Patent Description:
Due to the rapid increase in the use of fossil fuels, the demand for the use of alternative energy or clean energy is increasing, and as part thereof, the fields that are being studied most actively are the fields of power generation and power storage using electrochemistry.

At present, a secondary battery is a representative example of an electrochemical device that utilizes such electrochemical energy, and the range of use thereof tends to be gradually expanding.

Recently, along with the increase of the technological development and demand for mobile devices such as portable computers, portable phones, and cameras, the demand for secondary batteries has also sharply increased as an energy source. Among such secondary batteries is a lithium secondary battery exhibiting high charge/discharge characteristics and lifetime characteristics and being environmentally friendly, in which much research has been carried out and which is now commercialized and widely used.

Generally, the secondary battery has a structure in which an electrode assembly comprising a positive electrode, a negative electrode, and a porous separator is built into in a battery case in a state of being impregnated with a non-aqueous electrolyte.

In this case, depending upon the shape of a battery case, a secondary battery may be generally classified as a cylindrical secondary battery or a prismatic secondary battery in which a stacked/folded type, or wound type electrode assembly is housed in a case made of metal as a battery case, a pouch type secondary battery in which a stacked type or stacked/folding type electrode assembly is built into a pouch type battery case made of an aluminum laminate sheet, and a coin-type secondary battery in which a coin-type electrode assembly is housed in an upper case and a lower case made of metal.

Here, the exterior material of the cylindrical, prismatic, or coin-type secondary battery, i.e., the battery case, is generally made of metal, especially stainless steel (SUS).

However, there is a problem that when such a metal comes into contact with an electrolyte, corrosion occurs, and especially when an imide-based lithium salt is used, corrosion is deepened.

In this regard, conventionally1, corrosion has been suppressed by a method of coating the battery case of such a secondary battery with an inexpensive metal such as Cr, Zn, Sn, etc., which does not easily cause corrosion, but these also have a problem that not only a sufficient corrosion-preventing effect cannot be obtained with a metal, but also a browning phenomenon occurs on the metal surface.

Therefore, there is a need to develop a technology for a secondary battery that can solve the above problems and effectively prevent the corrosion of a metal can regardless of the type of electrolyte.

<CIT> discloses a coin-type alkaline cell with a can made from nickel or stainless steel which undergoes a surface treatment with an electrically conductive polymer, polyaniline and tin. The cell also comprises a ring gasket which seals the first and the second case.

<CIT> discloses an alkaline zinc-manganese dry battery having a cylindrical shape composed of a steel case with a sealing ring and a current collector. The steel case has a conductive coating on its inner wall comprising of graphene. The conductive coating also contains a binder.

<CIT> discloses that maintaining electrodes under a compressive force improves the life of a battery.

<CIT> discloses a safety mechanism comprising of a disk plate as a safety valve and a shut-off disk, which releases and shuts off the connection in a battery.

<CIT> discloses a positive electrode including a positive electrode current collector, a positive electrode mixed material layer that is formed on at least one surface of the positive electrode current collector, and a protective layer which includes an insulating inorganic compound and a conductive material, and is interposed between the positive electrode current collector and the positive electrode mixed material layer.

The present disclosure has been made to solve the above-mentioned problems and other technical problems that have yet to be resolved.

Specifically, an object of the present disclosure is to provide a secondary battery that can effectively suppress the corrosion of the secondary battery case due to contact with the electrolyte.

In order to achieve the above object, according to one embodiment of the present disclosure, there is provided a secondary battery configured such that an electrode assembly including a positive electrode, a separator, and a negative electrode is housed in a battery case together with an electrolyte solution,
wherein the battery case is made of metal, and a conductive layer consisting of a a conductive epoxy layer is formed on a part or the whole of the inner surface of the battery case coming into contact with the electrolyte solution.

Specifically, depending upon the shape of the secondary battery,.

Moreover, the secondary battery further comprises a spring and a spacer that fill an inner space excluding the electrode assembly in the inside of the first case and the second case,.

Further, the secondary battery may further comprise a gasket for sealing the first case and the second case.

In another example, the secondary battery is a cylindrical secondary battery,.

More specifically, a gasket is mounted on the upper part of the beading part of the cylindrical can,.

In yet another example, the electrode assembly is a jelly-roll type or stack/folding type electrode assembly,.

In this case, the electrode assembly comprises a positive electrode tab and a negative electrode tab drawn out from the electrode assembly, wherein the positive tab and the negative tab are respectively connected to the cap terminals, and
a conductive epoxy layer is formed on the inside surface of the secondary battery, in at least one member selected from the group consisting of the positive electrode tab and the negative electrode tab.

On the other hand, in any of the above examples, the metal may be made of any one selected from the group consisting of aluminum, nickel, stainless steel (SUS), copper, iron, bronze, and brass.

The secondary battery may further comprise a hollow center pin inserted into the center of the electrode assembly.

The conductive layer may be formed to a thickness of <NUM> µm to <NUM> µm.

The conductive epoxy layer may comprise at least one conductive filler selected from the group consisting of gold, platinum, silver, copper, or nickel metal powder, carbon or carbon fiber, graphite, and composite powder, and an epoxy polymer.

Hereinafter, the present disclosure will be described in more detail for a better understanding of the present disclosure.

Terms or words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the present disclosure should be construed with meanings and concepts that are consistent with the technical idea of the present disclosure based on the principle that the inventors may appropriately define concepts of the terms to appropriately describe their own disclosure in the best way.

The technical terms provided herein is merely used for the purpose of describing particular embodiments only, and is not intended to be limiting of the present disclosure. The singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise.

Further, throughout the specification, when a portion is referred to as "including" a certain component, it means that the portion can further include other components, without excluding the other components, unless otherwise stated.

According to one embodiment of the present disclosure, there is provided a secondary battery configured such that an electrode assembly including a positive electrode, a separator, and a negative electrode is housed in a battery case together with an electrolyte solution, wherein the battery case is made of metal, and a conductive layer p consisting of a conductive epoxy layer is formed on a part or the whole of the inner surface of the battery case coming into contact with the electrolyte solution.

Specifically, the position where the conductive layer is formed may differ depending on the type of secondary battery.

Specifically, the conductive layer is formed on a surface coming into contact with an electrolyte solution, and more specifically, the conductive layer may be formed at a position at which it should have conductivity while coming into contact with the electrolyte solution.

In one example, first, the secondary battery may be a coin-type secondary battery,.

More specifically, the secondary battery further comprises a spring and a spacer that fill an inner space excluding the electrode assembly in the inside of the first case and the second case,.

That is, the first case, the second case, the spring, and the spacer are made of metal, and the degree of corrosion is severe depending on what kind of material is used as the electrolyte solution, the lifespan characteristics are deteriorated, or it will be unusable any more or the safety may be threatened.

Thus, according to the present disclosure, a conductive layer can be formed on a surface where the first case, the second case, the spring, and the spacer come into contact with the electrolyte, thereby preventing corrosion due to the electrolyte solution while having conductivity.

Meanwhile, the secondary battery may further include a gasket for sealing the first case and the second case.

The gasket is generally made of an insulating material and thus, the conductive layer need not be formed. However, the conductive layer may also be formed on a surface of the gasket, and such a structure is not excluded.

In the present disclosure, a perspective view of a coin-type secondary battery having such a conductive layer formed therein is shown in <FIG>, and a schematic diagram of the cross section is shown in <FIG>.

Referring to <FIG> and <FIG> together, the coin-type secondary battery <NUM> of the present disclosure includes an electrode assembly <NUM>; a first case <NUM> for housing the electrode assembly <NUM>; a second case <NUM> assembled so as to cover the upper end of the first case <NUM>; and a spring <NUM> and a spacer <NUM> that fill an inner space excluding the electrode assembly in the inside of the first case and the second case.

At this time, the electrode assembly <NUM> includes a positive electrode <NUM>, a negative electrode <NUM>, and a separator <NUM> interposed between the positive electrode <NUM> and the negative electrode <NUM>, wherein the positive electrode <NUM>, the negative electrode <NUM> and the separator <NUM> have a coin-type structure.

Meanwhile, the first case <NUM>, the second case <NUM>, the spring <NUM> and the spacer <NUM> are made of metal and thus, in order to prevent corrosion due to the reaction with an electrolyte solution, conductive layers <NUM>, <NUM>, <NUM> and <NUM> made of a conductive epoxy layer are formed on a surface coming into contact with the electrolyte solution, respectively.

Meanwhile, the coin-type secondary battery <NUM> may further include a gasket <NUM> for sealing the first case <NUM> and the second case <NUM>.

Moreover, the conductive layers <NUM> , <NUM>, <NUM> and <NUM> preferably include a material having conductivity, considering that the cases, spring and spacer of the coin-type secondary battery are made of metal, and these themselves serve as electrode terminals. In particular, when the conductive layers <NUM> , <NUM> , <NUM> and <NUM> are formed wholly on the inner surface of the case, ensuring conductivity as much as corrosion is prevented is a very important issue. Even if the corrosion is prevented, the performance as a secondary battery will be eventually deteriorated if the conductivity is not sufficiently secured, and thus there is no choice but to lose the meaning of the invention.

Therefore, the conductive layers <NUM> , <NUM>, <NUM> and <NUM> are made of one a conductive epoxy layer.

Such specific materials will be described again below.

On the other hand, in another embodiment of the present disclosure, the secondary battery is a cylindrical secondary battery,
the electrode assembly is a jelly-roll type or stack/folding type electrode assembly,.

That is, the bottom part of the cylindrical can and the components of the cap assembly are made of metal, and the degree of corrosion is severe depending on what kind of material is used as the electrolyte solution, the lifespan characteristics are deteriorated, or it will be unusable any more or the safety may be threatened.

Additionally, the components necessarily require conductivity.

Thus, according to the present disclosure, a conductive layer can be formed on a surface where the components come into contact with the electrolyte solution, thereby preventing corrosion due to the electrolyte solution while having conductivity.

On the other hand, the housing part, the beading part, and the gasket excluding the bottom surface of the cylindrical can do not necessarily require conductivity as described above, and thus the conductive layer does not need to be formed. However, a conductive layer may also be formed on the surfaces of these components, and such a structure is not excluded.

In the present disclosure, a perspective view of a cylindrical secondary battery in which such a conductive layer is formed is shown in <FIG> below.

Referring to <FIG>, the secondary battery <NUM> according to the present disclosure is structured such that an electrode assembly <NUM> including a positive electrode, a separator, and a negative electrode is housed together with an electrolyte solution in a cylindrical can <NUM> including a housing part <NUM> and a beading part <NUM> as a battery case, wherein a cap assembly <NUM> including the upper end cap <NUM> is located at the opened upper end part of the cylindrical can <NUM> and seals the cylindrical can <NUM>.

In this case, the electrode assembly <NUM> may be a jelly-roll type or a stack/folding type electrode assembly, without being limited thereto.

The jelly-roll type electrode assembly is manufactured by interposing a sheet-type separator between a sheet-type positive electrode and a sheet-type negative electrode and winding it.

The stack/folding type electrode assembly is manufactured by arranging a unit electrode, a full cell stacked so that electrodes having the same polarity are located at both ends, and a bi-cell stacked so that electrodes having different polarities are located at both ends, on a sheet-type separation film, and winding the same.

Specific configurations of the jelly-roll type electrode assembly and the stack/folding type electrode assembly are conventionally known, and thus detailed descriptions thereof will be omitted herein.

More specifically, the secondary battery <NUM> according to the present disclosure includes a gasket <NUM> mounted on the upper end part of the beading part <NUM> of the cylindrical can <NUM>, and is formed in a structure in which the cap assembly <NUM> includes an upper end cap <NUM>, a current interruption safety device (PTC device, <NUM>) stacked under the upper end cap <NUM> and a safety vent <NUM> for internal pressure drop, and a current interruption device (CID) <NUM> formed at the lower end of the safety vent <NUM>.

Further, the positive electrode tab <NUM> and the negative electrode tab <NUM> are drawn out from the electrode assembly <NUM>, the positive electrode tab <NUM> is connected to the cap assembly <NUM>, and the negative electrode tab <NUM> is connected to a bottom surface <NUM> spaced apart from a housing part <NUM> of the cylindrical can <NUM>.

Here, the current interruption safety device <NUM>, the safety vent <NUM>, and the current interruption device <NUM> all are preferably structures through which current flows, which are formed in order to ensure the safety of the secondary battery.

Since other specific contents are conventionally known, a description thereof will be omitted herein.

On the other hand, as described above, the current interruption safety device <NUM>, the safety vent <NUM>, the current interruption device <NUM>, as well as the upper end cap <NUM> serving as a positive electrode terminal, the bottom surface <NUM> of the cylindrical can <NUM> serving as a negative electrode terminal, and the positive electrode tab <NUM> and the negative electrode tab <NUM> preferably have conductivity. Therefore, a conductive layer <NUM> may be formed on the inside surface of the secondary battery <NUM> in order to prevent corrosion due to leakage of the electrolyte solution while maintaining conductivity, in which the secondary battery <NUM> includes the upper end cap <NUM>, the bottom surface <NUM> of the cylindrical can, the current interruption safety device <NUM>, the safety vent <NUM>, the current interruption device <NUM>, the positive electrode tab <NUM>, and the negative electrode tab <NUM>.

In this case, the conductive layer <NUM> may be formed wholly on the surface of the above members exposed inside the secondary battery, but may be formed only on a surface toward the electrode assembly in each member.

On the other hand, a conductive layer for corrosion prevention may be formed on the housing part <NUM>, the beading part <NUM>, and the gasket <NUM> excluding the bottom surface <NUM> of the cylindrical can <NUM>, without being limited thereto, or the above components do not necessarily require conductivity, and thus other anti-corrosion layers <NUM> may be formed.

Furthermore, the secondary battery <NUM> according to the present disclosure may further include a hollow center pin <NUM> inserted into the center of the jelly-roll type electrode assembly <NUM>.

At this time, the center pin <NUM> may also be made of any one selected from the group consisting of metal, specifically aluminum, nickel, stainless steel (SUS), copper, iron, bronze, and brass, which thus causes corrosion to the electrolyte. However, the conductivity is not necessarily required.

Therefore, although the outer surface and the inner surface of the center pin <NUM> are not clearly shown in the figure, also in the outer surface coming into contact with an electrolyte solution in the center pin <NUM>, a conductive layer may be formed, other anti-corrosion layers <NUM> may be additionally formed, and more specifically, the anti-corrosion layer <NUM> may be formed up to the hollow inner surface.

That is, according to the present disclosure, the conductive layer <NUM> may be formed at a portion that is likely to come into contact with the electrolyte solution, whereby the conductivity may not be lowered while effectively preventing corrosion due to contact with the electrolyte solution, which is thus more preferable.

In another embodiment, the secondary battery is a prismatic secondary battery,.

More specifically, the electrode assembly comprises a positive electrode tab and a negative electrode tab drawn out from the electrode assembly, wherein the positive tab and the negative tab are respectively connected to the cap terminals, and
a conductive epoxy layer is formed on the inside surface of the secondary battery, in at least one member selected from the group consisting of the positive electrode tab and the negative electrode tab.

That is, the inner surface of the cap terminals of the top cap, the positive electrode tab, and the negative electrode tab are made of metal, and the degree of corrosion is severe depending on what kind of material is used as the electrolyte solution, the lifespan characteristics are deteriorated, or it will be unusable any more or the safety may be threatened.

Moreover, these components necessarily require conductivity.

Therefore, according to the present disclosure, a conductive layer can be formed on a surface where the components come into contact with the electrolyte solution, thereby preventing corrosion due to the electrolyte solution while having conductivity.

On the other hand, the can body, the portion excluding the cap terminals of the top cap, and the gasket do not necessarily require conductivity, and thus the conductive layer does not need to be formed. However, a conductive layer may be formed even on the surface of these components, and such a structure is not excluded.

In the present disclosure, a perspective view of a prismatic secondary battery in which such a conductive layer is formed is shown in <FIG> below.

Referring to <FIG>, the secondary battery <NUM> according to the present disclosure comprises a rectangular can body <NUM> that is opened in its upper end and houses the electrode assembly <NUM> and the electrolyte solution together, and a top cap <NUM> including cap terminals <NUM> that are coupled and sealed to the upper end part of the can body <NUM> and are connected to the electrode terminals <NUM> and <NUM> of the electrode assembly <NUM>.

Here, the electrode assembly <NUM> is the same as those described for the cylindrical secondary battery.

Further, the electrode assembly <NUM> includes a positive electrode tab <NUM> and a negative electrode tab <NUM> drawn upward from the electrode assembly <NUM>, and the positive electrode tab <NUM> and the negative electrode tab <NUM> are respectively connected to the can terminals <NUM>.

At this time, since the positive electrode tab <NUM>, the negative electrode tab <NUM>, and the cap terminals <NUM> must have conductivity, a conductive layer <NUM> made of one selected from the group consisting of a conductive carbon layer, a conductive polymer layer, and a conductive epoxy layer are formed on the inside surface of the secondary battery <NUM>.

On the other hand, a conductive layer for corrosion prevention may be formed on the portion excluding the cap terminals <NUM> of the prismatic can body <NUM> and the top cap <NUM>, without being limited thereto, or the components do not necessarily require conductivity and thus, other anti-corrosion layers <NUM> and <NUM> may be formed.

At this time, the center pin <NUM> may also made of metal, specifically any one selected from the group consisting of aluminum, nickel, stainless steel (SUS), copper, iron, bronze, and brass, which thus causes corrosion to the electrolyte solution. However, the conductivity is not necessarily required.

Therefore, although the outer surface and inner surface of the center pin <NUM> are not clearly shown in the figure, a conductive layer may also be formed on the outer surface coming into contact with an electrolyte solution in the center pin <NUM>, other anti-corrosion layers <NUM> may be additionally formed, and more specifically, the anti-corrosion layer <NUM> may be formed up to the hollow inner surface.

On the other hand, in all cases, the conductive layer may have a thickness of <NUM> µm to <NUM> µm, specifically <NUM> µm to <NUM> µm, and more specifically, <NUM> µm to <NUM> µm.

If the conductive layer is too thin outside the above range, it cannot exhibit a sufficient anti-corrosion effect, and if the conductive layer is too thick, the conductivity may be lowered or the bulk energy density may be lowered, which is thus not preferable.

The metals constituting the above components may be made of any one selected from the group consisting of aluminum, nickel, stainless steel (SUS), copper, iron, bronze, and brass, and specifically, it may be made of aluminum or stainless steel (SUS), and more specifically, it may be made of stainless steel (SUS).

On the other hand, since the conductive layer should have conductivity as described above, it is made of a conductive epoxy layer.

The conductive epoxy layer may include a conductive filler and an epoxy polymer.

Here, the conductive filler may be at least one selected from the group consisting of metal powders of gold, platinum, silver, copper, or nickel, carbon or carbon fibers, graphite, and composite powder.

The epoxy polymer is a component that binds the conductive filler, and examples thereof may be at least one selected from the group consisting of acrylic-based, epoxy-based, polyurethane-based, silicon-based, polyimide-based, phenolic-based, polyester-based polymer materials, composite polymer resins and low melting point glass, without being limited thereto.

Meanwhile, the conductive epoxy layer may be classified into a room-temperature drying type, a room-temperature curing type, a heat-curing type, a high-temperature sintering type, and a UV curing type, based on the production method.

The room-temperature drying type may be formed by incorporating a conductive filler into an acrylic polymer such as acrylic-based and a solvent, and drying it at room temperature, and the room-temperature curing type is a two-component type and may be formed by additionally containing a highly reactive curing agent and curing a solvent containing a conductive filler and an epoxy polymer.

Further, the heat-curing type can be formed by applying heat to a solvent containing a conductive filler, mainly using an epoxy-based epoxy polymer, and the high-temperature sintering type can be formed by curing by heat treatment at a high temperature, and the UV-curable type can be formed by curing by the irradiation with UV.

In this case, the conductive filler and the epoxy binder may also be contained in a weight ratio of <NUM>:<NUM> to <NUM>: <NUM>, specifically, in a weight ratio of <NUM>:<NUM> to <NUM>:<NUM>.

When the content of the conductive filler is too low outside the above range, the conductivity decreases and thus the resistance increases, and when the content of the epoxy polymer is too low, the binding force of the conductive filler cannot be obtained, which is thus not preferable.

On the other hand, it is more preferable that the conductive layer has a configuration that can effectively prevent corrosion by an electrolyte solution even after long-term use while having excellent conductivity, and specifically, it may be a conductive polymer layer or a conductive epoxy layer.

However, the electrolyte contains a non-aqueous electrolyte and a lithium salt, and the coin-type secondary battery according to the present disclosure is more effective when a lithium imide-based salt is used as the lithium salt.

The lithium imide-based salt may be lithium bis(fluorosulfonyl)imide, lithium bis(trifluoromethanesulfonyl)imide or lithium bis(perfluoroethylsulfonyl)imide. Preferably, the lithium imide-based salt is lithium bis(fluorosulfonyl)imide or lithium bis(trifluoromethanesulfonyl)imide.

Hereinafter, preferred examples of the present disclosure, comparative examples compared thereto, and experimental examples for evaluating them will be described.

<NUM> of graphene as a conductive material was put in <NUM> of NMP solvent, and then dispersed by adding an H-NBR dispersant, which was mixed with <NUM> of PVdF as a binder to prepare a conductive carbon layer precursor solution.

<NUM> of natural graphite as a conductive material was put in <NUM> of NMP solvent, and then dispersed by adding an H-NBR dispersant, which was mixed with <NUM> of PVdF as a binder to prepare a conductive carbon layer precursor solution.

<NUM> of acetylene black as a conductive material was put in <NUM> of NMP solvent, and then dispersed by adding an H-NBR dispersant, which was mixed with <NUM> of PVdF as a binder to prepare a conductive carbon layer precursor solution.

<NUM> of polypyrrole as a conductive polymer was mixed with <NUM> of dimethylformamide (DMF) as a solvent, and the mixture was stirred (<NUM>) for <NUM> hours with a magnetic bar to prepare a conductive polymer layer precursor solution.

<NUM> product (two-component electroconductive epoxy adhesive containing silver) available from MG Chemicals was used.

<NUM> of polymethyl methacrylate (PMMA) as a polymer was mixed with <NUM> of dimethylformamide (DMF) as a solvent, and the mixture was stirred (<NUM>) for <NUM> hours with a magnetic bar to prepare a binder solution.

The conductive carbon layer precursor solution prepared in Preparation Example <NUM> was coated (spray coated) onto the surface where the first case, the second case, the spring, and the spacer as a coin-type battery case could come into contact with the electrolyte solution as shown in <FIG>. A positive electrode mixture having a composition of <NUM> wt. % of positive active material (LiNi<NUM>Co<NUM>Mn<NUM>O<NUM>), <NUM> wt. % of Super-P (conductive material), and <NUM> wt. % of PVDF (binder) was added to NMP (N-methyl-<NUM>- pyrrolidone) as a solvent to prepare a positive electrode slurry, and then the slurry was coated (<NUM> µm) onto an aluminum current collector substrate to prepare a coin-type positive electrode.

A negative electrode mixture having a composition of <NUM> wt. % of artificial graphite, <NUM> wt. % of Super-P (conductive material), and <NUM> wt. % of PVDF (binder) was added to NMP (N-methyl-<NUM>- pyrrolidone) as a solvent to prepare a negative electrode slurry, and then the slurry was coated (<NUM> µm) onto a copper current collector substrate to prepare a coin-type negative electrode.

A polyethylene-based separator was interposed between the prepared positive electrode and negative electrode to prepare an electrode assembly, and the electrode assembly was incorporated in the coin-type case as shown in <FIG>, and a solution of ethylene carbonate (EC) and dimethyl carbonate (DMC) in a volume ratio of <NUM>:<NUM> in which <NUM> LiFSI was dissolved was injected as an electrolyte, and then sealed with a gasket to manufacture a coin-type secondary battery.

A coin-type secondary battery was manufactured in the same manner in Example <NUM>, except that in Example <NUM>, the conductive polymer layer precursor solution prepared in Preparation Example <NUM> was coated (spray coated) onto the surface where the first case, the second case, the spring, and the spacer as a coin-type battery case could come into contact with the electrolyte solution.

A coin-type secondary battery was manufactured in the same manner in Example <NUM>, except that in Example <NUM>, the conductive epoxy layer precursor solution prepared in Preparation Example <NUM> was coated (spray coated) onto the surface where the first case, the second case, the spring, and the spacer as a coin-type battery case could come into contact with the electrolyte solution.

A coin-type secondary battery was manufactured in the same manner in Example <NUM>, except that in Example <NUM>, the conductive carbon layer precursor solution prepared in Preparation Example <NUM> was coated (spray coated) onto the surface where the first case, the second case, the spring, and the spacer as a coin-type battery case could come into contact with the electrolyte solution.

A coin-type secondary battery was manufactured in the same manner in Example <NUM>, except that in Example <NUM>, any coating treatment was not performed onto the surface where the first case, the second case, the spring, and the spacer as a coin-type battery case could come into contact with the electrolyte solution.

The coin cell batteries manufactured in Examples <NUM> to <NUM> and Comparative Example <NUM> were charged and discharged <NUM> times under the following conditions, and then the <NUM>-time discharge capacity retention relative to the one-time discharge capacity was calculated, and the results are shown in Table <NUM> below.

Referring to Table <NUM>, it can be confirmed that when the conductive layer is formed according to the present disclosure, it exhibits excellent lifetime characteristics as compared with Comparative Example <NUM> that was failed to take any action.

The coin cell batteries manufactured in Examples <NUM> and <NUM> and <NUM> were rate-evaluated under the following conditions.

The capacity retention of the average discharge capacity value at <NUM> C obtained in the 4th to 6th cycle relative to the average discharge capacity value at <NUM>. 1C obtained in the initial <NUM>-time charge/discharge was calculated, and the results are shown in Table <NUM> below.

Referring to Table <NUM>, it can be confirmed that when the conductive carbon layer containing a conductive material other than graphene was coated according to Comparative Examples <NUM> and <NUM>, metal corrosion can be prevented in Experimental Example <NUM> and thus lifetime characteristics are excellent, but compared with the case of using graphene, the conductivity is reduced by the coating and the rate characteristic is lowered, which is thus not preferable.

The conductive carbon layer precursor solution prepared in Preparation Example <NUM> was coated (spray coated) onto the housing part of the cylindrical battery case, the beading part and the upper end cap.

A positive electrode mixture having a composition of <NUM> wt. % of positive active material (LiNi<NUM>Co<NUM>Mn<NUM>O<NUM>), <NUM> wt. % of Super-P (conductive material), and <NUM> wt. % of PVDF (binder) was added to NMP (N-methyl-<NUM>- pyrrolidone) as a solvent to prepare a positive electrode slurry, and then the slurry was coated (<NUM> µm) onto an aluminum current collector substrate to prepare a coin-type positive electrode.

A polyethylene-based separator was interposed between the prepared positive electrode and negative electrode to prepare an electrode assembly, and the electrode assembly was incorporated in the cylindrical battery case as shown in <FIG>, and a solution of ethylene carbonate (EC) and dimethyl carbonate (DMC) in a volume ratio of <NUM>:<NUM> in which <NUM> LiFSI was dissolved was injected as an electrolyte, and then sealed with a gasket to manufacture a cylindrical secondary battery.

A cylindrical secondary battery was manufactured in the same manner in Example <NUM>, except that in Example <NUM>, the conductive polymer layer precursor solution prepared in Preparation Example <NUM> was coated onto the housing part of the cylindrical battery case, the beading part and the upper end cap.

A cylindrical secondary battery was manufactured in the same manner in Example <NUM>, except that in Example <NUM>, the conductive epoxy layer precursor solution prepared in Preparation Example <NUM> was coated onto the housing part of the cylindrical battery case, the beading part and the upper end cap.

A cylindrical secondary battery was manufactured in the same manner in Example <NUM>, except that in Example <NUM>, the conductive carbon layer precursor solution prepared in Preparation Example <NUM> was coated onto the housing part of the cylindrical battery case, the beading part and the upper end cap.

A cylindrical secondary battery was manufactured in the same manner in Example <NUM>, except that in Example <NUM>, any coating treatment was not performed onto the housing part of the cylindrical battery case, the beading part and the upper end cap.

A cylindrical secondary battery was manufactured in the same manner in Example <NUM>, except that in Example <NUM>, Cr metal was electrolytically-plated and coated onto the housing part of the cylindrical battery case, the beading part and the upper end cap.

A cylindrical secondary battery was manufactured in the same manner in Example <NUM>, except that in Example <NUM>, the binder solution prepared in Preparation Example <NUM> was coated onto the housing part of the cylindrical battery case and the beading part. In the case of coating the upper end cap with a binder solution, it acts as a resistance of a large current, and thus the lifetime characteristics cannot be evaluated. Therefore, the binder coating was formed only on the housing part and the beading part.

The cylindrical secondary batteries manufactured in Examples <NUM> to <NUM> and Comparative Examples <NUM> to <NUM> were charged and discharged <NUM> times under the following conditions, and then the <NUM>-time discharge capacity retention relative to the one-time discharge capacity was calculated, and the results are shown in Table <NUM> below.

Referring to Table <NUM>, it can be confirmed that when the conductive layer is formed according to the present disclosure, it exhibits excellent lifetime characteristics as compared with Comparative Example <NUM> electrolytically coated with another metal and Comparative Example <NUM> in which a binder layer was formed,.

The cylindrical secondary batteries manufactured in Examples <NUM> and <NUM> were rate-evaluated under the following conditions.

Referring to Table <NUM>, it can be confirmed that even if the same conductive carbon layer is formed, the use of graphene exhibits superior rate characteristics than when acetylene black is used.

Claim 1:
A secondary battery (<NUM>: <NUM>; <NUM>) configured such that an electrode assembly (<NUM>;<NUM>; <NUM>) including a positive electrode (<NUM>), a separator (<NUM>), and a negative electrode (<NUM>) is housed in a battery case together with an electrolyte solution,
wherein the battery case is made of metal, and a conductive layer (<NUM>, <NUM>, <NUM>, <NUM>;<NUM>) consisting of a conductive epoxy layer is formed on a part or the whole of the inner surface of the battery case coming into contact with the electrolyte solution.