Patent Description:
In generally, secondary batteries refer to chargeable and dischargeable batteries unlike primary batteries that are not chargeable, and such a secondary battery is being widely used in the high-tech electronic fields such as phones, laptop computers, and camcorders.

The secondary batteries are classified into a can-type secondary battery, in which an electrode assembly is stored in a metal can, and a pouch-type secondary battery, in which an electrode assembly is stored in a pouch. Also, the pouch-type secondary battery comprises an electrode assembly having an electrode tab, an electrode lead coupled to the electrode tab, and a battery case accommodating the electrode assembly in a state in which a front end of the electrode lead is drawn to the outside. Also, the electrode assembly has a structure in which the electrode and the separator are alternately stacked, and the battery case comprises an accommodation portion for accommodating the electrode assembly and a sealing portion formed along an edge surface of the accommodation portion.

Meanwhile, the method for manufacturing the electrode assembly comprises supplying a first separator, disposing an electrode on a top surface of the first separator, disposing a second separator on a top surface of the electrode, bonding the first separator, the electrode, and the second separator, and cutting first and second separators between electrodes corresponding to each other.

However, during an electrode assembly manufacturing method according to the related art, the position of the electrode disposed between the first and second separators shakes and deviates. That is, skew fail occurs at the electrode.

<CIT> relates to a roll member having an outer circumferential surface in which a plurality of grooves are formed, wherein the plurality of grooves are arranged at an angle relative to a direction parallel to a central axis of the roll member. A coating device for coating a film member with a coating liquid, the coating device comprising the roll member. A separator production device for producing a separator in which a heat-resistant layer is laminated over a substrate. The separator production device comprising the coating device. A secondary battery production device for producing a secondary battery comprising a positive electrode plate, a negative electrode plate, and a pair of separators that sandwich the positive electrode plate or the negative electrode plate therebetween. The secondary battery production device comprising the separator production device.

<CIT> provides a manufacturing method for a battery capable of preventing the soiling of a roll for carrying a separator caused by an adhesive and the breakage of the separator by unreasonable force applied to the separator, wherein the adhesive within recesses installed on the surface of a coating roll is transferred to the surface of the separator, the adhesive is supplied to the surface of the separator stretched between two carrying rollers and transferred to the separator.

An object of the present invention is to provide an adhesive layer coating unit, an electrode assembly manufacturing apparatus comprising same, and an electrode assembly manufacturing method, by which an adhesive layer having uniform width and thickness may be applied on a surface of a separator, and an electrode and the separator are alternately stacked. Thus, the electrode and the separator may be bonded when an electrode assembly is manufactured, and accordingly, it is possible to prevent the electrode from shaking and deviating, that is, skew fail of the electrode may be prevented.

The present invention provides an adhesive layer coating unit (<NUM>) according to claim <NUM>, configured to continuously apply an adhesive layer (<NUM>) having a first width in a longitudinal direction of a first separator (<NUM>). The adhesive layer coating unit (<NUM>) comprises: a transfer roller (<NUM>) configured to support a bottom surface of the first separator (<NUM>) and transfer the first separator (<NUM>); a discharge roller (<NUM>) configured to transfer the first separator (<NUM>), which has passed through the transfer roller (<NUM>), in conjunction with the transfer roller (<NUM>) while supporting a top surface of the first separator (<NUM>), wherein a coating groove (122a) having the first width and a closed curve shape is formed in a circumferential surface of the discharge roller (<NUM>); and a coating member (<NUM>) configured to inject an adhesive (12a) into a space between the discharge roller (<NUM>) and the top surface of the first separator (<NUM>) which has passed through the transfer roller (<NUM>), wherein as the adhesive (12a) flows in the coating groove (122a) of the discharge roller (<NUM>), the adhesive layer (<NUM>) having the first width is continuously applied on the top surface of the first separator (<NUM>) ); a case (<NUM>), wherein the transfer roller (<NUM>) and the discharge roller (<NUM>) are installed inside the case (<NUM>), and both ends between the transfer roller (<NUM>) and the discharge roller (<NUM>) are finished thereby; and a curing member (<NUM>) which emits a light source toward the first separator (<NUM>) and cures the adhesive layer (<NUM>), which is continuously applied on the first separator (<NUM>), to a set viscosity, wherein a depth of the coating groove (122a) is <NUM> to <NUM>, and the adhesive layer (<NUM>) having a thickness of <NUM> to <NUM> is applied on the top surface of the first separator (<NUM>), wherein a center point of the discharge roller (a2) is positioned on a different vertical line from a center point of the transfer roller (a1), and is positioned above the center point of the transfer roller (a1), wherein the first width is less than a width of the first separator (<NUM>).

The adhesive layer (<NUM>) may be provided with acrylate or epoxy which is curable monomer.

The set viscosity may be <NUM> to <NUM> cPs at <NUM>.

An electrode assembly manufacturing apparatus (<NUM>) of the present invention is defined in claim <NUM> and comprises: a first separator supply unit (<NUM>) configured to supply a first separator (<NUM>); an adhesive layer coating unit (<NUM>) which continuously applies an adhesive layer (<NUM>) having a first width in a longitudinal direction of the first separator (<NUM>); an electrode supply unit (<NUM>) configured to dispose an electrode (<NUM>) on the adhesive layer (<NUM>) applied on the first separator (<NUM>); and a second separator supply unit (<NUM>) configured to dispose a second separator (<NUM>) on a top surface of the electrode (<NUM>).

The electrode assembly manufacturing apparatus (<NUM>) may further comprise: a lamination unit (<NUM>) configured to bond a stack of the first separator (<NUM>), the electrode (<NUM>), and the second separator (<NUM>) which have passed through the second separator supply unit (<NUM>); and a cutting unit (<NUM>) configured to cut the first separator (<NUM>) and the second separator (<NUM>) which are positioned between electrodes (<NUM>) facing each other in the stack.

An electrode assembly manufacturing method of the present invention is defined in claim <NUM>, is adapted to the electrode assembly manufacturing apparatus (<NUM>) and comprises: a first separator supply process (S10) of supplying a first separator (<NUM>); an adhesive layer coating process (S20) of continuously applying an adhesive layer (<NUM>) having a first width in a longitudinal direction of the first separator (<NUM>); an electrode supply process (S40) of disposing an electrode (<NUM>) on the adhesive layer (<NUM>) applied on the first separator <NUM>); and a second separator supply process (S50) of disposing a second separator (<NUM>) on a top surface of the electrode (<NUM>) disposed on the first separator (<NUM>), a lamination process (S60) of bonding a stack of the first separator (<NUM>), the electrode (<NUM>), and the second separator (<NUM>); and a cutting process (S70) of cutting the first and second separators (<NUM>,<NUM>) which are positioned between electrodes (<NUM>) facing each other in the stack, wherein the adhesive layer coating process (S20) comprises a transfer process of transferring the first separator (<NUM>) with a transfer roller (<NUM>) while supporting a bottom surface of the first separator (<NUM>), a discharge process of transferring the first separator (<NUM>), which has passed through the transfer roller (<NUM>), with a discharge roller (<NUM>) in conjunction with the transfer roller (<NUM>) while supporting a top surface of the first separator (<NUM>), wherein a coating groove (122a) having the first width and a closed curve shape is formed in a circumferential surface of the discharge roller (<NUM>), and a solution casting process of injecting an adhesive (12a) into a space between the discharge roller (<NUM>) and the top surface of the first separator (<NUM>) which has passed through the transfer roller (<NUM>), wherein as the adhesive (12a) flows in the coating groove (122a) of the discharge roller (<NUM>), the adhesive layer (<NUM>) having the first width is continuously applied on the top surface of the first separator (<NUM>), and a curing process (S30) of curing the adhesive layer (<NUM>), which is applied on the first separator (<NUM>), to a set viscosity when the solution casting process is completed.

A depth of the coating groove (122a) may be <NUM> to <NUM>, and the adhesive layer (<NUM>) having a thickness of <NUM> to <NUM> may be applied on the top surface of the first separator.

In the curing process (S30), a light source may be emitted toward the first separator (<NUM>) transferred through the discharge roller (<NUM>), and the adhesive layer (<NUM>) applied on the first separator (<NUM>) may be cured to the set viscosity, wherein as the set viscosity is <NUM> to <NUM> cPs at <NUM>, an adhesive force between the electrode and the first separator (<NUM>) may be <NUM> to <NUM> N (<NUM> to <NUM> gf).

The adhesive layer coating unit of the present invention comprises the transfer roller, the discharge roller, the coating member, and the curing member, and thus, the adhesive layer having the first width may be conveniently applied on the surface of the first separator. Accordingly, the work efficiency may be enhanced, and processes may be simplified.

Also, the adhesive layer coating unit of the present invention further comprises a case, and thus, an accommodation space filled with the certain amount of the adhesive may be formed between the case, the transfer roller, and the discharge roller. Accordingly, the adhesive may be uniformly injected or applied on the entirety of the first separator that passes through the transfer roller and the discharge roller.

Also, the curing member of the adhesive layer coating unit of the present invention uses an UV lamp for emitting the light source. Thus, the adhesive may be cured simultaneously when applied on the top surface of the first separator.

Also, the electrode assembly manufacturing apparatus of the present invention comprises the first separator supply unit, the adhesive layer coating unit, the curing unit, the electrode supply unit, and the second separator supply unit. Thus, the adhesive layer is applied on the top surface of the first separator, and accordingly, it is possible to prevent the electrode from shaking and deviating when the electrode and the first separator are disposed, that is, the skew fail of the electrode may be prevented.

Also, in the electrode assembly manufacturing apparatus of the present invention, the center point of the transfer roller and the center point of the discharge roller are positioned on different vertical lines, and the center point of the discharge roller is positioned above the center point of the transfer roller. That is, as the discharge roller is kept at a higher position than the transfer roller, it is possible to prevent the adhesive applied on the first separator between the transfer roller and the discharge roller from running over the discharge roller.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so as to be easily carried out by a person skilled in the art to which the present invention pertains. Also, in the drawings, parts irrelevant to the description will be omitted to clearly describe the present invention, and similar elements will be designated by similar reference numerals throughout the specification.

Referring to <FIG>, the electrode assembly of the present invention comprises one or more electrode assemblies <NUM>, and each of the electrode assemblies <NUM> has a structure in which a first separator <NUM>, an adhesive layer <NUM>, an electrode <NUM>, and a second separator <NUM> are alternately arranged.

Here, referring to the enlarged view of <FIG>, the adhesive layer <NUM> having a first width is provided on the top surface of the first separator and has an entirely uniform thickness. Particularly, a first width α of the adhesive layer <NUM> is set to <NUM> to <NUM>% of an overall width β of the first separator, preferably, to <NUM>%.

In the electrode assembly having the above structure of the present invention, the adhesive layer <NUM> may prevent the electrode <NUM> disposed on the top surface of the first separator <NUM> from shaking and deviating, that is, skew fail of the electrode may be prevented. Furthermore, it is possible to prevent battery performance from deteriorating by optimizing the width of the adhesive layer.

Meanwhile, the first separator coated with the adhesive layer is manufactured through the adhesive layer coating unit according to a first embodiment of the present invention.

The adhesive layer coating unit according to the first embodiment of the present invention has a structure capable of continuously applying an adhesive layer having the same width and thickness on a surface of a separator through a novel method. Accordingly, work efficiency may be enhanced, and processes may be simplified.

That is, as illustrated in <FIG>, an adhesive layer coating unit <NUM> according to the first embodiment of the present invention is to continuously apply the adhesive layer <NUM> in the longitudinal direction of the first separator <NUM>. Particularly, the adhesive layer coating unit <NUM> may apply a plurality of adhesive layers <NUM> in the width direction of the first separator <NUM>, that is, the adhesive layer coating unit <NUM> has a structure patterning and coating the surface of the first separator with the adhesive layers.

The adhesive layer coating unit <NUM> comprises a transfer roller <NUM>, a discharge roller <NUM>, a coating member <NUM>, and a curing member <NUM>.

The transfer roller <NUM> supports the bottom surface of the first separator <NUM> and moves the first separator <NUM> from one side to the other side (left to right when viewed in <FIG>) when rotating.

The discharge roller <NUM> transfers the first separator <NUM>, which has passed through the transfer roller <NUM>, in conjunction with the transfer roller <NUM> while supporting a top surface of the first separator <NUM>. A coating groove 122a having a first width and a closed curve shape is formed in a circumferential surface of the discharge roller. Here, the first width α is less than a width β of the first separator.

That is, the discharge roller <NUM> comprises the coating groove 122a having the closed curve shape and a supporting surface 122b transferring the first separator <NUM> while supporting the first separator <NUM>.

The coating member <NUM> injects an adhesive 12a into a gap between the discharge roller <NUM> and the top surface of the first separator <NUM> which has passed through the transfer roller <NUM>. So, as the adhesive 12a flows in the coating groove 122a of the discharge roller <NUM>, the adhesive layer <NUM> having the first width is continuously applied on the top surface of the first separator <NUM>.

Meanwhile, the coating member <NUM> comprises a storage tank, in which the adhesive is stored, and an injection nozzle, which injects the adhesive stored in the storage tank into the gap between the discharge roller <NUM> and the top surface of the first separator <NUM>.

In the adhesive layer coating unit <NUM> having the above structure according to the first embodiment of the present invention, when the first separator <NUM> is transferred by the transfer roller <NUM> and the discharge roller <NUM>, the coating member <NUM> applies the adhesive into the gap between the discharge roller <NUM> and the top surface of the first separator <NUM> which has passed through the transfer roller <NUM>. So, as the adhesive 12a flows only in the coating groove 122a of the discharge roller <NUM>, the adhesive layer <NUM> having the first width is continuously applied in the longitudinal direction of the first separator <NUM>.

Here, the adhesive layer <NUM> has the same width and thickness as the coating groove 122a. Meanwhile, due to the supporting surface 122b of the discharge roller <NUM>, an adhesive layer is not formed on the remainder of the first separator <NUM> other than the coating groove 122a.

Thus, the adhesive layer coating unit <NUM> according to the first embodiment of the present invention may continuously apply the adhesive layer <NUM> in the longitudinal direction of the first separator <NUM>. Accordingly, work efficiency may be enhanced, and processes may be simplified.

Particularly, the adhesive layer coating unit <NUM> according to the first embodiment of the present invention may continuously apply the adhesive layer having the same width and thickness on the surface of the separator even without a separate adjustment process.

Meanwhile, the discharge roller <NUM> may further comprise at least one coating groove having a second width on the circumferential surface thereof, and accordingly, the surface of the first separator may be patterned and coated with two or more adhesive layers.

Particularly, the first width and the second width may be equal to each other or different from each other. That is, when the first width and the second width are equal to each other, the surface of the first separator may be patterned and coated with the adhesive layers having the same width. When the first width and the second width are different from each other, the surface of the first separator may be patterned and coated with the adhesive layers having different widths.

Meanwhile, the depth of the coating groove 122a is <NUM> to <NUM>, preferably, <NUM> to <NUM>. Accordingly, the adhesive layer <NUM> having the thickness of <NUM> to <NUM>, preferably, the adhesive layer <NUM> having the thickness of <NUM> to <NUM> is applied on the top surface of the first separator <NUM>.

Here, when the depth of the coating groove 122a is <NUM> or less, the adhesive layer does not smoothly flow in the coating groove 122a, and thus, a defective adhesive layer <NUM> may be formed. Also, when the depth of the coating groove 122a is <NUM> or more, the number of stacked electrodes may be reduced due to the increase in the thickness of the stack, and as a result, the battery performance may deteriorate.

Thus, the depth of the coating groove 122a is <NUM> to <NUM>. Accordingly, the adhesive layer <NUM> having the thickness of <NUM> to <NUM> may be stably applied on the top surface of the first separator <NUM>, and battery performance may be stably ensured.

Meanwhile, the discharge roller <NUM> is positioned above the transfer roller <NUM> when viewed in <FIG>. That is, a center point a1 of the transfer roller <NUM> and a center point a2 of the discharge roller <NUM> are positioned on different vertical lines, and the center point a2 of the discharge roller <NUM> is positioned above the center point a1 of the transfer roller <NUM> when viewed with respect to the ground. Accordingly, it is possible to prevent the adhesive 12a applied on the first separator <NUM> between the transfer roller <NUM> and the discharge roller <NUM> from running over the discharge roller <NUM>.

Meanwhile, the coating member <NUM> applies the adhesive 12a on the top surface of the first separator <NUM> through a solution casting process, and accordingly, the adhesive 12a may be stably applied on the top surface of the first separator <NUM>.

Meanwhile, the area of the adhesive <NUM> is set not to exceed <NUM>% of the entire area of the first separator <NUM>. That is, when the area of the adhesive layer <NUM> is greater than <NUM>% of the area of the first separator <NUM>, the battery performance deteriorates by <NUM>% or more.

Meanwhile, the adhesive layer coating unit <NUM> further comprises a case <NUM>. The transfer roller <NUM> and the discharge roller <NUM> are installed inside the case <NUM>, and both ends between the transfer roller <NUM> and the discharge roller <NUM> are finished thereby.

That is, the transfer roller <NUM> and the discharge roller <NUM> are free-rotatably installed in the case <NUM>, and both inner walls thereof finish side portions between the transfer roller <NUM> and the discharge roller <NUM>. Accordingly, the case may prevent the adhesive applied on the first separator between the transfer roller <NUM> and the discharge roller <NUM> from flowing down toward both the side portions of the transfer roller <NUM> and the discharge roller <NUM>.

Meanwhile, the adhesive layer coating unit according to the first embodiment of the present invention further comprises a curing member <NUM> that cures the adhesive layer, which has been applied on the first separator, to a set viscosity.

The curing member <NUM> is provided below the discharge roller <NUM>, and emits a light source toward the first separator <NUM>, which is transferred along the discharge roller <NUM>, and cures the adhesive layer <NUM> applied on the first separator <NUM>.

Here, the curing member <NUM> may use one of a mercury lamp, a metal halide lamp, or a UV LED so as to increase curing strength of the adhesive layer <NUM> applied on the first separator <NUM>. Particularly, the UV LED is used. Here, when the UV LED is used, the intensity of the light source having <NUM> J/cm<NUM> is applied.

Meanwhile, the curing member <NUM> cures the adhesive layer such that the adhesive layer does not infiltrate into <NUM>% or more of the thickness of the first separator, preferably, <NUM>% or more. Accordingly, the coupling between the adhesive layer and the first separator <NUM> may be enhanced while minimizing the thickness deviation of the adhesive layer <NUM>.

Meanwhile, the set viscosity may be <NUM> to <NUM> cPs at <NUM>, preferably, <NUM> cPs. Here, when the set viscosity is <NUM> cPs or less, all the adhesive infiltrate into the porous separator, and the adhesive may flow out from the opposite surface of the separator. When <NUM> cPs or more, it is difficult to blend the adhesive, the adhesive is not injected into the coating groove 122a due the poor flowability. Thus, the set viscosity may be <NUM> to <NUM> cPs at <NUM>, and accordingly, the adhesive layer may be stably applied on the top surface of the first separator.

Meanwhile, when the set viscosity is <NUM> to <NUM> cPs at <NUM>, an adhesive force between the electrode and the first separator is <NUM> to <NUM> N (<NUM> to <NUM> gf).

Meanwhile, the adhesive layer is provided with a curable material. For example, the adhesive is provided with acrylate or epoxy which is a monomer. Particularly, the acrylate or epoxy has the high curing strength due to a UV light source.

Hereinafter, in describing another embodiment of the present invention, components having the same functions as those in the foregoing embodiment are given the same reference numerals, and their duplicated description will be omitted.

An electrode assembly manufacturing apparatus <NUM> according to the second embodiment of the present invention comprises the adhesive layer coating unit <NUM> according to the first embodiment described above.

That is, as illustrated in <FIG>, the electrode assembly manufacturing apparatus <NUM> according to the second embodiment of the present invention is to manufacture a stack <NUM>, in which a first separator <NUM>, an adhesive <NUM>, an electrode <NUM>, and a second separator <NUM> are stacked in this order, and comprises a first separator supply unit <NUM>, an adhesive layer coating unit <NUM>, a curing member <NUM>, an electrode supply unit <NUM>, a second separator supply unit <NUM>, a lamination unit <NUM>, and a cutting unit <NUM>.

The first separator supply unit <NUM> has a roller structure, on which the first separator <NUM> is wound, and supplies the wound first separator <NUM> to the adhesive layer coating unit <NUM> when rotating.

The adhesive layer coating unit <NUM> is to continuously apply the adhesive layer <NUM> having a first width in the longitudinal direction of the first separator <NUM>, and comprises a transfer roller <NUM>, a discharge roller <NUM>, a coating member <NUM>, and a curing member <NUM>.

Meanwhile, the adhesive layer coating unit <NUM> has the same configuration and function as the adhesive layer coating unit of the first embodiment, and accordingly, detailed description thereof will be omitted.

Particularly, the adhesive layer coating unit <NUM> has a structure that patterns and coats the top surface of the first separator <NUM> with the adhesive layer <NUM>.

That is, the adhesive layer coating unit <NUM> comprises: the transfer roller <NUM> which supports the bottom surface of the first separator <NUM> and transfers the first separator <NUM> from one side to the other side (left to right when viewed in <FIG>); the discharge roller <NUM> which supports the top surface of the first separator <NUM> passing through the transfer roller <NUM>, transfers the first separator <NUM> to the electrode supply unit <NUM>, and has a coating groove 122a extending along the outer circumferential surface and having a closed curve shape; and the coating member <NUM> which applies an adhesive 12a on the top surface of the first separator <NUM> passing through between the transfer roller <NUM> and the discharge roller <NUM>. As the adhesive 12a flows in the groove 122a of the discharge roller <NUM>, the top surface of the first separator <NUM> is patterned and coated with the adhesive layer <NUM>.

The electrode supply unit <NUM> disposes the electrode <NUM> on the top surface of the first separator <NUM> coated with the adhesive layer <NUM>. Here, the electrode <NUM> is attached to the top surface of the first separator <NUM> by the adhesive force of the adhesive layer <NUM>, and accordingly, the skew fail of the electrode may be prevented.

The second separator supply unit <NUM> disposes the second separator <NUM> on the top surface of the electrode <NUM>, and the second separator <NUM> is disposed symmetrically to the first separator <NUM>. Thus, the stack <NUM> is completed in which the first separator <NUM>, the adhesive <NUM>, the electrode <NUM>, and the second separator <NUM> are stacked in this order.

The lamination unit <NUM> presses and bonds the stack <NUM> which has passed through the second separator supply unit <NUM>.

Referring to <FIG>, the cutting unit <NUM> cuts the first separator <NUM> and the second separator <NUM> which are positioned between electrodes <NUM> facing each other in the stack <NUM>.

Thus, the electrode assembly manufacturing apparatus according to the second embodiment of the present invention may manufacture the stack <NUM> of the first separator <NUM>, the adhesive layer <NUM>, the electrode <NUM>, and the second separator <NUM>. Particularly, the first separator <NUM> and the electrode <NUM> are bonded by the adhesive layer <NUM>, and thus, the skew fail of the electrode <NUM> may be prevented. As a result, productivity may be enhanced, and a defect rate may be reduced.

Hereinafter, an electrode assembly manufacturing method according to the second embodiment of the present invention will be described.

As illustrated in <FIG>, the electrode assembly manufacturing method according to the second embodiment of the present invention comprises a first separator supply process (S10), an adhesive layer coating process (S20), a curing process (S30), an electrode supply process (S40), a second separator supply process (S50), a lamination process (S60), and a cutting process (S70).

The first separator supply process (S10) supplies a first separator <NUM>, which is wound on a first separator supply unit <NUM>, to the adhesive layer coating process.

The adhesive layer coating process (S20) applies an adhesive on the top surface of the first separator <NUM> through an adhesive layer coating unit <NUM>, and thus, the top surface is coated with an adhesive layer <NUM>. Particularly, the adhesive layer coating process (S20) continuously applies the adhesive layer <NUM> in the longitudinal direction of the first separator <NUM>.

That is, the adhesive layer coating process (S20) comprises a transfer process, a discharge process, a solution casting process, and a curing process. Also, the adhesive layer coating unit <NUM> comprises a transfer roller <NUM>, a discharge roller <NUM>, a coating member <NUM>, a case <NUM>, and a curing member <NUM>.

In the transfer process, when the first separator <NUM> is supplied through the first separator supply process (S10), the transfer roller <NUM> transfers the first separator <NUM> to the discharge roller <NUM> while supporting the bottom surface of the first separator <NUM>.

In the discharge process, the discharge roller <NUM> transfers the first separator <NUM>, which has passed through the transfer roller <NUM>, to the electrode supply unit <NUM> in conjunction with the transfer roller <NUM> while supporting the top surface of the first separator <NUM>. Meanwhile, a coating groove 122a having a closed curve shape is formed in a circumferential surface of the discharge roller <NUM>.

In the solution casting process, an adhesive 12a is injected, through the coating member <NUM>, into a gap between the discharge roller <NUM> and the top surface of the first separator <NUM> which has passed through the transfer roller <NUM>. Thus, as the adhesive 12a injected on the top surface of the first separator <NUM> flows only in the coating groove 122a of the discharge roller <NUM>, the adhesive layer <NUM> having the same shape and width as the coating groove may be applied on the top surface of the first separator <NUM>.

For example, when the coating groove is formed having a depth of <NUM> to <NUM>, the adhesive layer applied on the first separator <NUM> may have the thickness of <NUM> to <NUM>.

In the curing process, the adhesive layer <NUM> applied on the first separator <NUM> is cured to a set viscosity. That is, in the curing process, a light source (high-temperature light or heat) is emitted, by using the curing member <NUM>, toward the first separator <NUM> transferred along the discharge roller <NUM>. Thus, the adhesive layer <NUM> applied on the first separator may be cured to a set viscosity. Here, curing strength of the curing member <NUM> may be adjusted such that the adhesive layer does not infiltrate into <NUM>% or more of the thickness of the first separator <NUM>, preferably, <NUM>% or more.

Meanwhile, an appropriate viscosity of the adhesive is <NUM> to <NUM> cPs at <NUM>, and accordingly, the adhesive may be cured so as not to infiltrate into <NUM>% or more of the thickness of the first separator <NUM>. Here, the adhesive force between the electrode and the first separator is <NUM> to <NUM> N (<NUM> to <NUM> gf).

Meanwhile, the adhesive layer is provided with a curable material. For example, the adhesive layer is provided with acrylate or epoxy which is a monomer, and accordingly, the curing strength of the adhesive may be enhanced.

Also, the curing member <NUM> may be one of a mercury lamp, a metal halide lamp, or a UV LED so as to increase curing strength of the adhesive layer <NUM> applied on the first separator <NUM>. Preferably, the UV LED is used.

Meanwhile, the solution casting process and the curing process are performed simultaneously, and thus, the adhesive may be applied on the first separator and simultaneously cured. Accordingly, the processes may be simplified, and the adhesive may be prevented from adhering on the discharge roller.

The electrode supply process (S40) disposes an electrode <NUM> on the adhesive layer <NUM> applied on the first separator <NUM>. Thus, as the electrode <NUM> is bonded to the first separator <NUM> by the adhesive layer <NUM>, the adhesive force may be enhanced. Accordingly, it is possible to prevent the electrode from shaking and deviating when the first separator, on which the electrode is disposed, is transferred.

The second separator supply process (S50) disposes the second separator <NUM> on the top surface of the electrode <NUM> disposed on the first separator <NUM>. Thus, the stack <NUM> is completed in which the first separator <NUM>, the adhesive <NUM>, the electrode <NUM>, and the second separator <NUM> are stacked in this order. Here, the electrode <NUM> is maintained while being bonded to the first separator <NUM> by the adhesive layer <NUM>, and accordingly, the skew fail of the electrode <NUM> may be prevented.

The lamination process (S60) rolls and bonds the stack <NUM> in which the first separator <NUM>, the adhesive layer <NUM>, the electrode <NUM>, and the second separator <NUM> are stacked in this order.

The cutting process (S70) cuts the first and second separators <NUM> and <NUM> positioned between electrodes <NUM> facing each other in the stack, and thus, complete stacks having a certain size are manufactured.

The adhesive force of the electrode, which is provided in the complete product manufactured by the electrode assembly manufacturing method according to the second embodiment of the present invention, is measured.

That is, the adhesive layer having an acrylate material which is a curable monomer is applied on the top surface of the first separator, and thus, the top surface is coated with the adhesive layer <NUM>. Then, the adhesive layer <NUM> is cured, through the curing member, to a set hardness. Next, the electrode is disposed on the adhesive layer <NUM> applied on the first separator, and the second separator is disposed on the top surface of the electrode. Accordingly, the complete stack is manufactured.

Here, the thickness of the adhesive layer is <NUM> to <NUM>, the hardness of the adhesive layer is <NUM> cPs. Also, the curing member uses the UV LED, and the intensity of the UV LED having <NUM> J/cm<NUM> is applied. Here, it may be confirmed that the adhesive layer infiltrates into <NUM>% or more of the thickness of the first separator.

As illustrated in <FIG>, the adhesive forces are measured at three points of the complete stack. That, an upper region A and a lower region C of the complete stack, which do not have the adhesive layer <NUM>, and a central region B of the complete stack, which has the adhesive layer <NUM>, are measured with respect to the adhesive forces.

As a result, as illustrated in <FIG>, the coupling force between the electrode and the first separator is measured to <NUM> to <NUM> N (<NUM> to <NUM> gf) in the region B in which the adhesive layer is positioned. Also, the coupling force between the electrode and the first separator is measured to <NUM> to <NUM> N (<NUM> to <NUM> gf) in each of the regions A and C which do not have the adhesive layer.

Claim 1:
An adhesive layer coating unit (<NUM>) configured to continuously apply an adhesive layer (<NUM>) having a first width (a) in a longitudinal direction of a first separator (<NUM>), the adhesive layer coating unit (<NUM>) comprising:
a transfer roller (<NUM>) configured to support a bottom surface of the first separator (<NUM>) and transfer the first separator (<NUM>);
a discharge roller (<NUM>) configured to transfer the first separator (<NUM>), which has passed through the transfer roller (<NUM>), in conjunction with the transfer roller (<NUM>) while supporting a top surface of the first separator (<NUM>), wherein a coating groove (122a) having the first width and a closed curve shape is formed in a circumferential surface of the discharge roller (<NUM>);
a coating member (<NUM>) configured to inject an adhesive (12a) into a space between the discharge roller (<NUM>) and the top surface of the first separator (<NUM>) which has passed through the transfer roller (<NUM>), wherein as the adhesive (12a) flows in the coating groove (122a) of the discharge roller (<NUM>), the adhesive layer (<NUM>) having the first width is continuously applied on the top surface of the first separator (<NUM>);
a case (<NUM>), wherein the transfer roller (<NUM>) and the discharge roller (<NUM>) are installed inside the case (<NUM>), and both ends between the transfer roller (<NUM>) and the discharge roller (<NUM>) are finished thereby; and
a curing member (<NUM>) which emits a light source toward the first separator (<NUM>) and cures the adhesive layer (<NUM>), which is continuously applied on the first separator (<NUM>), to a set viscosity,
wherein a depth of the coating groove (122a) is <NUM> to <NUM>, and the adhesive layer (<NUM>) having a thickness of <NUM> to <NUM> is applied on the top surface of the first separator (<NUM>),
wherein a center point of the discharge roller (a2) is positioned on a different vertical line from a center point of the transfer roller (a1), and is positioned above the center point of the transfer roller (a1),
wherein the first width (a) is less than a width (b) of the first separator (<NUM>).