only the tape in a state in which the clamp member <NUM> fixes the end portion of the raw material, and supplying the raw material to a desired location by causing the attachment pad <NUM> to move to unwind the roll. The attachment pad <NUM> may attach the raw material through adsorption or electrostatic force. When the raw material R is formed of two or more layers of fabrics, the attachment pad <NUM> may fix the raw material R in a state in which each layer of the fabrics is attached using electrostatic force, thereby conveying the raw material R in a state in which each layer is not separated from each other. An electrostatic chuck may be used in order to apply the electrostatic force, and if the raw material R may be fixed in a state in which each layer of the fabrics is attached, the type of electrostatic chuck is not particularly limited. According to one embodiment of the present invention, the electrostatic chuck includes a polyimide substrate and a bipolar type electrode, and is driven by applying a voltage of <NUM> kV to <NUM> kV, specifically <NUM> kV to <NUM> kV, and more specifically <NUM> kV to <NUM> kV. Two or more layers of fabrics may be efficiently fixed within the above range.

The second conveying cylinder <NUM> is a device for moving the attachment pad <NUM>. The second conveying cylinder <NUM> causes the attachment pad <NUM> to be in contact with the roll type raw material R and move in a direction away from the roll type raw material R (the left-right direction in <FIG>), and also causes the attachment pad <NUM> to move in a direction perpendicular thereto (the up-down direction in <FIG>) in order to supply the raw material to a desired location. As the second conveying cylinder <NUM>, a <NUM>-axis direction orthogonal robot, which is movable in both an X direction (the left-right direction in <FIG>) and a Z direction (the up-down direction in <FIG>) except for a Y direction (a front-rear direction in <FIG>), may be used, and when the <NUM>-axis orthogonal robot moves in the Y direction, a warping phenomenon of the raw material may occur.

The roll type raw material supply device according to an embodiment of the present invention further includes one or more second rollers <NUM>. The second rollers <NUM> are a device for adjusting the tension of the raw material and deciding a movement path of the raw material. In the roll type raw material supply device, the second rollers <NUM> are disposed in the middle of the movement path of the raw material, thereby preventing a phenomenon in which the tension of the raw material is decreased at a specific portion according to a supply speed of the raw material. The tension of the raw material may be controlled by installing a load cell in the second roller <NUM>, and the warping phenomenon or a break phenomenon of the raw material may be prevented by controlling the tension of the raw material.

In order to specifically describe a process of separating a tape from a roll type raw material and causing the end portion of the raw material to move to a location required for a subsequent step, <FIG> provides a view showing a process in which a roll type raw material supply device is driven sequentially according to an embodiment of the present invention.

As shown in <FIG>, the clamp member <NUM> of the tape removal unit <NUM> moves to a vicinity of the roll type raw material R to identify a location of a tape T from the roll type raw material R which rotates in a counterclockwise direction. Thereafter, as shown in <FIG>, when the location of the tape T is identified, the location of the roll is adjusted so that the clamp member <NUM> may be positioned just below the non-bonding portion of the tape, and then the clamp member <NUM> is in contact with the roll type raw material R. Thereafter, as shown in <FIG>, the roll type raw material is rotated in a clockwise direction so that the non-bonding portion of the tape is positioned between the first clamp member 21A and the second clamp member 21B of the clamp member <NUM>, and when the non-bonding portion of the tape is positioned between the first clamp member 21A and the second clamp member 21B of the clamp member <NUM>, the second clamp member 21B is moved close to the first clamp member 21A so that the clamp member <NUM> clamps the non-bonding portion of the tape. Further, the attachment pad <NUM> moves to the end portion of the raw material to attach and fix the end portion of the raw material. In this case, since the attachment pad <NUM> is not in contact with the tape, the attachment pad <NUM> does not interfere with removal of the tape. As shown in <FIG>, the clamp member <NUM> is spaced apart from the roll type raw material to remove the tape T. Thereafter, as shown in <FIG>, the attachment pad <NUM> is spaced apart from the roll type raw material R to unwind the roll and move the end portion of the raw material. Thereafter, as shown in <FIG>, when the second roller <NUM> is present, the attachment pad <NUM> is moved so that the raw material moves in contact with the second roller <NUM>.

In order to increase the efficiency of removing the tape, the tape coated with the film may be used. <FIG> and <FIG> provide views showing a tape in which a non-bonding portion is coated with a film according to an embodiment of the present invention. <FIG> is a perspective view showing a state in which the tape is viewed obliquely and <FIG> is a plan view showing a state in which the tape is viewed from the top.

Since a generally used tape is transparent, even though the tape is attached to the roll type raw material, the roll type raw material shows the same color as the raw material in appearance even at a location to which the tape is attached, equally at a location to which the tape is not attached. Therefore, the location of the tape may not be easily distinguished visually. If the tape is coated with a film F having a different color from the raw material, the location of the tape may be easily distinguished visually. In an automated device, the film F having the different color is identified by a sensor such as color sensor. As shown in <FIG> and <FIG>, the tape T is separated into a bonding portion A and a non-bonding portion B. The non-bonding portion B of the tape T is a portion where there is no bonding force on the surface that is in contact with the raw material, and when the tape T has the non-bonding portion B, the clamp member <NUM> of the device may easily clamp the tape T. The non-bonding portion B of the tape T is coated with the film F. A lower portion of the non-bonding portion B facing the raw material may also be coated with the film, and an upper portion of the non-bonding portion B, which is an opposite surface thereto, may be coated with the film, and the upper and lower portions of the non-bonding portion B may be coated with the film. Since a transparent tape or a translucent tape is used, there is no problem in identifying the film by the sensor even though the lower portion of the non-bonding portion B is coated with the film, and since a material of the film F may be rather lower in electrostatic attraction with the raw material R than the material of the tape T, it may be more advantageous in separating the non-bonding portion B of the tape from the roll type raw material R. When only the non-bonding portion B is coated with the film F by distinguishing the bonding portion A and the non-bonding portion B, it is easy for the sensor of the device to recognize the size of the non-bonding portion B and decide a location for the clamp member <NUM> to clamp the tape T. As the film F, a material having larger rigidity than the tape T may be used, and for example, a material such as polyethylene terephthalate (PET) may be used. When the material having the large rigidity is used as the film F, the non-bonding portion may be easily raised at once. A thickness of the film may be <NUM> to <NUM>, and preferably <NUM> to <NUM>. A portion coated with the film in the tape may have one or more holes H1 through which air may pass. The hole H1 may reduce the phenomenon in which the raw material and the non-bonding portion are in close contact with each other by the electrostatic attraction, and when the non-bonding portion B of the tape T is spaced apart from the roll type raw material R by artificially blowing the wind, the air passes between the holes H1, thereby preventing the non-bonding portion B of the tape T from excessively separating beyond a space between the first clamp member 21A and the second clamp member 21B.

In order to describe the location for the color sensor, <FIG> provides a view showing the clamp member including the color sensor according to an embodiment of the present invention.

When the film F having the different color is attached to the non-bonding portion B of the tape T, the clamp member <NUM> may include a color sensor <NUM> in order to recognize the location of the film F and adjust the location of the clamp member <NUM>, and the color sensor <NUM> may be positioned on a surface facing the roll type raw material R of the first clamp member 21A or the tape T in order for the color sensor <NUM> to be effectively operated. If the film F may be identified with a high sensitivity, the type of color sensor <NUM> is not particularly limited.

In order to describe the location for the air eruption hole, <FIG> provides a view showing the clamp member including the air eruption hole according to an embodiment of the present invention.

In the case of the roll type raw material R and the non-bonding portion B of the tape T, even though the non-bonding portion B has no bonding force, the phenomenon in which the raw material R and the non-bonding portion B are in close contact with each other by the electrostatic attraction may occur, and when artificially blowing the wind to the space between the roll type raw material R and the non-bonding portion B, the non-bonding portion B may be easily spaced apart from the roll type raw material R. The wind may be generated by erupting the air from an air eruption hole H2 positioned in the clamp member. The air eruption hole H2 is connected to a device (not shown) that injects the air. In order to effectively separate the non-bonding portion B, it may be preferable that the air eruption hole H2 is formed to be close to the non-bonding portion B of the tape T in the first clamp member 21A as possible as shown in <FIG>.

In order to describe a state in which the clamp member and the attachment pad are in contact with the roll type raw material just before removing the tape, <FIG> provides a plan view showing a state in which the clamp member and the attachment pad are in contact with the roll type raw material just before removing the tape according to an embodiment of the present invention, and <FIG> provides a perspective view showing a state in which the first clamp member is in contact with the raw material before clamping the non-bonding portion of the tape according to an embodiment of the present invention.

In general, one tape T is attached to the vicinity of a width center of the roll type raw material R, and the tape is bonded so that the bonding portion A goes through a start line L of the roll type raw material. In order to remove the tape, first, as shown in <FIG>, the first clamp member 21A is in contact with the roll type raw material R in the state of being adjacent to the end of the non-bonding portion of the tape, the first clamp member 21A moves toward the non-bonding portion B of the tape and is placed at a lower end of the first clamp member as shown in <FIG>, and the non-bonding portion B of the tape is positioned between the first clamp member and the second clamp member. Just before removing the tape, the first clamp member 21A among the clamp members <NUM> is in contact with the roll type raw material R in the state in which the clamp member <NUM> clamps the non-bonding portion B of the tape T, and the attachment pad <NUM> is in contact with the roll type raw material R in order to clamp the roll type raw material R so that the roll type material R is not unwound. In this case, in order to effectively remove the tape by separating the clamp member <NUM>, it is important that the attachment pad <NUM> is not in contact with the tape. The shape of the attachment surface of the attachment pad <NUM> is not particularly limited as long as the roll type raw material R is not unwound and is not in contact with the tape, but covering the periphery of the tape as much as possible can prevent the deformation of the raw material at most by removing the tape. In addition, since the attachment pad <NUM> serves to prevent the roll type raw material from unwinding when removing the tape and also move the end portion of the raw material, if the attachment pad <NUM> clamps a corner of the end portion of the raw material, the phenomenon in which the corner is bent while moving may be prevented. In <FIG>, one exemplary shape of the attachment pad <NUM> is presented, and in such a shape, the attachment pad <NUM> is in contact with the corner of the end portion of the raw material and is not in contact with the tape.

In order to describe the supplementary member, <FIG> and <FIG> provide view showing the raw material conveying unit including the supplementary member according to an embodiment of the present invention.

Since the attachment pad <NUM> serves to clamp the raw material so as to prevent the roll type raw material from unwinding when removing the tape, the attachment pad <NUM> has a shape in which the attachment pad <NUM> is not in contact with the tape. The attachment pad <NUM> does not cover the entire area of the end portion of the raw material due to such a shape, and this causes a problem in that when the attachment pad <NUM> moves the end portion of the raw material, the end portion of the raw material is not sufficiently fixed. The raw material conveying unit <NUM> may further include a supplementary member <NUM>, and the supplementary member <NUM> supplements the attachment pad <NUM> so that the attachment surface is in contact with the entire area of the end portion of the raw material after the tape is removed. Since the area to be supplemented is determined, the shape of the supplementary member <NUM> is not diversified, but the supplementary member <NUM> may be applied in various directions. <FIG> and <FIG> present an exemplary application direction of the supplementary member <NUM>.

In order to describe the support member, <FIG> provides a view showing the raw material conveying unit including the support member according to an embodiment of the present invention.

Claim 1:
A roll type raw material supply device comprising:
a raw material mounting unit (<NUM>) for introducing a roll type raw material (R) to which a tape (T) for fixing to the end portion of the raw material is attached;
a tape removal unit (<NUM>) for clamping a non-bonding portion of the tape (B) and separating the tape (T) from the raw material;
the roll type raw material supply device being characterized by further comprising
a raw material conveying unit for attaching and moving the raw material.