Patent Description:
Recently, in response to industrial demands, batteries having high energy density and safety have been actively developed. For example, lithium-ion batteries are being used not only in the fields of information-related appliances and communication appliances, but also in the fields of automobiles. In the fields of automobiles, safety is especially important because it has an influence on life.

Since commercially available lithium-ion batteries use an electrolyte including a flammable organic solvent, there is a possibility of overheating and fire when a short circuit occurs. In this regard, all-solid batteries using a solid electrolyte instead of an electrolyte have been proposed.

Since all-solid batteries do not use flammable organic solvents, even when a short circuit occurs, the possibility of fire or explosion may be greatly reduced. Accordingly, safety of such all-solid secondary batteries may greatly increase as compared with that of lithium-ion batteries.

Further, one of the characteristics of all-solid secondary batteries is that they can easily be built with a bipolar structure unlike general lithium-ion batteries, and thus the number of parts may be reduced, and large currents flow easily, thus allowing the development of high-power, high-energy-density cells having high voltages. However, it is difficult to design a structure capable of absorbing a volume change due to a lithium deposition reaction used in the anode of an all-solid secondary battery.

<CIT> relates to a battery module structured by layering bipolar batteries, an assembled battery structured by electrically connecting a plurality of battery modules, and a vehicle including these batteries. <CIT> relates to a stacked battery in which sneak current caused by an unevenness of a short circuit resistance among a plurality of cells is to be suppressed. In Deiseroth et al. (<NPL>)) argyrodite-type sulfide-based solid electrolyte for solid state batteries is described. In Lee et al. (<NPL>)) high energy long cycling all-solid lithium metal batteries with carbon-silver composite anodes and argyrodite sulfide-based solid electrolyte are disclosed.

One or more embodiments are to provide a bipolar stack unit cell structure capable of absorbing a volume change of an anode.

One or more embodiments are to provide an all-solid secondary battery including the bipolar stack unit cell structure.

According to one or more embodiments, a bipolar stack unit cell structure includes: a bicell in which a first anode current collector, a first anode active material layer, a first electrolyte layer, a first cathode active material layer, a cathode current collector, a second cathode active material layer, a second electrolyte layer, a second anode active material layer, and a second anode current collector are sequentially arranged, wherein a plurality of the bicells are stacked, and a compression pad is provided between the first anode current collector and second anode current of adjacent bicells of the plurality of bicells.

The bipolar stack unit cell structure may further comprise: a first bipolar plate and a second bipolar plate, which are located on the first anode current collector and the second anode current collector existing at both ends of the bipolar stack unit cell structure, respectively. Compression pads may be further provided between the first anode current collector existing at one of the ends of the bipolar stack unit cell structure and the first bipolar plate and between the second anode current collector existing at the other of the ends of the bipolar stack unit cell structure and the second bipolar plate.

The compression pad is made of an elastic material.

The elastic material includes at least one selected from polyurethane, natural rubber, spandex, butyl rubber (isobutylene isoprene rubber, IIR), fluoroelastomer, elastomer, ethylene-propylene rubber (EPR), styrene-butadiene rubber (SBR), chloroprene, elastin, rubber epi Chlorohydrin, nylon, terpene, isoprene rubber, polybutadiene, nitrile rubber, thermoplastic elastomer, silicone rubber, ethylene-propylene-diene rubber (EPDM), ethylene vinyl acetate (EVA), halogenated butyl rubber, neoprene, and copolymers thereof.

The compression pad is pressed to have a thickness of about <NUM>% to about <NUM>% of an initial thickness thereof before being pressed.

A thickness of a compression pad is set in a range of about <NUM>% to about <NUM>% of a thickness of a lithium deposition layer of an anode formed when charging an all-solid secondary battery including the bipolar stack unit cell structure.

The first electrolyte layer and the second electrolyte layer includes a solid electrolyte.

Preferably, the solid electrolyte is a sulfide-based solid electrolyte, and the sulfide-based solid electrolyte is at least one selected from P<NUM>S<NUM>, Li<NUM>S-P<NUM>S<NUM>-LiX (where X is a halogen element), Li<NUM>S-P<NUM>S<NUM>-Li<NUM>O, Li<NUM>S-P<NUM>S<NUM>-Li<NUM>O-Lil, Li<NUM>S-SiS<NUM>, Li<NUM>S-SiS<NUM>-Lil, Li<NUM>S-SiS<NUM>-LiBr, Li<NUM>S-SiS<NUM>-LiCl, Li<NUM>S-SiS<NUM>-B<NUM>S<NUM>-Lil, Li<NUM>S-SiS<NUM>-P<NUM>S<NUM>-Lil, Li<NUM>S-B<NUM>S<NUM>, Li<NUM>S-P<NUM>S<NUM>-ZmSn (where m and n are each a positive number, and Z is one selected from Ge, Zn, and Ga), Li<NUM>S-GeS<NUM>, Li<NUM>S-SiS<NUM>-Li<NUM>PO<NUM>, Li<NUM>S-SiS<NUM>-LipMOq (where p and q are each a positive number, and M is one selected from P, Si, Ge, B, Al, Ga, and In), Li<NUM>-xPS<NUM>-xClx (<NUM>≤x≤<NUM>), Li<NUM>-xPS<NUM>-xBrx (<NUM>≤x≤<NUM>), and Li<NUM>-xPS<NUM>-xIx (<NUM>≤x≤<NUM>).

Preferably, the solid electrolyte is an argyrodite-type sulfide-based solid electrolyte including at least one selected from Li<NUM>PS<NUM>Cl, Li<NUM>PS<NUM>Br, and Li<NUM>PSSI.

The first anode active material layer and the second anode active material layer may include an anode active material and a binder. The anode active material may have a particle form. The anode active material may have an average particle diameter of <NUM> or less, the average particle diameter being a median diameter measured by a laser diffraction method.

The anode active material may include at least one selected from a carbon-based anode active material and a metal or metalloid anode active material, and the carbon-based anode active material includes amorphous carbon.

Preferably, the metal or metalloid anode active material includes at least one selected from gold (Au), platinum (Pt), palladium (Pd), silicon (Si), silver (Ag), aluminum (Al), bismuth (Bi), tin (Sn), and zinc (Zn).

Preferably, the anode active material includes a mixture of first particles made of amorphous carbon and second particles made of metal or a metalloid, and a content of the second particles is about <NUM> wt% to about <NUM> wt% based on a total weight of the mixture.

The bipolar stack unit cell structure may further comprise: a fourth anode active material layer provided i) between the first anode current collector and the first anode active material layer, ii) between the first anode active material layer and the first electrolyte layer, iii) between the second electrolyte layer and the second anode active material layer, and/or iv) between the second anode active material layer and the second anode current collector, wherein the fourth anode active material layer may be a metal layer. The metal layer may include lithium or a lithium alloy.

According to one or more embodiments, an all-solid secondary battery includes: the above-described bipolar stack unit cell structure, wherein a plurality of the bipolar stack unit cells are stacked.

The all-solid secondary battery may further comprise: a cathode terminal and an anode terminal at both ends of the stacked bipolar stack unit cell structure. A third cathode active material layer, a third electrolyte layer, a third anode active material layer, a third anode current collector, and a compression pad may be further arranged sequentially from the cathode terminal between the cathode terminal and a first anode current collector or a second anode current collector adjacent thereto.

All embodiments described in this specification may be advantageously combined with one another to the extent that their respective features are compatible.

The present inventive concept will now be described more fully with reference to the accompanying drawings, in which example embodiments are illustrated.

The terms used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the inventive concept. Singular expressions include plural expressions unless the context clearly indicates otherwise. As used herein, the slash "/" or the term "and/or" includes any and all combinations of one or more of the associated listed items.

In the drawings, the thickness is enlarged or reduced in order to clearly express various layers and regions. Throughout the specification, the same reference numerals are attached to similar parts Throughout the specification, when an element such as a layer, a film, a region or a component is referred to as being "on" another layer or element, it can be "directly on" the other layer or element, or intervening layers, regions, or components may also be present. Although the terms "first", "second", "third", etc., may be used herein to describe various elements, components, regions, and/or layers, these elements, components, regions, and/or layers should not be limited by these terms. These terms are used only to distinguish one component from another, not for purposes of limitation.

Hereinafter, a bipolar stack unit cell structure according to embodiments and an all-solid secondary battery including the same will be described in more detail.

Conventionally, it is difficult to design a structure capable of absorbing a volume change due to a lithium deposition reaction used in an anode of an all-solid secondary battery with a bipolar structure, and a current collector also uses expensive SUS, which also acts as a price increase factor.

In conventional all-solid secondary batteries, a structure in which stacked cells are placed in a bipolar structure to increase the capacity of a cell has been proposed, but a structure for absorbing a volume change has not been proposed.

Accordingly, the present inventors intend to provide a bipolar stack unit cell structure for all-solid secondary batteries, capable of solving the above-described problems, and an all-solid secondary battery including the same.

A bipolar stack unit cell structure according to an embodiment includes: a bicell in which a first anode current collector, a first anode active material layer, a first electrolyte layer, a first cathode active material layer, a cathode current collector, a second cathode active material layer, a second electrolyte layer, a second anode active material layer, and a second anode current collector are sequentially arranged, wherein a plurality of the bicells are stacked, and a compression pad is provided between the first anode current collector and second anode current of adjacent bicells of the plurality of bicells.

A bi-cell forming the bipolar stack unit cell structure of an embodiment has a C-type bicell structure in which one cathode layer on both sides thereof and two anode layers as a single plate are symmetrical to each other. When a plurality of bicells are stacked, a compression pad is installed between adjacent bicells to absorb a volume change of the cathode layer in the bipolar stack unit cell structure. In the bipolar stack unit cell structure, since a compression pad capable of absorbing the volume change of the anode layer is provided, the volume change of the entire cell can be suppressed to obtain a stable lifetime, and stack and bipolar structures may be simultaneously provided, so capacity and voltage can be freely designed.

<FIG> is a schematic cross-sectional view of a bipolar stack unit cell structure according to an embodiment.

As shown in <FIG>, a bipolar stack unit cell structure <NUM> is a structure in which a plurality of bicells <NUM> are stacked, and each of the bicells <NUM> has a structure in which a first anode current collector <NUM>, a first anode active material layer <NUM>, a first electrolyte layer <NUM>, a first cathode active material layer <NUM>, a cathode current collector <NUM>, a second cathode active material layer <NUM>', a second electrolyte layer <NUM>', a second anode active material layer <NUM>', and a second anode current collector <NUM>' are sequentially arranged. In the bipolar stack unit cell structure <NUM>, the plurality of bi-cells <NUM> are stacked, and a compression pad <NUM> is provided between the first anode current collector <NUM> and the second anode current collector <NUM>' of the adjacent bicells <NUM>.

As shown in <FIG>, a first bipolar plate <NUM> and a second bipolar plate <NUM>' may be further provided on the first anode current collector <NUM> and the second anode current collector <NUM>' existing at both ends of the bipolar stack unit cell structure <NUM>, respectively. In this case, the compression pads <NUM> may also be further provided between the first anode current collector <NUM> existing at the end thereof and the first bipolar plate <NUM> and between the second anode current collector <NUM>' existing at the end thereof and the second bipolar plate <NUM>'.

The compression pads <NUM> provided between the first anode current collector <NUM> and the second anode current collector <NUM>' of the adjacent bicells <NUM>, between the first anode current collector <NUM> existing at the end of the bipolar stack unit cell structure <NUM> and the first bipolar plate <NUM> and between the second anode current collector <NUM>' existing at the end thereof and the second bipolar plate <NUM>' are sheets made of an elastic material.

The elastic material includes at least one selected from polyurethane, natural rubber, spandex, butyl rubber (isobutylene isoprene rubber, IIR), fluoroelastomer, elastomer, ethylene-propylene rubber (EPR), styrene-butadiene rubber (SBR), chloroprene, elastin, rubber epi Chlorohydrin, nylon, terpene, isoprene rubber, polybutadiene, nitrile rubber, thermoplastic elastomer, silicone rubber, ethylene-propylene-diene rubber (EPDM), ethylene vinyl acetate (EVA), halogenated butyl rubber, neoprene, and copolymers thereof. However, the present disclosure is not limited thereto, and any elastic material may be used without limitation as long as it has elasticity. According to an embodiment, the compression pad <NUM> may be made of a urethane-based material, for example, polyurethane.

The compression pad <NUM> is pressed to have a thickness of about <NUM>% to about <NUM>% of an initial thickness thereof before applying pressure. Specifically, for example, the compression pad <NUM> may be pressed to have a thickness of about <NUM>% to about <NUM>%, about <NUM>% to about <NUM>%, or about <NUM>% to about <NUM>% of the initial thickness thereof before applying pressure. Since the volume change of the anode is effectively absorbed within the above range, it is possible to smoothly charge and discharge an all-solid secondary battery.

The thickness of the compression pad <NUM> is set in a range of about <NUM>% to about <NUM>% of a thickness of a lithium deposition layer of an anode formed when charging an all-solid secondary battery. In an all-solid secondary battery, the thickness of the lithium deposition layer of the anode is determined in proportion to the current density of the cathode. That is, the thickness of the lithium deposition layer of the anode is determined according to the amount of lithium moving from the cathode to the anode, and thereby the volume change of the anode occurs. Accordingly, the thickness of the compression pad <NUM> may be determined to absorb the volume change of the anode. Therefore, the thickness of the compression pad <NUM> is set to be in a range of about <NUM>% to about <NUM>% of a thickness of a lithium deposition layer of the anode formed when charging an all-solid secondary battery, thereby effectively absorbing the voltage change of the anode. For example, the thickness of the compression pad <NUM> is in a range of about <NUM>% to about <NUM>%, specifically, about <NUM>% to about <NUM>% of a thickness of a lithium deposition layer of the anode formed when charging an all-solid secondary battery.

The thickness of the compression pad <NUM> may be set in the range of about <NUM> to about <NUM>, and in some case, may be selectively set in the range of about <NUM> to about <NUM>, about <NUM> to about <NUM>, or about <NUM> to about <NUM>.

As such, since the compression pad <NUM> is provided between the anode current collectors, the volume change caused by a lithium (Li) deposition reaction used in the anode may be absorbed, and thus the volume change of the entire cell may be suppressed, thereby obtaining stable lifetime.

In the C-type bicell, the cathode layer includes a cathode current collector <NUM> and a first cathode active material layer <NUM> and a second cathode active material layer <NUM>' disposed on both surfaces of the cathode current collector <NUM>.

The first and second cathode active material layers <NUM> and <NUM>' include, for example, a cathode active material and a solid electrolyte. The solid electrolyte included in the first and second cathode active material layers <NUM> and <NUM>' is similar to or different from the solid electrolyte included in the first and second electrolyte layers <NUM> and <NUM>'. For details of the solid electrolyte, refer to those of the first and second electrolyte layers <NUM> and <NUM>'.

The cathode active material is a cathode active material capable of reversibly absorbing and desorbing lithium ions. The cathode active material is, for example, a lithium transition metal oxide such as a lithium cobalt oxide (LCO), a lithium nickel oxide, a lithium nickel cobalt oxide, a lithium nickel cobalt aluminum oxide (NCA), a lithium nickel cobalt manganese oxide (NCM), lithium manganate, lithium and iron phosphate, and a nickel sulfide, a copper sulfide, a lithium sulfide, an iron oxide, or a vanadium oxide, and the like, but is not limited thereto, and any one available as a cathode active material in the art may be used. The cathode active materials may each be used alone or as a mixture of two or more thereof.

The lithium transition metal oxide is a compound represented by one of, for example, LiaA<NUM>-bBbD<NUM> (where <NUM>≤a≤ <NUM>, and <NUM>≤b≤<NUM>); LiaE<NUM>-bBbO<NUM>-cDc (where <NUM>≤a≤<NUM>, <NUM>≤b≤<NUM>, and <NUM>≤c≤<NUM>); LiE<NUM>-bBbO<NUM>-cDc (where <NUM>≤b≤<NUM>, and <NUM>≤c≤<NUM>); LiaNi<NUM>-b-cCobBcDα(where <NUM>≤a≤ <NUM>, <NUM>≤b≤<NUM>, <NUM>≤c≤<NUM>, and <NUM><α≤<NUM>); LiaNi<NUM>-b-cCobBcO<NUM>-αFα(where <NUM>≤a≤<NUM>, <NUM>≤b≤<NUM>, <NUM>≤c≤<NUM>, and <NUM><α<<NUM>); LiaNi<NUM>-b-cCobBcO<NUM>-αF<NUM> (where <NUM>≤a≤<NUM>, <NUM>≤b≤<NUM>, <NUM>≤c≤<NUM>, and <NUM><α< <NUM>); LiaNi<NUM>-b-cMnbBcDα(where <NUM>≤a≤<NUM>, <NUM>≤b≤<NUM>, <NUM>≤c≤<NUM>, and <NUM><α≤<NUM>); LiaNi<NUM>-b-cMnbBcO<NUM>-αFα(where <NUM>≤a≤<NUM>, <NUM>≤b≤<NUM>, <NUM>≤c≤<NUM>, and <NUM><α<<NUM>); LiaNi<NUM>-b-cMnbBcO<NUM>-αF<NUM> (where <NUM>≤a≤<NUM>, <NUM>≤b≤<NUM>, <NUM>≤c≤<NUM>, and <NUM><α< <NUM>); LiaNibEcGdO<NUM>(where <NUM>≤a≤ <NUM>, <NUM>≤b≤<NUM>, <NUM>≤c≤<NUM>, and <NUM>≤d≤<NUM>); LiaNibCocMndGeO<NUM> (where <NUM>≤a≤<NUM>, <NUM>≤b≤<NUM>, <NUM>≤c≤<NUM>, <NUM>≤d≤<NUM>, and <NUM>≤e≤<NUM>); LiaNiGbO<NUM> (where <NUM>≤a≤ <NUM>, and <NUM>≤b≤ <NUM>); LiaCoGbO<NUM> (where <NUM>≤a≤ <NUM> and <NUM>≤b≤<NUM>); LiaMnGbO<NUM> (where <NUM>≤a≤ <NUM> and <NUM>≤ b<<NUM>); LiaMn<NUM>GbO<NUM> (where, <NUM>≤a≤ <NUM> and <NUM> ≤b≤<NUM>); LiaNibCocMndGeO<NUM>(where, <NUM> ≤ a ≤ <NUM>, <NUM> ≤ b ≤ <NUM>, <NUM> ≤ c ≤ <NUM>, <NUM> ≤ d ≤<NUM>, and <NUM> ≤ e ≤ <NUM>);LiaNiGbO<NUM>(where, <NUM> ≤ a ≤ <NUM> and <NUM> ≤ b ≤ <NUM>);LiaCoGbO<NUM>(where, <NUM> ≤ a ≤ <NUM> and <NUM> ≤ b ≤ <NUM>);LiaMnGbO<NUM>(where, <NUM> ≤ a ≤ <NUM> and <NUM> ≤ b ≤ <NUM>);LiaMn<NUM>GbO<NUM>(where, <NUM> ≤ a ≤ <NUM> and <NUM> ≤ b ≤ <NUM>);QO<NUM>; QS<NUM>; LiQS<NUM>; V<NUM>O<NUM>; LiV<NUM>O<NUM>; LilO<NUM>; LiNiVO<NUM>; Li(<NUM>-f)J<NUM>(PO<NUM>)<NUM> (<NUM>≤f≤<NUM>); Li(<NUM>-f)Fe<NUM>(PO<NUM>)<NUM> (<NUM>≤f≤<NUM>); and LiFePO<NUM>. In the compound, A is Ni, Co, Mn, or a combination thereof; B is Al, Ni, Co, Mn, Cr, Fe, Mg, Sr, V, a rare earth element, or a combinations thereof; D is O, F, S, P, or a combination thereof; E is Co, Mn, or a combination thereof; F is F, S, P, or a combination thereof; G is Al, Cr, Mn, Fe, Mg, La, Ce, Sr, V, or a combination thereof; Q is Ti, Mo, Mn, or a combination thereof; I is Cr, V, Fe, Sc, Y, or a combination thereof; and J is V, Cr, Mn, Co, Ni, Cu, or a combination thereof. A compound having a coating layer added on a surface thereof may be also used, and a mixture having the compound described above and a coating layer which are added thereto may be also used. The coating layer added to the surface of the compound includes, for example, a coating element compound of an oxide, a hydroxide, an oxyhydroxide, an oxycarbonate, or a hydroxycarbonate of the coating element. The compound forming the coating layer is amorphous or crystalline. The coating elements included in the coating layer are Mg, Al, Co, K, Na, Ca, Si, Ti, V, Sn, Ge, Ga, B, As, Zr, or a mixture thereof. A method of forming the coating layer is selected within a range which does not adversely affect properties of the cathode active material. The coating method is, for example, spraying, coating, or dipping. Since a specific coating method can be well understood by people in the art, detailed descriptions thereof will be omitted.

The cathode active material includes, for example, a lithium salt of a transition metal oxide having a layered rock salt type structure among the above-described lithium transition metal oxides. The "layered rock salt type structure", for example, is a structure wherein an oxygen atom layer and a metal atom layer are alternately and regularly arranged in the direction of <<NUM>> of a cubic rock salt type structure, whereby each atom layer forms a two-dimensional plane. "Cubic rock salt type structure" refers to a sodium chloride type (NaCl type) structure, which is a type of crystal structure, and, specifically, has a structure in which face-centered cubic lattices (FCCs) forming each of cations and anions are arranged to be displaced from each other by <NUM>/<NUM> of a ridge of a unit lattice. A lithium transition metal oxide having the layered rock salt type structure is a ternary lithium transition metal oxide, for example, LiNixCoyAlzO<NUM> (NCA) or LiNixCoyMnzO<NUM> (NCM) (<NUM><x< <NUM>, <NUM><y< <NUM>, <NUM><z<<NUM>, x+y+z=<NUM>). When the cathode active material includes a ternary lithium transition metal oxide having a layered rock salt type structure, the energy density and thermal stability of the all-solid secondary battery <NUM> are further improved.

The cathode active material may be covered by the coating layer as described above. The coating layer may be any one known as a coating layer of the cathode active material of the all-solid secondary battery. The coating layer is, for example, Li<NUM>O-ZrO<NUM> or the like.

When the cathode active material includes nickel (Ni) as a ternary lithium transition metal oxide such as NCA or NCM, the capacity density of the all-solid secondary battery <NUM> is increased, whereby metal elution of the cathode active material in a charged state may be reduced. As a result, cycle characteristics in the charge state of the all-solid secondary battery <NUM> are improved.

The shape of the cathode active material is, for example, a sphere or an elliptical sphere. The particle diameter of the cathode active material is not particularly limited and is within a range applicable to a conventional all-solid secondary battery. The content of the cathode active material in the cathode layer <NUM> is also not particularly limited and is within a range applicable to a conventional all-solid secondary battery.

The first and second cathode active material layers <NUM> and <NUM>' may include, for example, a solid electrolyte. The solid electrolyte included in the first and second cathode active material layers <NUM> and <NUM>' may be the same as or different from the solid electrolyte included in the first and second electrolyte layer <NUM> and <NUM>'. For details of the solid electrolyte included in the first and second cathode active material layers <NUM> and <NUM>', refer to those of the solid electrolyte included in the first and second electrolyte layer <NUM> and <NUM>'.

The solid electrolyte included in the first and second cathode active material layers <NUM> and <NUM>' may have a smaller average particle diameter D50 than the solid electrolyte included in the first and second electrolyte layer <NUM> and <NUM>'. For example, the average particle diameter D50 of the solid electrolyte included in the first and second cathode active material layers <NUM> and <NUM>' is <NUM>% or less, <NUM>% or less, <NUM>% or less, <NUM>% or less, <NUM>% or less, <NUM>% or less, <NUM>% or less, or <NUM>% or less of the average particle diameter D50 of the solid electrolyte included in the first and second electrolyte layer <NUM> and <NUM>'.

The average particle diameter D50 is, for example, a median particle diameter D50. The median particle diameter D50 is, for example, a particle size corresponding to a <NUM>% cumulative volume calculated from a particle having a small particle size in a particle size distribution measured by a laser diffraction method.

The first and second cathode active material layers <NUM> and <NUM>' may include a binder. Examples of the binder may include, but are not limited to, styrene butadiene rubber (SBR), polytetrafluoroethylene, polyvinylidene fluoride, and polyethylene. Any binder may be used as long as it is used in the art.

The first and second cathode active material layers <NUM> and <NUM>' may include a conductive material. Examples of the conductive material may include, but are not limited to, graphite, carbon black, acetylene black, Ketjen black, carbon fiber, and metal powder. Any conductive material may be used as long as it is used in the art.

The first and second cathode active material layers <NUM> and <NUM>' may further include additives such as a filler, a coating agent, a dispersing agent, and an ion-conductive auxiliary agent in addition to the above-described cathode active material, solid electrolyte, binder, and conductive material.

As the filler, coating agent, dispersing agent and ion-conductive auxiliary agent included in the first and second cathode active material layers <NUM> and <NUM>', known materials generally used for electrodes of all-solid secondary batteries may be used.

As the cathode current collector <NUM>, for example, a plate, foil, or the like made of indium (In), copper (Cu), magnesium (Mg), stainless steel, titanium (Ti), iron (Fe), cobalt (Co), nickel (Ni), zinc (Zn), aluminum (Al), germanium (Ge), lithium (Li), or an alloy thereof. The cathode current collector <NUM> may be omitted. The thickness of the cathode current collector <NUM> is, for example, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, or about <NUM> to about <NUM>.

As shown in <FIG>, the first electrolyte layer <NUM> and the second electrolyte layer <NUM>' are disposed on the first cathode active material layer <NUM> and the second cathode active material layer <NUM>', respectively. The first electrolyte layer <NUM> and the second electrolyte layer <NUM>' may be solid electrolyte layers.

The solid electrolyte may be, for example, a sulfide-based solid electrolyte. The sulfide-based solid electrolyte is, for example, at least one selected from P<NUM>S<NUM>, Li<NUM>S-P<NUM>S<NUM>-LiX (where X is a halogen element), Li<NUM>S-P<NUM>S<NUM>-Li<NUM>O, Li<NUM>S-P<NUM>S<NUM>-Li<NUM>O-Lil, Li<NUM>S-SiS<NUM>, Li<NUM>S-SiS<NUM>-Lil, Li<NUM>S-SiS<NUM>-LiBr, Li<NUM>S-SiS<NUM>-LiCl, Li<NUM>S-SiS<NUM>-B<NUM>S<NUM>-LiI, Li<NUM>S-SiS<NUM>-P<NUM>S<NUM>-LiI, Li<NUM>S-B<NUM>S<NUM>, Li<NUM>S-P<NUM>S<NUM>-ZmSn (where m and n are each a positive number, and Z is one selected from Ge, Zn and Ga), Li<NUM>S-GeS<NUM>, Li<NUM>S-SiS<NUM>-Li<NUM>PO<NUM>, Li<NUM>S-SiS<NUM>-LipMOq (where p and q are each a positive number, and M is one selected from P, Si, Ge, B, Al, Ga, and In), Li<NUM>-xPS<NUM>-xClx (<NUM>≤x≤<NUM>), Li<NUM>-xPS<NUM>-xBrx (<NUM>≤x≤<NUM>), and Li<NUM>-xPS<NUM>-xIx (<NUM>≤x≤<NUM>). The sulfide-based solid electrolyte is prepared by treating a starting material such as Li<NUM>S or P<NUM>S<NUM> by a melt quenching method or a mechanical milling method. After this treatment, heat treatment may be performed. The solid electrolyte may be amorphous, crystalline, or a mixed state thereof. The solid electrolyte may include sulfur (S), phosphorus (P), and lithium (Li) as at least constituent elements among the above-described sulfide-based solid electrolyte materials. For example, the solid electrolyte may be a material including Li<NUM>S-P<NUM>S<NUM>. When a solid electrolyte including Li<NUM>S-P<NUM>S<NUM> as a material of the sulfide-based solid electrolyte forming the solid electrolyte, the mixing molar ratio of Li<NUM>S and P<NUM>S<NUM> is, for example, in the range of about Li<NUM>S: P<NUM>S<NUM>=<NUM>:<NUM> to <NUM>:<NUM>.

The sulfide-based solid electrolyte may include, for example, an argyrodite-type solid electrolyte represented by the following Formula <NUM>:.

<Formula <NUM>>     Li+<NUM>-n-xAn+X<NUM>-<NUM>-xY-x.

In Formula <NUM>, A is P, As, Ge, Ga, Sb, Si, Sn, Al, In, Ti, V, Nb or Ta, X is S, Se or Te, Y is Cl, Br, I, F, CN, OCN, SCN, or N<NUM>, and <NUM>≤n≤<NUM> and <NUM>≤x≤<NUM> are satisfied. The sulfide-based solid electrolyte may be an argyrodite-type compound including at least one selected from Li<NUM>-xPS<NUM>-xClx (<NUM>≤x≤<NUM>), Li<NUM>-xPS<NUM>-xBrx (<NUM>≤x≤<NUM>), and Li<NUM>-xPS<NUM>-xIx (<NUM>≤x≤<NUM>). The sulfide-based solid electrolyte may be, for example, an argyrodite-type compound including at least one selected from Li<NUM>PS<NUM>Cl, Li<NUM>PS<NUM>Br, and Li<NUM>PS<NUM>I.

The density of the argyrodite-type solid electrolyte may be about <NUM>/cc to about <NUM>/cc. Since the argyrodite-type solid electrolyte has a density of <NUM>/cc or more, the internal resistance of the all-solid secondary battery may be reduced, and the penetration of the solid electrolyte by Li may be effectively suppressed.

The solid electrolyte layer may include, for example, a binder. Examples of the binder included in the solid electrolyte layer may include, but are not limited to, styrene butadiene rubber (SBR), polytetrafluoroethylene, polyvinylidene fluoride, and polyethylene. Any binder may be used as long as it is used in the art. The binder included in the solid electrolyte layer may be the same as or different from the binder included in the first and second cathode active material layers <NUM> and <NUM>' and the first and second anode active material layers <NUM> and <NUM>'. The binder may be omitted.

The content of the binder included in the solid electrolyte layer is about <NUM> wt% to about <NUM> wt%, about <NUM> wt% to about <NUM> wt%, about <NUM> wt% to about <NUM> wt%, about <NUM> wt% to about <NUM> wt%, about <NUM> wt% to about <NUM> wt%, or about <NUM> wt% to about <NUM> wt% with respect to the total weight of the solid electrolyte layer.

As shown in <FIG>, the first anode active material layer <NUM> and the second anode active material layer <NUM>' are disposed on the first electrolyte layer <NUM> and the second electrolyte layer <NUM>', respectively.

The first and second anode active material layer <NUM> and <NUM>' include, for example, an anode active material and a binder.

The anode active material included in the first and second anode active material layer <NUM> and <NUM>' has, for example, a particle shape. The average particle diameter of the anode active material having a particle shape is, for example, <NUM> or less, <NUM> or less, <NUM> or less, <NUM> or less, or <NUM> or less. The average particle diameter of the anode active material having a particle shape is, for example, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, or about <NUM> to about <NUM>. Since the anode active material has an average particle diameter in this range, reversible absorbing and/or desorbing of lithium may be easier during charging and discharging. The average particle diameter of the anode active material is, for example, a median diameter (D50) measured using a laser particle size distribution meter.

The anode active material included in the first and second anode active material layer <NUM> and <NUM>' includes, for example, at least one selected from a carbon-based anode active material and a metal or metalloid anode active material.

In particular, the carbon-based anode active material is amorphous carbon. Examples of amorphous carbon may include, but are not limited to, carbon black (CB), acetylene black (AB), furnace black (FB), Ketjen black (KB), and graphene. Any material may be used as long as it is classified into amorphous carbon in the art. Amorphous carbon is carbon that does not have crystallinity or has very low crystallinity, and is distinguished from crystalline carbon or graphite-based carbon.

The metal or metalloid anode active material includes at least one selected from gold (Au), platinum (Pt), palladium (Pd), silicon (Si), silver (Ag), aluminum (Al), bismuth (Bi), tin (Sn), and zinc (Zn), but the present disclosure is not limited thereto. All are possible as long as it is used as a metal anode active material or a metal or metalloid anode active material that forms an alloy or compound with lithium in the art. For example, since nickel (Ni) does not form an alloy with lithium, it is not a metal anode active material.

The anode active material included in the first and second anode active material layer <NUM> and <NUM>' include a kind of anode active material among these anode active materials, or a mixture of a plurality of different anode active materials. For example, the anode active material included in the first and second anode active material layer <NUM> and <NUM>' includes only amorphous carbon, or includes at least one selected from gold (Au), platinum (Pt), palladium (Pd), silicon (Si), silver (Ag), aluminum (Al), bismuth (Bi), tin (Sn), and zinc (Zn). Alternatively, the anode active material included in the first and second anode active material layer <NUM> and <NUM>' include a mixture of amorphous carbon and at least one selected from gold (Au), platinum (Pt), palladium (Pd), silicon (Si), silver (Ag), aluminum (Al), bismuth (Bi), tin (Sn), and zinc (Zn). The mixing ratio of the mixture of amorphous carbon and gold or the like is, for example, about <NUM>:<NUM> to about <NUM>:<NUM>, about <NUM>:<NUM> to about <NUM>:<NUM>, or about <NUM>:<NUM> to about <NUM>:<NUM> as a weight ratio, but is not necessarily limited to this range, and is selected according to the characteristics of the solid secondary battery <NUM>. Since the anode active material has such a composition, cycle characteristics of the all-solid secondary battery <NUM> are further improved.

The anode active material included in the first and second anode active material layer <NUM> and <NUM>' includes, for example, a mixture of first particles made of amorphous carbon and second particles made of metal or metalloid. Examples of the metal or metalloid includes gold (Au), platinum (Pt), palladium (Pd), silicon (Si), silver (Ag), aluminum (Al), bismuth (Bi), tin (Sn), and zinc (Zn). Alternatively, the metalloid is semiconductor. The content of the second particles is about <NUM> wt% to about <NUM> wt%, about <NUM> wt% to about <NUM> wt%, about <NUM> wt% to about <NUM> wt%, or about <NUM> wt% to about <NUM> wt% based on the total weight of the mixture. When the second particle has a content within this range, for example, the cycle characteristics of the all-solid-state secondary battery <NUM> are further improved.

Examples of the binder included in the first and second anode active material layer <NUM> and <NUM>' may include, but are not limited to, styrene-butadiene rubber (SBR), polytetrafluoroethylene, polyvinylidene fluoride, polyethylene, vinylidene fluoride/hexafluoropropylene copolymers, polyacrylonitrile, and polymethyl methacrylate. Any binder may be used as long as it is used in the art. The binder may be a single binder or a plurality of different binders.

Since the first and second anode active material layer <NUM> and <NUM>' include a binder, the first and second anode active material layers <NUM> and <NUM>' are stabilized on the first and second anode current collectors <NUM> and <NUM>', respectively. Further, cracking of the first and second anode active material layer <NUM> and <NUM>' is suppressed despite a volume change and/or relative position change of the first and second anode active material layer <NUM> and <NUM>' in the charging-discharging process. For example, when the first and second anode active material layer <NUM> and <NUM>' do not include a binder, it is possible for the first and second anode active material layer <NUM> and <NUM>' to be easily separated from the first and second anode current collector <NUM> and <NUM>'. When the first and second anode active material layer <NUM> and <NUM>' are separated from the first and second anode current collector <NUM> and <NUM>', the first and second anode current collector <NUM> and <NUM>' comes into contact with the solid electrolyte layers <NUM> and <NUM>' at the exposed portions of the first and second anode current collector <NUM> and <NUM>', thereby increasing the possibility of a short circuit. The first and second anode active material layer <NUM> and <NUM>' are prepared by applying slurries, in which materials constituting the first and second anode active material layer <NUM> and <NUM>' are dispersed, on the first and second anode current collector <NUM> and <NUM>' and drying the slurries, respectively. Since the binder is included in the first and second anode active material layer <NUM> and <NUM>', it is possible to stably disperse the anode active material in the slurries. For example, when the slurries are respectively applied on the first and second anode current collector <NUM> and <NUM>' by a screen printing method, it is possible to suppress the clogging of a screen (for example, clogging by aggregates of the anode active material).

The first and second anode active material layers <NUM> and <NUM>' may further include additives used in conventional all-solid secondary batteries, for example, a filler, a coating agent, a dispersing agent, and an ion conductive auxiliary agent.

The thickness of each of the first and second anode active material layers <NUM> and <NUM>' is, for example, <NUM>% or less, <NUM>% or less, <NUM>% or less, <NUM>% or less, <NUM>% or less, or <NUM>% or less of the thickness of each of the first and second cathode active material layers <NUM> and <NUM>'. The thickness of each of the first and second anode active material layers <NUM> and <NUM>' is, for example, about <NUM> to about <NUM>, about <NUM> to about <NUM>, or about <NUM> to about <NUM>. When each of the first and second anode active material layers <NUM> and <NUM>' is too thin, lithium dendrites formed between each of the first and second anode active material layer <NUM> and <NUM>' and each of the first and second anode current collectors <NUM> and <NUM>' collapse the first and second anode active material layers <NUM> and <NUM>', so that it is difficult to improve the cycle characteristics of the all-solid secondary battery <NUM>. When the thickness of each of the first and second anode active material layers <NUM> and <NUM>' excessively increases, the energy density of the all-solid secondary battery <NUM> decreases, and the internal resistance of the all-solid secondary battery <NUM> by the first and second anode active material layers <NUM> and <NUM>' increases, so that it is difficult to improve the cycle characteristics of the all-solid secondary battery <NUM>.

When the thickness of each of the first and second anode active material layers <NUM> and <NUM>' decreases, for example, the charging capacity of the each of the first and second anode active material layers <NUM> and <NUM>' also decreases. The charging capacity of each of the first and second anode active material layers <NUM> and <NUM>' is, for example, <NUM>% or less, <NUM>% or less, <NUM>% or less, <NUM>% or less, <NUM>% or less, <NUM>% or less, or <NUM>% or less of the charging capacity of each of the cathode active material layers <NUM> and <NUM>'. The charging capacity of each of the first and second anode active material layers <NUM> and <NUM>' is, for example, about <NUM>% to about <NUM>%, about <NUM>% to about <NUM>%, about <NUM>% to about <NUM>%, about <NUM>% to about <NUM>%, about <NUM>% to about <NUM>%, about <NUM>% to about <NUM>%, or about <NUM>% to about <NUM>% of the charging capacity of each of the cathode active material layers <NUM> and <NUM>'. When the charging capacity of each of the first and second anode active material layers <NUM> and <NUM>' is too small, each of the first and second anode active material layers <NUM> and <NUM>' becomes very thin. Therefore, lithium dendrites formed between each of the first and second anode active material layers <NUM> and <NUM>' and each of the first and second anode current collectors <NUM> and <NUM>' during repeated charging and discharging processes collapse the first and second anode active material layers <NUM> and <NUM>', so that it is difficult to improve the cycle characteristics of the all-solid secondary battery <NUM>. When the charging capacity of each of the first and second anode active material layers <NUM> and <NUM>' excessively increases, the energy density of the all-solid secondary battery <NUM> decreases, and the internal resistance of the all-solid secondary battery <NUM> by the first and second anode active material layers <NUM> and <NUM>' increases, so that it is difficult to improve the cycle characteristics of the all-solid secondary battery <NUM>.

The charging capacity of each of the first and second cathode active material layers <NUM> and <NUM>' is obtained by multiplying the charging capacity density (mAh/g) of the cathode active material by the mass of the cathode active material in each of the first and second cathode active material layers <NUM> and <NUM>'. When several types of cathode active materials are used, the values of charge capacity density x mass are calculated for respective cathode active materials, and the sum of these values is the charging capacity of each of the first and second cathode active material layers <NUM> and <NUM>'. The charging capacity of each of the first and second anode active material layers <NUM> and <NUM>' is calculated in the same way. That is, the charging capacity of each of the first and second anode active material layers <NUM> and <NUM>' is obtained by multiplying the charging capacity density (mAh/g) of the anode active material by the mass of the anode active material in each of the first and second anode active material layers <NUM> and <NUM>'. When several types of anode active materials are used, the values of charge capacity density x mass are calculated for respective anode active materials, and the sum of these values is the charging capacity of each of the first and second anode active material layers <NUM> and <NUM>'. Here, the charge capacity densities of the cathode active material and the anode active material are estimated using an all-solid half-cell using lithium metal as a counter electrode. The charging capacities of the first and second cathode active material layers <NUM> and <NUM>' and the first and second anode active material layers <NUM> and <NUM>' are directly measured by the measurement of the charging capacity using the all-solid half-cell. When the measured charge capacity is divided by the mass of each active material, the charging capacity density is obtained. Alternatively, the charging capacities of the first and second cathode active material layers <NUM> and <NUM>' and the first and second anode active material layers <NUM> and <NUM>' may be initial charging capacities measured during the first charging cycle.

Although not shown in the drawings, the bipolar stack unit cell structure <NUM> may further include a fourth anode active material layer disposed i) between the first anode current collector <NUM> and the first anode active material layer <NUM>, ii) between the first anode active material layer <NUM> and the first electrolyte layer <NUM>, iii) between the second electrolyte layer <NUM>' and the second anode active material layer <NUM>', and/or iv) between the second anode active material layer <NUM>' and the second anode current collector <NUM>'. The fourth anode active material layer is a metal layer including lithium or a lithium alloy. The metal layer includes lithium or a lithium alloy. Accordingly, since the fourth anode active material layer is a metal layer including lithium, it functions as, for example, a lithium reservoir. Examples of the lithium alloy may include, but are not limited to, a Li-Al alloy, a Li-Sn alloy, a Li-In alloy, a Li-Ag alloy, a Li-Au alloy, a Li-Zn alloy, a Li-Ge alloy, and a Li-Si alloy. Any lithium alloy may be used as it is used in the art. The fourth anode active material layer may be made of one of these alloys or lithium, or may be made of several kinds of alloys.

The thickness of the fourth anode active material layer is not particularly limited, but is, for example, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, or about <NUM> to about <NUM>. When the thickness of the fourth anode active material layer is too thin, it is difficult for the second anode active material layer to serve as a lithium reservoir. When the fourth anode active material layer is too thick, the mass and volume of the bipolar stack unit cell structure <NUM> may increase, and the cycle characteristics thereof may be rather deteriorated. The fourth anode active material layer may be, for example, a metal foil having a thickness within this range.

In the bipolar stack unit cell structure <NUM>, the fourth anode active material layer is disposed between each of the first and second current collectors <NUM> and <NUM>' and each of the first and second anode active material layers <NUM> and <NUM>' before assembly of the all-solid secondary battery <NUM> or is deposited between each of the first and second current collectors <NUM> and <NUM>' and each of the first and second anode active material layers <NUM> and <NUM> by charging after assembly of the all-solid secondary battery <NUM>. When the fourth anode active material layer is disposed between each of the first and second current collectors <NUM> and <NUM>' and each of the first and second anode active material layers <NUM> and <NUM>' before assembly of the all-solid secondary battery <NUM>, since the fourth anode active material layer is a metal layer including lithium, it functions as a lithium reservoir. For example, a lithium foil is disposed between each of the first and second current collectors <NUM> and <NUM>' and each of the first and second anode active material layers <NUM> and <NUM>' before assembly of the all-solid secondary battery <NUM>. Thus, the cycle characteristics of the all-solid secondary battery <NUM> including the fourth anode active material layer are further improved. When the fourth anode active material layer is deposited by charging after assembly of the all-solid secondary battery <NUM>, the third anode active material layer is not included during assembly of the all-solid secondary battery <NUM>, so that the energy density of the all-solid secondary battery <NUM> increases. For example, when charging the all-solid secondary battery <NUM>, the all-solid secondary battery <NUM> is charged to exceed the charging capacity of each of the first and second current collectors <NUM> and <NUM>'. That is, the first and second current collectors <NUM> and <NUM>' are overcharged. At the initial stage of charging, lithium is absorbed in the first and second current collectors <NUM> and <NUM>'. The anode active material included in the first and second current collectors <NUM> and <NUM>' forms an alloy or compound with lithium ions that have migrated from the first and second cathode active material layers <NUM> and <NUM>'. When the all-solid secondary battery <NUM> is charged to exceed the charging capacity of each of the first and second anode active material layers <NUM> and <NUM>', for example, lithium is deposited on the rear surface of each of the first and second anode active material layers <NUM> and <NUM>', that is, between each of the first and second current collectors <NUM> and <NUM>' and each of the first and second anode active material layers <NUM> and <NUM>', and a metal layer corresponding to the fourth anode active material layer is formed by the deposited lithium. The fourth anode active material layer is a metal layer mainly including lithium (that is, metal lithium). Such a result is obtained, for example, when the anode active material included in the first and second anode active material layers <NUM> and <NUM>' is composed of a material that forms an alloy or compound with lithium. During discharging, lithium in the first and second anode active material layers <NUM> and <NUM>' and the fourth anode active material layer, that is, the metal layer is ionized and moves toward the first and second cathode active material layers <NUM> and <NUM>'. Accordingly, it is possible to use lithium as an anode active material in the all-solid secondary battery <NUM>. Further, since the first and second anode active material layers <NUM> and <NUM>' cover the fourth anode active material layer, they serve as a protective layer for the fourth anode active material layer, that is, the metal layer, and serve to suppress the deposition growth of lithium dendrites. Therefore, the short circuit and capacity reduction of the all-solid secondary battery <NUM> are suppressed, and as a result, the cycle characteristics of the all-solid secondary battery <NUM> are improved. Further, when the fourth anode active material layer is disposed by charging after assembly of the all-solid secondary battery <NUM>, the first and second current collectors <NUM> and <NUM>' and the first and second anode active material layers <NUM> and <NUM>' and the regions therebetween are, for example, Li-free regions that do not include lithium (Li) in the initial state or post-discharge state of the all-solid secondary battery.

The first and second anode current collectors <NUM> and <NUM>' are made of, for example, a material that does not react with lithium, that is, does not form both an alloy and a compound. Examples of the material constituting the first and second anode current collectors <NUM> and <NUM>' may include, but are not limited to, stainless steel, aluminum (Al), copper (Cu), titanium (Ti), iron (Fe), cobalt (Co), and nickel (Ni). Any material may be used as long as it is used to constitute an electrode current collector in the art. The first and second anode current collectors <NUM> and <NUM>' may be made of one of the above-described metals or an alloy of two or more metals, or may be made of a coating material. The first and second anode current collectors <NUM> and <NUM>' are made in the form of a plate or foil.

The bipolar stack unit cell structure <NUM> may further include, for example, a thin film containing an element capable of forming an alloy with lithium on the first and second anode current collectors <NUM> and <NUM>'. The thin film is disposed between the first and second anode current collectors <NUM> and <NUM>' and the first and second anode active material layers <NUM> and <NUM>'. The thin film contains, for example, an element capable of forming an alloy with lithium. Examples of the element capable of forming an alloy with lithium may include, but are not limited to, gold, silver, zinc, tin, indium, silicon, aluminum, and bismuth. Any element may be used as long as it forms an alloy with lithium in the art. The thin film is formed of one of these metals or is formed of an alloy of several types of metals. As the thin film is disposed between the first and second anode current collectors <NUM> and <NUM>', for example, the deposition form of the third anode active material layer deposited between the thin film <NUM> and the first and second anode active material layers <NUM> and <NUM>' may be further flattened, and the cycle characteristics of the all-solid secondary battery <NUM> may be further improved.

The thickness of the thin film is, for example, about <NUM> to about <NUM>, about <NUM> to about <NUM>, about <NUM> to about <NUM>, or about <NUM> to about <NUM>. When the thickness of the thin film is less than <NUM>, it may be difficult to exert a function as the thin film. When the thickness of the thin film is too thick, the thin film itself absorbs lithium to decrease the amount of lithium deposited in an anode decreases, so that the energy density of the all-solid secondary battery <NUM> decreases, and the cycle characteristics of the all-solid secondary battery <NUM> may be deteriorated. The thin film may be disposed on first and second anode current collectors <NUM> and <NUM>' by, for example, a vacuum deposition method, a sputtering method, a plating method, or the like, but the present disclosure is not necessarily limited to these methods. Any method capable of forming the thin film in the art may be used.

<FIG> is a schematic cross-sectional view of an all-solid secondary battery according to an embodiment.

As shown in <FIG>, the all-solid secondary battery <NUM> includes the bipolar stack unit cell structure <NUM>, and has a structure in which a plurality of the bipolar stack unit cell structures <NUM> are stacked and connected in a bipolar manner. Bipolar plates <NUM> and <NUM>' may be disposed between the bipolar stack unit cell structures <NUM>. In the all-solid secondary battery <NUM>, a desired voltage design may be performed by connecting the bipolar stack unit cell structures <NUM> in a bipolar manner, and a change in volume of the entire cell may be suppressed by the introduction of the compression pad <NUM>.

The stacked bipolar stack unit cell <NUM> may further include a cathode terminal <NUM> and an anode terminal <NUM>, and the compression pad <NUM> of the bipolar stack unit cell structure <NUM> may be in direct contact with the cathode terminal <NUM> and the anode terminal <NUM>.

Alternatively, a third cathode active material layer, a third electrolyte layer, a third anode active material layer, a third anode current collector and a compression pad are further disposed sequentially from the cathode terminal <NUM> between the cathode terminal <NUM> and the first anode current collector or the second anode current collector adjacent thereto, so that the third cathode active material layer may be in direct contact with the cathode terminal <NUM>, and the compression pad <NUM> may be in direct contact with the anode terminal <NUM>.

The present creative idea will be described in more detail through the following Examples and Comparative Examples.

A SUS foil having a thickness of <NUM> was prepared as an anode current collector. Further, carbon black (CB) particles having a primary particle diameter of about <NUM> and silver (Ag) particles having an average particle diameter of about <NUM> were prepared as anode active materials.

<NUM> of mixed powder obtained by mixing carbon black (CB) particles and silver (Ag) particles in a weight ratio of <NUM>:<NUM> was put into a container, and <NUM> of an NMP solution including <NUM> wt% of a PVDF binder (#<NUM> of KUREHA CORPORATION) was added thereto to prepare a mixed solution. Subsequently, the mixed solution was stirred while adding NMP by little to this mixed solution to prepare a slurry. The slurry was applied onto a SUS sheet using a bar coater, and dried in air at <NUM> for <NUM> minutes to obtain a laminate. The obtained laminate was dried in vacuum at <NUM> for <NUM> hours. The dried laminate was roll-pressed by a pressure of <NUM> MPa for <NUM> to flatten the surface of an anode active material layer of the laminate. An anode layer was manufactured by the above processes. The thickness of the anode active material layer included in the anode layer was about <NUM>.

LiNi<NUM>CO<NUM>Mn<NUM>O<NUM> (NCM) coated with Li<NUM>O-ZrO<NUM> (LZO) was prepared as a cathode active material. The LZO-coated cathode active material was prepared according to the method disclosed in <CIT>. Li<NUM>PS<NUM>Cl (D50=<NUM>, crystalline), which is argyrodite-type crystal, was used as a solid electrolyte. A polytetrafluoroethylene (PTFE) binder (Teflon binder of DuPont Corporation) was prepared as a binder. Carbon nanofibers (CNF) were prepared as a conducting agent. A cathode active material composition in which these materials are mixed with a xylene solvent at a weight ratio of cathode active material: solid electrolyte: conducting agent: binder = <NUM> : <NUM> : <NUM> : <NUM> was molded into a sheet, followed by drying in vacuum at <NUM> for <NUM> hours to manufacture a cathode sheet. Two cathode sheets was pressed and attached to both surfaces of a cathode current collector made of a carbon-coated aluminum foil having a thickness of <NUM> to manufacture a cathode layer. The thickness of the cathode layer was about <NUM>.

Acrylic binder was added to a solid electrolyte Li<NUM>PS<NUM>Cl (D50=<NUM>, crystalline), which is argyrodite-type crystal, in an amount of <NUM> parts by weight based on <NUM> parts by weight of the solid electrolyte to prepare a mixture. Subsequently, the prepared mixture was stirred while adding octyl acetate to this mixture to prepare a slurry. The slurry was applied onto a non-woven fabric using a bar coater, and dried in air at <NUM> for <NUM> minutes to obtain a laminate. The obtained laminate was dried in vacuum at <NUM> for <NUM> hours. A solid electrolyte layer was manufactured by the above processes.

Referring to <FIG>, the solid electrolyte layer was brought into contact with both sides of the cathode layer, the anode layer was placed on the solid electrolyte layer so as to contact the anode active material layer, and pressure was applied to prepare a C-type bicell. Subsequently, a polyurethane-made compression pad (Rogers Corp. PORON microcellular #<NUM>) having a thickness of <NUM> was placed between anode current collectors of the adjacent bicells, the cathode current collector of each bicell was welded to the bipolar plate (<NUM>) located at the outermost portion, and the anode current collector of each bicell was welded to the bipolar plate <NUM> to manufacture a bipolar stack unit cell structure.

Referring to <FIG>, an all-solid secondary battery was manufactured by sequentially stacking the manufactured bipolar stack unit cell structures in an outer case.

A bipolar all-solid second battery was manufactured in the same manner as in Example <NUM>, except that a compression pad was not placed between the anode current collectors of the adjacent bicells in Example <NUM>.

As a cathode layer, a cathode sheet formed on only one surface of the cathode current collector used in Example <NUM> was used, and a cathode layer and a solid electrolyte layer were the same as those in Example <NUM>.

The anode layer, the solid electrolyte layer, and the cathode layer were sequentially arranged to prepare a laminate. The prepared laminate was plate-pressed by a pressure of <NUM> MPa for <NUM> to prepare a unit cell of anode/ solid electrolyte film/ cathode to manufacture a monopolar all-solid secondary battery having no compression pad.

The charge-discharge characteristics of the all-solid secondary batteries manufactured in Example <NUM> and Comparative Examples <NUM> and <NUM> were evaluated by the following charge-discharge test. The charge-discharge test was performed after putting the all-solid secondary battery into a thermostat bath at <NUM>.

First, each of the all-solid secondary batteries of Example <NUM> and Comparative Examples <NUM> and <NUM> was charged with a constant current of <NUM> C until a voltage reached <NUM> V, and was then charged with a constant voltage until a current reached <NUM> C. After the charging was completed, the cell was subjected to a rest of about <NUM> minutes, and then subjected to constant current discharge at a current of <NUM>. 1C until the voltage reached <NUM> V.

<FIG> shows graphs of voltages of the all-solid secondary batteries of Comparative Examples <NUM> and <NUM> according to time. Here, the voltages refer to voltages of the bipolar cell of Comparative Example <NUM> and the monopolar cell of Comparative Example <NUM>, respectively. As shown in <FIG>, it may be found that the bipolar and monopolar all-solid secondary batteries having no compression pad cannot accommodate the volume expansion of the cell during charging, so that there is a high possibility of a short circuit occurring.

In contrast, <FIG> shows a graph of voltage and pressure of the all-solid secondary battery of Example <NUM> according to time. Here, the voltage refers to a voltage of the bipolar cell, and the pressure refers to a force applied to the outer wall during volume expansion of the cell. As shown in <FIG>, it may be found that the bipolar all-solid secondary battery of Example <NUM> in which a compression pad is provided between anode current collectors can be normally charged and discharged without occurrence of a short circuit even when the volume of the cell expands during charging.

An additional charge-discharge test was performed on the all-solid secondary battery of Example <NUM> as follows, and the results thereof are shown in <FIG>.

The all-solid secondary battery of Example <NUM> was charged with a constant current of <NUM> C until a voltage reached <NUM> V, and was then charged with a constant voltage until a current reached <NUM> C. After the charging was completed, the cell was subjected to a rest of about <NUM> minutes, and then subjected to constant current discharge at a current of <NUM> C until the voltage reached <NUM> V. This cycle was repeated <NUM> times, and the voltage and pressure according to time were evaluated.

As shown in <FIG>, it may be found that in the bipolar all-solid secondary battery of Example <NUM> in which a compression pad is provided between anode current collectors, there is no short circuit by repeating the volume expansion and contraction of the battery during the cycle.

In order to evaluate the compression stress of the compression pads used in the all-solid secondary batteries manufactured in Comparative Examples <NUM>, <NUM>, and <NUM> according to the type of installation, the compression stress of the compression pads with respect to compression strain was evaluated through a pellet density measuring instrument (PDMI), and the results thereof are shown in <FIG>.

As shown in <FIG>, the compression pad can be pressed toward the outside by contraction, and the pressing can be controlled within an appropriate pressure range even if there is a change in thickness through the initial thickness setting of the compression pad.

According to an aspect, the bipolar stack unit cell structure absorbs a volume change of an anode and suppresses a volume change of the entire cell to obtain a stable lifetime, and the capacity and voltage thereof can be freely designed by bipolar connection of the unit cells.

Claim 1:
A bipolar stack unit cell structure (<NUM>) comprising:
a bicell (<NUM>) in which a first anode current collector (<NUM>), a first anode active material layer (<NUM>), a first electrolyte layer (<NUM>), a first cathode active material layer (<NUM>), a cathode current collector (<NUM>), a second cathode active material layer (<NUM>'), a second electrolyte layer (<NUM>'), a second anode active material layer (<NUM>'), and a second anode current collector (<NUM>') are sequentially arranged,
wherein the first electrolyte layer (<NUM>) and the second electrolyte layer (<NUM>') include a solid electrolyte,
wherein a plurality of the bicells (<NUM>) are stacked, and a compression pad (<NUM>) is provided between the first anode current collector (<NUM>) and second anode current collector (<NUM>') of adjacent bicells (<NUM>) of the plurality of bicells (<NUM>),
wherein the compression pad (<NUM>) is made of an elastic material including at least one selected from polyurethane, natural rubber, spandex, butyl rubber (isobutylene isoprene rubber, IIR), fluoroelastomer, elastomer, ethylene-propylene rubber (EPR), styrene-butadiene rubber (SBR), chloroprene, elastin, rubber epi Chlorohydrin, nylon, terpene, isoprene rubber, polybutadiene, nitrile rubber, thermoplastic elastomer, silicone rubber, ethylene-propylene-diene rubber (EPDM), ethylene vinyl acetate (EVA), halogenated butyl rubber, neoprene, and copolymers thereof,
wherein the compression pad (<NUM>) is pressed to have a thickness of about <NUM>% to about <NUM>% of an initial thickness thereof before being pressed, and
wherein a thickness of the compression pad (<NUM>) is set in a range of about <NUM>% to about <NUM>% of a thickness of a lithium deposition layer of an anode formed when charging an all-solid secondary battery (<NUM>) comprising the bipolar stack unit cell structure (<NUM>), wherein the thickness of the lithium deposition layer of the anode is determined according to the amount of lithium moving from the cathode to the anode.