KR20060025276A - Slitting apparatus for manufacturing lithium secondary battery employing substrate guiding device - Google Patents

Abstract

The slitting apparatus for manufacturing a lithium secondary battery employing the electrode plate induction device according to the present invention includes a cutting device for cutting an electrode plate at an intermediate cutting portion while a roll for guiding the electrode plate and an electrode plate guided by the roll contact; And a winding roll for winding the electrode plate cut by the cutting device, and further comprising an electrode plate inducing device for safely guiding the electrode plate to the cutting device before the electrode plate guided by the roll is input to the cutting device.

Here, the electrode plate inducing apparatus may be provided with a nip roll for receiving and transferring the electrode plate guided by the roll, and a safety plate installed between the nip roll and the cutting device to safely guide the electrode plate to the cutting device.

Preferably, the safety plate is preferably a rectangular plate shape.

In addition, the nip roll may be removed after the initial portion of the electrode plate is cut by a predetermined length in the cutting device.

Slitting, Nip Roll, Safety Plate

Description

SLITTING APPARATUS FOR MANUFACTURING LITHIUM SECONDARY BATTERY EMPLOYING SUBSTRATE GUIDING DEVICE}

1 is a view showing a conventional slitting apparatus for manufacturing a lithium secondary battery.

2 is a view showing a slitting device for manufacturing a lithium secondary battery employing an electrode plate induction device according to the present invention.

FIG. 3 is a plan view of a slitting apparatus for manufacturing a lithium secondary battery employing the electrode plate inducing apparatus according to the present invention of FIG. 2.

<Explanation of symbols for the main parts of the drawings>

1: electrode plate 2: cutting device

3a, 3b, 3c: pre roll 4: nip roll

5: safety valve

The present invention relates to an apparatus for manufacturing a lithium secondary battery, and more particularly, to an apparatus used in a slitting process of cutting an electrode plate to manufacture a lithium secondary battery.

A brief description will be given of a method for producing a lithium secondary battery. First, a long sheet-shaped positive electrode current collector and negative electrode current collector are prepared. In general, aluminum is used as the positive electrode current collector, copper is used as the negative electrode current collector, and the shape of the current collector is formed of foil, mesh, expanded metal, or the like.

Next, a solution of the positive electrode active material slurry and the negative electrode active material slurry is prepared, the positive electrode plate is prepared by coating a solution of the positive electrode active material slurry on both sides of the positive electrode current collector, and the negative electrode plate is coated by coating a solution of the negative electrode active material slurry on both sides of the negative electrode current collector. Manufacture.

When the positive electrode plate and the negative electrode plate is completed by the coating process as described above, the positive electrode plate and the negative electrode plate (hereinafter referred to as 'electrode plate') in the slitting process are cut to a predetermined length and width.

The slitting process of the electrode plate will be described in more detail with reference to FIG. 1. 1 is a view showing a conventional slitting apparatus for manufacturing a lithium secondary battery.

First, the electrode plate 1 is guided to the cutting device 2 via the pre rolls 3a and 3b. The electrode plate 1 guided by the cutting device 2 is determined by the operator, guided accordingly, and cut by the cutting device 2 before being input to the cutting device 2. The electrode plate 1 cut | disconnected by the intermediate cutting part is branched up and down in the free roll 3c, and is respectively wound up by a winding roll (not shown).

The electrode plate wound as described above is then cut into a unit electrode plate having a predetermined length and width.

However, there is a problem in the conventional slitting process for manufacturing a lithium secondary battery as described above.

That is, when the electrode plate 1 is guided to the cutting device 2 to perform the slitting process, the operator determines the intermediate cut portion of the electrode plate 1 to guide the cutting device 2. When the operator determines and guides the intermediate cutout of the electrode plate 1 as described above, the electrode plate 1 cut at the outlet of the cutting device 2 after the electrode plate 1 has been cut by the cutting device 2. There must have been another worker to hold the. When the electrode plate 1 cut | disconnected at the exit of the cutting device 2 is not hold | maintained, the cut | disconnected electrode plate 1 is hard to be guide | induced to the following pre-roll 3c properly.

Therefore, the conventional electrode plate slitting process could not be performed by one person, and because two people had to guide the electrode plate 1 before and after the cutting device 2, the use of manpower was not efficient and lithium 2 The manufacturing cost of the secondary battery also increased.

In addition, when the operator guides the electrode plate 1 to the cutting device 2, a backing phenomenon occurs, i.e., the electrode plate 1 occurs when the electrode plate 1 is input to the cutting device 2. In order to prevent the electrode plate 1 from retreating back when input to the cutting device 2, the operator had to keep pushing the electrode plate 1 until the cutting device 2 passed a predetermined length.

In this process, the part of the electrode plate 1 initially inputted to the cutting device 2 is generally not properly cut at the intermediate cutting part, so a loss occurs that the part of the electrode plate 1 is not used. .

 The present invention has been made to solve the above-mentioned conventional problems, in the slitting process of cutting the electrode plate during the manufacturing process of the lithium secondary battery, a device for properly inducing the electrode plate with a cutting device in front of the cutting device By doing so, it is an object of the present invention to provide a device that enables one worker to perform the slitting process so as to efficiently utilize manpower and reduce manufacturing costs.

In addition, the present invention provides a device that can prevent even a small loss of the electrode plate generated during the slitting process by installing a device for constantly inducing the electrode plate with a cutting device in the slitting process for cutting the electrode plate. For another purpose.

In order to achieve the above object, the slitting device for manufacturing a lithium secondary battery employing the electrode plate induction device according to the present invention is an electrode plate while a roll for guiding the electrode plate and an electrode plate guided by the roll are in contact with each other. Cutting device for cutting the cutting plate at an intermediate cutting portion, and a winding roll for winding the electrode plate cut by the cutting device, and the electrode for safely guiding the electrode plate to the cutting device before the electrode plate guided by the roll is input to the cutting device. It further comprises a plate guide device.

Here, the electrode plate inducing apparatus may be provided with a nip roll for receiving and transferring the electrode plate guided by the roll, and a safety plate installed between the nip roll and the cutting device to safely guide the electrode plate to the cutting device.

As a result, one worker can perform the slitting process so that efficient manpower can be utilized, and the electrode plate of the initial portion that is initially input to the cutting device is not properly cut, and thus the loss portion of the electrode plate can be prevented. .

Preferably, the safety plate is preferably a rectangular plate shape.

In addition, the nip roll may be removed after the initial portion of the electrode plate is cut by a predetermined length in the cutting device.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a view showing a slitting device for manufacturing a lithium secondary battery employing an electrode plate induction device according to the present invention. In Fig. 2, the same components as those in Fig. 1 are denoted by the same reference numerals and description thereof will be omitted.

Referring to the slitting apparatus for manufacturing a lithium secondary battery of FIG. 2, the electrode plate 1 is guided to the cutting device 2 via the free rolls 3a and 3b and guided by the cutting device 2. (1) is cut by the cutting device (2), and the cut electrode plate (1) is branched up and down in the free roll (3c) is wound with a winding roll (not shown), respectively, conventional slits for manufacturing lithium secondary batteries Same as the device.

However, as shown in Fig. 2, in the slitting apparatus for manufacturing a lithium secondary battery of the present invention, the electrode plate induction device is provided before the cutting device 2, and before the electrode plate 1 is input to the cutting device 2, It is different from the conventional slitting apparatus for manufacturing a lithium secondary battery in that it is guide | induced suitably by an electrode plate induction apparatus.

That is, in the slitting apparatus for manufacturing a lithium secondary battery according to the present invention, a nip roll 4 and a safety plate 5 are provided as an electrode plate induction apparatus before the cutting device 2, so that the electrode plate 1 is cut. It is to be guided safely to the end device (2).

The operator only needs to guide the electrode plate 1 transferred through the free rolls 3a and 3b to the nip roll 4 in accordance with the intermediate cut portion thereof, and after the electrode plate 1 is properly guided to the nip roll 4, It is only necessary to guide the electrode plate 1 cut and discharged by the cutting device 2 to the free roll 3c to move toward the exit direction of the cutting device 2.

Thereafter, the electrode plate 1 cut at the intermediate cut portion is branched up and down in the free roll 3c to be wound by a winding roll (not shown), respectively.

In addition, in the slitting apparatus for manufacturing a lithium secondary battery according to the present invention, an initial portion of the electrode plate 1 is cut by a predetermined length in the cutting device 2 via a nip roll 4 and a safety plate 5. Afterwards, the slitting process can be performed even if the nip roll 4 is removed from the electrode plate inducing apparatus.

In the conventional slitting apparatus for manufacturing a lithium secondary battery, two workers were required in the inlet direction and the outlet direction of the cutting device 2, respectively, for proper induction of the electrode plate 1, By the installation, one worker can perform the same process, thereby enabling efficient manpower utilization, thereby reducing the manufacturing cost of the lithium secondary battery.

In addition, as long as the operator makes the electrode plate 1 flow into the nip roll 4 appropriately in accordance with the intermediate cut portion, the nip roll 4 continues to convey the electrode plate 1 in the advancing direction.

Therefore, as in the conventional slitting process, a backing phenomenon that occurs when the electrode plate 1 is input to the cutting device 2, that is, when the electrode plate 1 is input to the cutting device 2, In order to prevent the phenomenon of retreating back again, the operator does not need to continuously guide the electrode plate 1 until the electrode plate 1 passes through the cutting device 2 by a predetermined length, and thus the cutting device It is also possible to prevent the electrode plate 1 of the initial portion initially inputted to (2) from being cut off properly, so that a loss portion of the electrode plate is generated.

3 is a plan view showing a slitting apparatus for manufacturing a lithium secondary battery employing the electrode plate inducing apparatus according to the present invention of FIG. In Fig. 3, the same components as those in Fig. 2 are denoted by the same reference numerals and description thereof will be omitted.

In FIG. 3, the center portion of the electrode plate 1 is indicated by the dotted line, which is the intermediate cut portion to be cut by the cutting device 2, and the portion indicated by the diagonal line on the electrode plate 1 represents the portion coated with the electrode active material. .

As can be seen in Figure 3, the electrode plate 1 cut to the left and right on the basis of the intermediate cut portion is branched up and down through the free roll (3c) are respectively wound up by a winding roll (not shown).

2 and 3, although the safety plate 5 constituting the electrode plate induction device has a wide rectangular plate shape, it is not necessary to have such a shape, and the electrode plate 1 can be properly guided to the cutting device 2. It may be any shape as long as it exists.

As mentioned above, although this invention was demonstrated in detail through the specific Example, this invention is not limited to the said Example, A various deformation | transformation is possible for a person with ordinary knowledge within the scope of the technical idea of this invention. .

 According to the slitting apparatus for manufacturing a lithium secondary battery employing the electrode plate induction apparatus according to the present invention, one worker can perform the same process as that performed in the conventional slitting apparatus for manufacturing a lithium secondary battery, thereby making it more efficient. It can be utilized, and the manufacturing cost of a lithium secondary battery can be reduced.

In addition, according to the slitting apparatus for manufacturing a lithium secondary battery employing the electrode plate induction device according to the present invention, in order to prevent the backing phenomenon that the electrode plate retreats back when the electrode plate is input to the cutting device, It is not necessary for the operator to continuously guide the electrode plate until it passes through the cutting device by a certain length, so that the electrode plate of the initial portion that is initially input to the cutting device may not be properly cut, resulting in the loss of the electrode plate. You can prevent it.

Claims (4)

In the slitting apparatus for manufacturing a lithium secondary battery, A roll for guiding the electrode plate; A cutting device for cutting the electrode plate at an intermediate cutting portion while the electrode plate guided by the roll is in contact; And A winding roll for winding an electrode plate cut by the cutting device, Before the electrode plate guided by the roll is input to the cutting device, further comprising an electrode plate induction device for guiding the electrode plate safely to the cutting device, lithium secondary with an electrode plate induction device, characterized in that Slitting device for battery manufacturing. The method of claim 1, The electrode plate induction device, A nip roll receiving the electrode plate guided by the roll and transferring the electrode plate; And A slitting device for manufacturing a lithium secondary battery employing an electrode plate induction device, comprising a safety plate provided between the nip roll and the cutting device to safely guide the electrode plate to the cutting device. The method of claim 2, The said safety plate is a rectangular plate shape, The slitting apparatus for lithium secondary battery manufacture which employ | adopted the electrode plate induction apparatus characterized by the above-mentioned. The method of claim 2 or 3, And the nip roll is removed after the initial portion of the electrode plate is cut by the cutting device by a predetermined length.

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