JP5532430B2 - Composite porous membrane, method for producing composite porous membrane, and battery separator using the same - Google Patents
Composite porous membrane, method for producing composite porous membrane, and battery separator using the same Download PDFInfo
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- JP5532430B2 JP5532430B2 JP2010209147A JP2010209147A JP5532430B2 JP 5532430 B2 JP5532430 B2 JP 5532430B2 JP 2010209147 A JP2010209147 A JP 2010209147A JP 2010209147 A JP2010209147 A JP 2010209147A JP 5532430 B2 JP5532430 B2 JP 5532430B2
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Description
本発明は、ポリプロピレン樹脂を最表層に含む多孔質膜に対してフッ素系樹脂を含む多孔質膜を積層した複合多孔質膜に関し、特にイオン透過性に優れ、かつ、ポリプロピレン樹脂を含む多孔質膜とフッ素系樹脂膜との密着性に優れる、リチウムイオン電池用セパレーターとして有用な複合多孔質膜に関するものである。 The present invention relates to a composite porous membrane in which a porous membrane containing a fluorine-based resin is laminated on a porous membrane containing a polypropylene resin as the outermost layer, and in particular, a porous membrane excellent in ion permeability and containing a polypropylene resin. The present invention relates to a composite porous membrane useful as a separator for a lithium ion battery, which is excellent in adhesiveness between the resin and the fluorine-based resin membrane.
熱可塑性樹脂製多孔質膜は、物質の分離や選択透過及び隔離のための材料等として広く用いられている。例えば、リチウム二次電池、ニッケル−水素電池、ニッケル−カドミウム電池、ポリマー電池に用いる電池用セパレーターや、電気二重層コンデンサ用セパレーター、逆浸透濾過膜、限外濾過膜、精密濾過膜等の各種フィルター、透湿防水衣料、医療用材料等などで用いられている。特にポリエチレン製多孔質膜やポリプロピレン製多孔質膜は、リチウムイオン二次電池用セパレーターとして好適に使用されているか又は開発が進められているが、その理由は、電気絶縁性に優れる、電解液含浸によりイオン透過性を有する、耐電解液性・耐酸化性に優れるという特徴だけでなく、電池異常昇温時の120〜150℃程度の温度において電流を遮断し過度の昇温を抑制する孔閉塞効果をも備えているためである。しかしながら、何らかの原因で孔閉塞後も昇温が続く場合、膜を構成する融解したポリエチレンやポリプロピレンの粘度低下及び膜の収縮により、ある温度で破膜を生じることがある。また、一定高温下に放置すると、融解したポリエチレンやポリプロピレンの粘度低下及び膜の収縮により、ある時間経過後に破膜を生じる可能性がある。この現象は、ポリエチレンやポリプロピレンに限定された現象ではなく、他の熱可塑性樹脂を用いた場合においても、その多孔質膜を構成する樹脂の融点以上では避けることができない。 A porous membrane made of a thermoplastic resin is widely used as a material for separating, selectively permeating and isolating substances. For example, various filters such as battery separators for lithium secondary batteries, nickel-hydrogen batteries, nickel-cadmium batteries, polymer batteries, separators for electric double layer capacitors, reverse osmosis filtration membranes, ultrafiltration membranes, microfiltration membranes, etc. It is used in breathable and waterproof clothing, medical materials, and the like. In particular, polyethylene porous membranes and polypropylene porous membranes are suitably used or developed as separators for lithium ion secondary batteries, because of their excellent electrical insulation and electrolyte impregnation. Not only has the characteristics of having excellent ion resistance and electrolyte resistance and oxidation resistance, but also has a hole plugging that cuts off the current and suppresses excessive temperature rise at a temperature of about 120 to 150 ° C. during abnormal battery temperature rise. This is because it also has an effect. However, if the temperature continues to rise even after the pores are closed for some reason, a film breakage may occur at a certain temperature due to a decrease in viscosity of the melted polyethylene or polypropylene constituting the film and a contraction of the film. Further, when left at a constant high temperature, there is a possibility that a film breakage may occur after a certain period of time due to a decrease in viscosity of the melted polyethylene or polypropylene and a contraction of the film. This phenomenon is not limited to polyethylene or polypropylene, and even when other thermoplastic resins are used, the phenomenon cannot be avoided beyond the melting point of the resin constituting the porous film.
特にリチウムイオン電池用セパレーターは、電池特性、電池生産性及び電池安全性に深く関わっており、優れた機械的特性、耐熱性、透過性、寸法安定性、孔閉塞特性(シャットダウン特性)、溶融破膜防止特性(メルトダウン防止特性)等が要求される。電気自動車、ハイブリッド自動車用の電池においては、今後、高容量化が期待できるリチウムイオン電池の開発が進められつつある一方で、厳しい機械的強度、耐圧縮性、耐熱性が要求されるため、これまでにポリオレフィン多孔質膜上に耐熱樹脂を積層させるなど、様々な耐熱性向上の検討がなされている。耐熱性樹脂として、耐熱性、耐酸化性を併せ持つフッ素系樹脂が好適に用いられている。しかしながら、一般にポリオレフィン多孔質膜上に耐熱樹脂を積層させた場合、複合多孔質膜の加工中やスリット工程、あるいは電池組み立て工程において耐熱性樹脂層が剥離することがあり、こうした場合、安全性の確保が困難となる。 In particular, lithium-ion battery separators are deeply involved in battery characteristics, battery productivity, and battery safety. Excellent mechanical characteristics, heat resistance, permeability, dimensional stability, pore clogging characteristics (shutdown characteristics), melting damage Film prevention characteristics (meltdown prevention characteristics) are required. As for batteries for electric vehicles and hybrid vehicles, while lithium ion batteries that can be expected to have higher capacities are being developed in the future, severe mechanical strength, compression resistance, and heat resistance are required. Various heat resistance improvement studies have been made, such as laminating a heat-resistant resin on a polyolefin porous membrane. As the heat resistant resin, a fluorine-based resin having both heat resistance and oxidation resistance is suitably used. However, in general, when a heat resistant resin is laminated on a polyolefin porous membrane, the heat resistant resin layer may be peeled off during the processing of the composite porous membrane, in the slitting process, or in the battery assembly process. It becomes difficult to secure.
また、低コスト化に対応するため、電池組み立て工程においては高速化が進むことが予想され、本発明者等は、電池の安全性の確保のみならずこのような高速加工においても耐熱性樹脂層の剥離等のトラブルが少ないことが求められ、そのためには、より一層の高い密着性が必要であると推測している。 In order to reduce costs, the battery assembly process is expected to increase the speed, and the present inventors have not only ensured the safety of the battery but also the heat-resistant resin layer not only in such high-speed processing. It is expected that there are few troubles such as peeling, and for that purpose, it is assumed that higher adhesion is required.
特許文献1では、コロナ放電処理を施したポリプロピレン(PP)微多孔質膜に直接Al(OH)3を含む芳香族ポリアミド(ポリ(フェニレンテレフタルアミド))を塗布して得たセパレーターを例示している。特許文献2では、ポリオレフィン多孔質膜に直接、膜厚が1μmとなるようにポリアミドイミド樹脂を塗布し、25℃の水中に浸漬した後、乾燥して得たリチウムイオン二次電池用セパレーターを例示している。 Patent Document 1 exemplifies a separator obtained by directly applying an aromatic polyamide (poly (phenylene terephthalamide)) containing Al (OH) 3 to a polypropylene (PP) microporous film subjected to corona discharge treatment. Yes. Patent Document 2 exemplifies a separator for a lithium ion secondary battery obtained by directly applying a polyamideimide resin to a polyolefin porous film so that the film thickness becomes 1 μm, immersing it in water at 25 ° C., and drying it. doing.
特許文献1および特許文献2の場合のように、塗布液をポリオレフィン多孔質膜に直接塗布した際に一般に用いられるロールコート法、ダイコート法、バーコート法、ブレードコート法等では、その剪断力によって、ポリオレフィン系多孔質膜への樹脂成分の浸透が避けられず、透気抵抗度の大幅な上昇と孔閉塞機能の低下が避けられず、簡単に樹脂成分が多孔質内部を埋めてしまうため透気抵抗度の極端な上昇を招く。また、このような方法では、ポリオレフィン系多孔質膜の膜厚斑が耐熱性樹脂層の膜厚斑に結びつきやすく、透気抵抗度のバラツキに繋がりやすいと言う問題も抱えている。 As in the case of Patent Document 1 and Patent Document 2, the roll coating method, die coating method, bar coating method, blade coating method, etc. that are generally used when the coating solution is directly applied to the polyolefin porous membrane, Infiltration of the resin component into the polyolefin-based porous membrane is unavoidable, and a significant increase in the air permeability resistance and a decrease in the pore blocking function are unavoidable, and the resin component easily fills the porous interior. This leads to an extreme increase in resistance. In addition, such a method also has a problem that the film thickness unevenness of the polyolefin-based porous film is likely to be related to the film thickness unevenness of the heat resistant resin layer, and the air resistance is likely to vary.
特許文献3では、耐熱性樹脂であるフッ化ビニリデン系共重合体を含むドープにアラミド繊維からなる不織布を浸漬し、乾燥して得た電解液担持ポリマー膜が例示されている。 Patent Document 3 exemplifies an electrolyte-supported polymer film obtained by immersing a nonwoven fabric made of aramid fibers in a dope containing a vinylidene fluoride copolymer that is a heat-resistant resin and drying it.
特許文献4では、耐熱性樹脂であるポリフッ化ビニリデンを主成分とするドープにポリプロピレン多孔質膜を浸漬し、凝固、水洗、乾燥工程を経由して得た複合多孔質膜が例示されている。 Patent Document 4 exemplifies a composite porous film obtained by immersing a polypropylene porous film in a dope mainly composed of polyvinylidene fluoride, which is a heat-resistant resin, and through a solidification, water washing, and drying process.
特許文献3のように耐熱性樹脂溶液中にアラミド繊維からなる不織布を浸漬させると、不織布の内部および両面に耐熱多孔質層が形成されるため、不織布内部の連通孔を大部分に渡って塞ぐことになり、透気抵抗度の大幅な上昇が避けられないだけでなく、セパレーターの安全性を決定付ける孔閉塞機能が得られない。 When a non-woven fabric made of aramid fibers is immersed in a heat-resistant resin solution as in Patent Document 3, a heat-resistant porous layer is formed on the inside and both surfaces of the non-woven fabric, so that the communication holes inside the non-woven fabric are mostly covered. In other words, a significant increase in the air permeability resistance cannot be avoided, and a hole closing function that determines the safety of the separator cannot be obtained.
特許文献4においてもポリプロピレン多孔質膜の内部および両面に耐熱多孔質層が形成されることに変わりはなく、特許文献3と同様に透気抵抗度の大幅な上昇が避けられず、また、孔閉塞機能が得られ難い。 In Patent Document 4, heat resistant porous layers are still formed inside and on both sides of the polypropylene porous membrane, and a significant increase in air resistance cannot be avoided as in Patent Document 3, and It is difficult to obtain an occlusion function.
特許文献5では、ポリエチレン製多孔質フィルムに直接、耐熱性樹脂であるパラアラミド樹脂溶液を塗布するに際し、透気抵抗度の大幅な上昇を避けるために事前に耐熱性樹脂溶液に使用される極性有機溶媒をポリエチレン製多孔質フィルムに含浸させておき、耐熱性樹脂溶液を塗布後、温度30℃、相対湿度65%に設定した恒温恒湿機内で白濁した膜状にし、次いで、洗浄、乾燥して得られたパラアラミドからなる耐熱多孔質層を有するセパレーターが開示されている。 In Patent Document 5, when applying a para-aramid resin solution, which is a heat-resistant resin, directly to a polyethylene porous film, a polar organic used in advance in the heat-resistant resin solution in order to avoid a significant increase in air resistance. After impregnating a porous film made of polyethylene with a solvent, and applying a heat-resistant resin solution, it is formed into a cloudy film in a constant temperature and humidity chamber set at a temperature of 30 ° C. and a relative humidity of 65%, and then washed and dried. A separator having a heat-resistant porous layer made of the obtained para-aramid is disclosed.
特許文献5では、透気抵抗度の大幅な上昇はないが、ポリエチレン製多孔質フィルムと耐熱性樹脂との密着性が極めて小さく、安全性の確保が困難となる。 In Patent Document 5, there is no significant increase in the air resistance, but the adhesion between the polyethylene porous film and the heat-resistant resin is extremely small, making it difficult to ensure safety.
特許文献6では、ポリエチレンフィルムにポリアミドイミド樹脂溶液を塗布し、25℃ 80%RH雰囲気中を30秒かけて通過させて、半ゲル状の多孔質膜を得、次いで厚さ20μmまたは10μmのポリエチレン多孔質フィルムを前記半ゲル状多孔質膜の上に重ね、N−メチル−2−ピロリドン(NMP)を含む水溶液に浸漬後、水洗、乾燥させて得られた複合多孔質膜を開示している。 In Patent Document 6, a polyamide-imide resin solution is applied to a polyethylene film and passed through an atmosphere of 25 ° C. and 80% RH over 30 seconds to obtain a semi-gel porous film, and then a polyethylene having a thickness of 20 μm or 10 μm. A composite porous membrane obtained by laminating a porous film on the semi-gel porous membrane, immersing it in an aqueous solution containing N-methyl-2-pyrrolidone (NMP), washing with water and drying is disclosed. .
特許文献6では、透気抵抗度の大幅な上昇はないが、ポリエチレン製多孔質フィルムと耐熱性樹脂との密着性が不十分であり、また、ポリエチレン製多孔質フィルムは、ポリプロピレン樹脂多孔質膜より柔らかく、機械的強度、耐圧縮性に劣るものであった。 In Patent Document 6, there is no significant increase in air permeability resistance, but the adhesion between the polyethylene porous film and the heat-resistant resin is insufficient, and the polyethylene porous film is a polypropylene resin porous film. It was softer and inferior in mechanical strength and compression resistance.
このように、基材となるポリオレフィン系等の多孔質膜に耐熱性樹脂層を積層した複合多孔質膜において、耐熱性樹脂を基材となる多孔質膜に浸透させて耐熱性樹脂層の密着性の向上を図れば、透気抵抗度上昇幅が大きくなり、耐熱性樹脂の浸透を小さくすれば、透気抵抗度上昇幅は小さく抑えることができるが、耐熱性樹脂層の密着性が小さくなり、電池組み立て工程での高速化を踏まえた場合、ますます要求が厳しくなる安全性の確保が難しくなる。特に延伸開孔法により得られたポリプロピレン系樹脂多孔質膜を多孔質膜基材とした場合、一般に耐熱樹脂層との密着が極めて得難く、耐熱性樹脂層の密着性と透気抵抗度上昇幅が両立した複合多孔質膜はなかった。 Thus, in a composite porous membrane in which a heat-resistant resin layer is laminated on a polyolefin-based porous membrane as a base material, the heat-resistant resin is infiltrated into the porous membrane as a base material and the heat-resistant resin layer is closely attached If the improvement is made, the increase in the air resistance increases, and if the permeation of the heat resistant resin is reduced, the increase in the air resistance can be suppressed, but the adhesion of the heat resistant resin layer is small. Therefore, in view of speeding up in the battery assembly process, it becomes difficult to ensure safety, which is becoming increasingly demanding. In particular, when a polypropylene resin porous membrane obtained by the stretch-opening method is used as a porous membrane substrate, generally it is very difficult to obtain close contact with the heat resistant resin layer, and the adhesion of the heat resistant resin layer and the air resistance increase. There were no composite porous membranes with compatible widths.
本発明は、ポリプロピレン樹脂層を最表層に有する多孔質膜に耐熱性樹脂層を含む多孔質膜を積層した複合多孔質膜において、優れた耐熱性樹脂層の密着性と小さい透気抵抗度上昇幅が両立したものを提供するものであり、特に電池用セパレーターに好適な複合多孔質膜の提供を目指したものである。 The present invention provides a composite porous membrane in which a porous membrane including a heat-resistant resin layer is laminated on a porous membrane having a polypropylene resin layer as the outermost layer, and has excellent adhesion to a heat-resistant resin layer and a small increase in air resistance. The present invention aims to provide a composite porous membrane that is suitable for battery separators.
本発明は、以下の(1)〜(8)の構成を有するものである。
(1)三層からなり最表層の少なくとも一方がポリプロピレン樹脂からなる多孔質膜Aの最表層のポリプロピレン樹脂の表面に対して、フッ素系樹脂を含む多孔質膜Bが積層された複合多孔質膜であって、多孔質膜Aが下記式(A)及び(B)を満足するものにおいて、複合多孔質膜が下記式(C)及び(D)を満足し、多孔質膜Aが、ポリプロピレン/ポリエチレン/ポリプロピレンの三層が積層されたものであることを特徴とする複合多孔質膜。
0.01μm≦多孔質膜Aの平均孔径≦1.0μm ・・・・・式(A)
30%≦多孔質膜Aの空孔率≦70% ・・・・・式(B)
多孔質膜Aと多孔質膜Bの界面での剥離強度≧1.0N/25mm・・・・・式(C)
20≦Y−X≦100 ・・・・・式(D)
(Xは多孔質膜Aの透気抵抗度(秒/100ccAir)、Yは複合多孔質膜全体の透気抵抗度(秒/100ccAir)である)
(2)フッ素系樹脂が、対数粘度0.5dl/g以上のフッ素系樹脂であることを特徴とする(1)に記載の複合多孔質膜。
(3)以下の工程(i)〜(iii)を含むことを特徴とする(1)又は(2)に記載の複合多孔質膜の製造方法。
工程(i):基材フィルム上にフッ素系樹脂溶液を塗布した後、絶対湿度6g/m3未満の低湿度ゾーンを通過させ、次いで、絶対湿度6g/m3以上25g/m3以下の高湿度ゾーンを通過させて基材フィルム上にフッ素系樹脂膜を形成する工程、
工程(ii):三層からなりかつ最表層の少なくとも一方がポリプロピレン樹脂からなる多孔質膜Aを用意する工程、および
工程(iii):工程(ii)の多孔質膜Aの最表層のポリプロピレン樹脂の表面に対して工程(i)で形成されたフッ素系樹脂膜を貼り合わせた後、凝固浴に浸漬させてフッ素系樹脂膜を多孔質膜Bに変換させ、洗浄、乾燥し、複合多孔質膜を得る工程。
(4)基材フィルムが、工程(iii)で複合多孔質膜を得た後に剥離されることを特徴とする(3)に記載の複合多孔質膜の製造方法。
(5)基材フィルムが厚さ25〜100μmのポリエステル系フィルム又はポリオレフィン系フィルムであることを特徴とする(3)又は(4)に記載の複合多孔質膜の製造方法。
(6)基材フィルムの表面の線状オリゴマーの量が20μg/m2以上100μg/m2以下であることを特徴とする(3)〜(5)のいずれかに記載の複合多孔質膜の製造方法。
(7)工程(i)において低湿度ゾーンの通過時間が3秒以上20秒以下であり、高湿度ゾーンの通過時間が3秒以上10秒以下であることを特徴とする(3)〜(6)のいずれかに記載の複合多孔質膜の製造方法。
(8)(1)又は(2)に記載の複合多孔質膜を含むことを特徴とする電池用セパレーター。
The present invention has the following configurations (1) to (8).
(1) A composite porous membrane in which a porous membrane B containing a fluororesin is laminated on the surface of the outermost polypropylene resin of the porous membrane A comprising three layers and at least one of the outermost layers made of polypropylene resin In the case where the porous membrane A satisfies the following formulas (A) and (B), the composite porous membrane satisfies the following formulas (C) and (D), and the porous membrane A is polypropylene / A composite porous membrane, wherein three layers of polyethylene / polypropylene are laminated.
0.01 μm ≦ average pore diameter of porous membrane A ≦ 1.0 μm Formula (A)
30% ≦ Porosity of porous membrane A ≦ 70% Formula (B)
Peel strength at the interface between porous membrane A and porous membrane B ≧ 1.0 N / 25 mm Formula (C)
20 ≦ Y−X ≦ 100 Formula (D)
(X is the air permeability resistance of the porous membrane A (second / 100 cc Air), Y is the air resistance of the entire composite porous membrane (second / 100 cc Air))
(2) The composite porous membrane according to (1), wherein the fluororesin is a fluororesin having a logarithmic viscosity of 0.5 dl / g or more.
(3) The method for producing a composite porous membrane according to (1) or (2), comprising the following steps (i) to (iii):
Step (i): After applying the fluororesin solution on the base film, it is passed through a low-humidity zone having an absolute humidity of less than 6 g / m 3 , and then high in an absolute humidity of 6 g / m 3 or more and 25 g / m 3 or less. Forming a fluororesin film on the base film by passing through the humidity zone;
Step (ii): Step of preparing a porous membrane A comprising three layers and at least one of the outermost layers comprising a polypropylene resin, and Step (iii): Polypropylene resin of the outermost layer of the porous membrane A in Step (ii) After the fluororesin film formed in step (i) is bonded to the surface of the film, it is immersed in a coagulation bath to convert the fluororesin film into a porous film B, washed and dried, and composite porous A step of obtaining a film.
(4) The method for producing a composite porous membrane according to (3), wherein the base film is peeled after obtaining the composite porous membrane in step (iii).
(5) The method for producing a composite porous membrane according to (3) or (4), wherein the base film is a polyester film or a polyolefin film having a thickness of 25 to 100 μm.
(6) The amount of the linear oligomer on the surface of the base film is 20 μg / m 2 or more and 100 μg / m 2 or less, wherein the composite porous membrane according to any one of (3) to (5) Production method.
(7) In the step (i), the passage time in the low humidity zone is 3 seconds or more and 20 seconds or less, and the passage time in the high humidity zone is 3 seconds or more and 10 seconds or less (3) to (6) The method for producing a composite porous membrane according to any one of the above.
(8) A battery separator comprising the composite porous membrane according to (1) or (2).
本発明の複合多孔質膜は、優れたシャットダウン機能を有し、かつ機械的強度、耐圧縮性を有するポリプロピレン系樹脂層を最表層に有する多孔質膜を基材とし、さらにフッ素系樹脂層を積層した構成を有し、優れたフッ素系樹脂層の密着性と小さい透気抵抗度上昇幅を両立しているので、特に電池用セパレーターに好適に使用することができる。 The composite porous membrane of the present invention is based on a porous membrane having a polypropylene resin layer having an excellent shutdown function and mechanical strength and compression resistance as an outermost layer, and further comprising a fluorine resin layer. Since it has a laminated structure and has both excellent adhesion of the fluororesin layer and a small increase in air permeability resistance, it can be suitably used particularly for a battery separator.
本発明の複合多孔質膜は、三層からなりかつ最表層の少なくとも一方がポリプロピレン樹脂からなる多孔質膜Aの最表層のポリプロピレン樹脂の表面に対して、フッ素系樹脂を含む多孔質膜Bを積層したものであり、高度な加工技術によって、積層による透気抵抗度の大幅な上昇を招くことなく、優れたフッ素系樹脂層の密着性を達成したものである。 The composite porous membrane of the present invention comprises a porous membrane B containing a fluororesin with respect to the surface of the outermost polypropylene resin of the porous membrane A consisting of three layers and at least one of the outermost layers made of polypropylene resin. It is a laminate, and it has achieved excellent adhesion of the fluororesin layer without causing a significant increase in the air resistance due to the lamination by an advanced processing technique.
ここで透気抵抗度の大幅な上昇とは、基材となる多孔質膜の透気抵抗度(X)と複合多孔質膜の透気抵抗度(Y)の差が100秒/100ccAirを超えることを意味する。また、優れたフッ素系樹脂層の密着性とは剥離強度が1.0N/25mm以上であることを意味し、好ましくは1.5N/25mm以上、さらに好ましくは2.0N/25mm以上である。1.0N/25mm未満では電池組み立て工程での加工時にフッ素系樹脂層が剥離してしまう可能性がある。剥離強度の上限は特にないが、30N/25mmもあれば密着性として十分である。 Here, the significant increase in the air resistance is that the difference between the air resistance (X) of the porous membrane as the base material and the air resistance (Y) of the composite porous membrane exceeds 100 seconds / 100 cc Air. Means that. The excellent adhesion of the fluororesin layer means that the peel strength is 1.0 N / 25 mm or more, preferably 1.5 N / 25 mm or more, more preferably 2.0 N / 25 mm or more. If it is less than 1.0 N / 25 mm, the fluororesin layer may be peeled off during processing in the battery assembly process. There is no particular upper limit to the peel strength, but 30 N / 25 mm is sufficient for adhesion.
まず、本発明で用いる多孔質膜Aについて説明する。
多孔質膜Aは、三層からなりかつ最表層の少なくとも一方がポリプロピレン樹脂からなるものである。このような多孔質膜Aは、一般に延伸開孔法、相分離法などの製造方法によって作製できる。
多孔質膜Aの層構成はポリプロピレン/ポリエチレン/ポリプロピレンであるが、ポリプロピレン層の厚さは片側3μm以上であることが好ましい。3μm未満では十分な機械的強度が得られない場合がある。
First, the porous membrane A used in the present invention will be described.
The porous membrane A is composed of three layers and at least one of the outermost layers is composed of a polypropylene resin. Such a porous membrane A can be generally produced by a production method such as a stretched hole method or a phase separation method.
The layer structure of the porous membrane A is polypropylene / polyethylene / polypropylene, but the thickness of the polypropylene layer is preferably 3 μm or more on one side. If it is less than 3 μm, sufficient mechanical strength may not be obtained.
さらに、多孔質膜A中のポリプロピレン樹脂は、工程作業性および電極との倦回時に生じる様々な外圧に耐える機械強度、例えば、引っ張り強度、弾性率、伸度、突き刺し強度の点から、好ましくは質量平均分子量が30万以上、さらに好ましくは40万以上、最も好ましくは50万以上である。 Further, the polypropylene resin in the porous membrane A is preferably from the viewpoint of process workability and mechanical strength that can withstand various external pressures generated during winding with the electrode, such as tensile strength, elastic modulus, elongation, and piercing strength. The mass average molecular weight is 300,000 or more, more preferably 400,000 or more, and most preferably 500,000 or more.
多孔質膜Aの層構造は、製法によって異なる。上記の各種特性を満足する範囲ならば、製法により目的に応じた相構造を自由に持たせることができる。多孔質膜の製造方法としては、発泡法、相分離法、溶解再結晶法、延伸開孔法、粉末焼結法などがあり、これらのなかでは微細孔の均一化、コストの点で相分離法が好ましい。 The layer structure of the porous membrane A differs depending on the production method. As long as the above various characteristics are satisfied, the phase structure according to the purpose can be freely given by the production method. There are foaming methods, phase separation methods, dissolution recrystallization methods, stretched pore opening methods, powder sintering methods, etc., among these porous membrane production methods, among these, phase separation in terms of uniform micropores and cost The method is preferred.
多孔質膜Aは、充放電反応の異常時に孔が閉塞する機能(孔閉塞機能)を有することが必要である。従って、構成する樹脂の融点(軟化点)は、好ましくは70〜150℃、さらに好ましくは80〜140℃、最も好ましくは100〜130℃である。70℃未満では、正常使用時に孔閉塞機能が発現して電池が使用不可になる可能性があるため実用性に乏しく、150℃を超えると異常反応が十分に進行してから孔閉塞機能が発現してしまうため、安全性を確保できないおそれがある。 The porous film A needs to have a function of closing the pores when the charge / discharge reaction is abnormal (pore closing function). Therefore, the melting point (softening point) of the constituent resin is preferably 70 to 150 ° C, more preferably 80 to 140 ° C, and most preferably 100 to 130 ° C. If the temperature is lower than 70 ° C, the pore blocking function may be exhibited during normal use and the battery may become unusable. Therefore, if the temperature exceeds 150 ° C, the abnormal reaction proceeds sufficiently and the hole blocking function appears. Therefore, safety may not be ensured.
多孔質膜Aの膜厚の上限は40μmであることが好ましく、より好ましくは35μmである。下限は10μmが好ましく、より好ましくは15μmである。10μmよりも薄い場合は、特に電気自動車等の厳しい環境下で用いられる電池では実用的な膜強度と孔閉塞機能を保有させることができないことがあり、40μmよりも厚い場合、電池ケースの単位容積当たりの面積が大きく制約され、今後、進むであろう電池の高容量化には適さない。 The upper limit of the thickness of the porous membrane A is preferably 40 μm, more preferably 35 μm. The lower limit is preferably 10 μm, more preferably 15 μm. If the thickness is less than 10 μm, the battery used in severe environments such as electric vehicles may not have a practical membrane strength and hole blocking function. If the thickness is greater than 40 μm, the unit volume of the battery case The area per contact is greatly restricted, and is not suitable for increasing the capacity of batteries that will be advanced in the future.
多孔質膜Aの透気抵抗度(JIS−P8117)の上限は好ましくは1000秒/100ccAir、さらに好ましくは800秒/100ccAir、最も好ましくは500秒/100ccAirであり、下限は好ましくは50秒/100ccAir、さらに好ましくは70秒/100ccAir、最も好ましくは100秒/100ccAirである。 The upper limit of the air permeability resistance (JIS-P8117) of the porous membrane A is preferably 1000 seconds / 100 cc Air, more preferably 800 seconds / 100 cc Air, most preferably 500 seconds / 100 cc Air, and the lower limit is preferably 50 seconds / 100 cc Air. More preferably, it is 70 seconds / 100 cc Air, and most preferably 100 seconds / 100 cc Air.
多孔質膜Aの空孔率の上限は70%、好ましくは60%、さらに好ましくは55%である。下限は30%、好ましくは35%、さらに好ましくは40%である。透気抵抗度が1000秒/100ccAirより高くても、空孔率が30%よりも低くても、十分な電池の充放電特性、特にイオン透過性(充放電作動電圧)、電池の寿命(電解液の保持量と密接に関係する)において十分ではなく、これらの範囲を超えた場合、電池としての機能を十分に発揮することができなくなる可能性がある。一方で、50秒/100ccAirよりも透気抵抗度が低くても、空孔率が70%よりも高くても、十分な機械的強度と絶縁性が得られず、充放電時に短絡が起こる可能性が高くなる。 The upper limit of the porosity of the porous membrane A is 70%, preferably 60%, more preferably 55%. The lower limit is 30%, preferably 35%, more preferably 40%. Whether the air resistance is higher than 1000 seconds / 100 cc Air or the porosity is lower than 30%, sufficient charge / discharge characteristics of the battery, particularly ion permeability (charge / discharge operating voltage), battery life (electrolysis) (It is closely related to the amount of liquid retained), and if these ranges are exceeded, the battery function may not be fully exhibited. On the other hand, even if the air permeability resistance is lower than 50 seconds / 100 cc Air or the porosity is higher than 70%, sufficient mechanical strength and insulation cannot be obtained, and a short circuit may occur during charging and discharging. Increases nature.
多孔質膜Aの平均孔径は、孔閉塞速度に大きく影響を与えるため、0.01〜1.0μm、好ましくは0.05〜0.5μm、さらに好ましくは0.1〜0.3μmである。0.01μmよりも小さい場合、フッ素系樹脂のアンカー効果が得られにくいため十分なフッ素系樹脂の密着性が得られない場合がある他、複合化の際に透気抵抗度が大幅に悪化する可能性が高くなる。1.0μmよりも大きい場合、孔閉塞現象の温度に対する応答が緩慢になる、昇温速度による孔閉塞温度がより高温側にシフトするなどの現象が生じる可能性がある。なお、多孔質膜Aが二層以上の多層膜(たとえばポリプロピレン/ポリエチレン/ポリプロピレン)の場合、多孔質膜Aの平均孔径は、少なくとも最表層のポリプロピレン樹脂の平均孔径が上記範囲を満たしさえすればよい。 Since the average pore diameter of the porous membrane A greatly affects the pore closing speed, it is 0.01 to 1.0 μm, preferably 0.05 to 0.5 μm, and more preferably 0.1 to 0.3 μm. If it is smaller than 0.01 μm, the anchor effect of the fluororesin is difficult to obtain, and sufficient adhesiveness of the fluororesin may not be obtained. The possibility increases. When it is larger than 1.0 μm, there is a possibility that a phenomenon such as a slow response to the temperature of the hole closing phenomenon or a phenomenon that the hole closing temperature due to the heating rate shifts to a higher temperature side may occur. When the porous film A is a multilayer film having two or more layers (for example, polypropylene / polyethylene / polypropylene), the average pore diameter of the porous film A only needs to satisfy at least the average pore diameter of the outermost layer polypropylene resin. Good.
さらに、多孔質膜Aの表面状態に関しては、表面粗さ(算術的平均粗さ)が0.01〜0.5μmの範囲にあると多孔質膜Bとの密着性がより強くなる傾向にある。表面粗さが0.01μmより低い場合、密着性改善の効果は見られず、0.5μmより高い場合、多孔質膜Aの機械強度低下または多孔質膜Bの表面への凸凹の転写が起こることがある。 Furthermore, regarding the surface state of the porous membrane A, when the surface roughness (arithmetic average roughness) is in the range of 0.01 to 0.5 μm, the adhesion with the porous membrane B tends to be stronger. . When the surface roughness is lower than 0.01 μm, the effect of improving the adhesion is not observed. When the surface roughness is higher than 0.5 μm, the mechanical strength of the porous film A is reduced or the unevenness is transferred to the surface of the porous film B. Sometimes.
次に、本発明で用いる多孔質膜Bについて説明する。
多孔質膜Bは、フッ素系樹脂を含むものであり、その耐熱性により多孔質膜Aを支持・補強する役割を担う。従って、多孔質膜Bを構成するフッ素系樹脂の融点は、好ましくは150℃以上、さらに好ましくは180℃以上、最も好ましくは210℃以上であり、上限は特に限定されない。融点が分解温度よりも高い場合、分解温度が上記範囲内であれば良い。融点が150℃よりも低い場合、十分な耐熱破膜温度が得られず、高い安全性を確保できないおそれがある。
Next, the porous membrane B used in the present invention will be described.
The porous membrane B contains a fluorine-based resin and plays a role of supporting and reinforcing the porous membrane A due to its heat resistance. Therefore, the melting point of the fluororesin constituting the porous membrane B is preferably 150 ° C. or higher, more preferably 180 ° C. or higher, most preferably 210 ° C. or higher, and the upper limit is not particularly limited. When the melting point is higher than the decomposition temperature, the decomposition temperature may be in the above range. When the melting point is lower than 150 ° C., a sufficient heat-resistant film breaking temperature cannot be obtained, and high safety may not be ensured.
以下、多孔質膜Bに使用するフッ素系樹脂について説明する。
フッ素系樹脂は、フッ化ビニリデン単独重合体、フッ化ビニリデン/フッ化オレフィン共重合体、フッ化ビニル単独重合体、及びフッ化ビニル/フッ化オレフィン共重合体からなる群より選ばれる1種以上を使用することが好ましい。特に好ましいものはポリテトラフルオロエチレンである。これらの重合体は、非水電解液とも親和性が高く、しかも耐熱性が適切で、非水電解液に対する化学的、物理的な安定性が高いため、高温下での使用にも電解液との親和性を十分維持できる。
Hereinafter, the fluororesin used for the porous membrane B will be described.
The fluororesin is at least one selected from the group consisting of vinylidene fluoride homopolymers, vinylidene fluoride / fluorinated olefin copolymers, vinyl fluoride homopolymers, and vinyl fluoride / fluorinated olefin copolymers. Is preferably used. Particularly preferred is polytetrafluoroethylene. These polymers have high affinity with non-aqueous electrolytes, are suitable for heat resistance, and have high chemical and physical stability against non-aqueous electrolytes. The affinity of can be maintained sufficiently.
本発明で用いるフッ素系樹脂は、対数粘度は0.5dl/g以上が好ましい。対数粘度が0.5dl/g未満では溶融温度の低下により十分なメルトダウン特性が得られない場合があることと分子量が低いため多孔質膜が脆くなり、アンカー効果が低下するため密着性が低下するためである。一方、対数粘度の上限は加工性や溶剤溶解性を考慮すると、2.0dl/g未満が好ましい。 The fluororesin used in the present invention preferably has a logarithmic viscosity of 0.5 dl / g or more. When the logarithmic viscosity is less than 0.5 dl / g, sufficient meltdown characteristics may not be obtained due to a decrease in melting temperature, and the porous film becomes brittle due to low molecular weight, and the anchor effect is reduced, resulting in reduced adhesion. It is to do. On the other hand, the upper limit of the logarithmic viscosity is preferably less than 2.0 dl / g in consideration of processability and solvent solubility.
多孔質膜Bは、フッ素系樹脂に対して可溶で且つ水と混和する溶剤で溶解したフッ素系樹脂溶液(ワニス)を所定の基材フィルムに塗布し、加湿条件下でフッ素系樹脂と、水と混和する溶剤を相分離させ、さらに水浴(凝固浴)に投入してフッ素系樹脂を凝固させることによって得られる。 The porous membrane B is a fluorine-based resin solution (varnish) which is soluble in a fluorine-based resin and dissolved in a solvent miscible with water, and is applied to a predetermined substrate film, It is obtained by phase-separating a solvent miscible with water and further putting it in a water bath (coagulation bath) to coagulate the fluororesin.
フッ素系樹脂を溶解するために使用できる溶剤としては、N,N−ジメチルアセトアミド(DMAc)、N−メチル−2−ピロリドン(NMP)、リン酸ヘキサメチルトリアミド(HMPA)、N,N−ジメチルホルムアミド(DMF)、ジメチルスルホキシド(DMSO)、γ−ブチロラクトン、クロロホルム、テトラクロロエタン、ジクロロエタン、3−クロロナフタレン、パラクロロフェノール、テトラリン、アセトン、アセトニトリルなどが挙げられ、樹脂の溶解性に応じて自由に選択できる。 Solvents that can be used to dissolve the fluororesin include N, N-dimethylacetamide (DMAc), N-methyl-2-pyrrolidone (NMP), hexamethyltriamide phosphate (HMPA), N, N-dimethyl. Examples include formamide (DMF), dimethyl sulfoxide (DMSO), γ-butyrolactone, chloroform, tetrachloroethane, dichloroethane, 3-chloronaphthalene, parachlorophenol, tetralin, acetone, acetonitrile, etc., depending on the solubility of the resin. You can choose.
ワニスの固形分濃度は、均一に塗布できれば特に制限されないが、2重量%以上、50重量%以下が好ましく、4重量%以上、40重量%以下がさらに好ましい。固形分濃度が2重量%未満では得られた多孔質膜Bが脆くなる場合がある。また、50重量%を超えると多孔質膜Bの厚み制御が困難となる場合がある。 The solid content concentration of the varnish is not particularly limited as long as it can be uniformly applied, but is preferably 2% by weight or more and 50% by weight or less, more preferably 4% by weight or more and 40% by weight or less. When the solid content concentration is less than 2% by weight, the obtained porous membrane B may become brittle. On the other hand, if it exceeds 50% by weight, it may be difficult to control the thickness of the porous membrane B.
また、多孔質層Bの熱収縮率を低減し、滑り性を付与するために、ワニスに無機粒子あるいは耐熱性高分子粒子を添加しても良い。粒子を添加する場合、その添加量の上限としては95質量%が好ましい。添加量が95質量%を超えると多孔質膜Bの総体積に対してフッ素系樹脂の割合が小さくなり、多孔質膜Aに対するフッ素系樹脂の十分な密着性が得られない場合がある。 Moreover, in order to reduce the heat shrinkage rate of the porous layer B and to impart slipperiness, inorganic particles or heat-resistant polymer particles may be added to the varnish. When adding particles, the upper limit of the amount added is preferably 95% by mass. When the addition amount exceeds 95% by mass, the ratio of the fluororesin to the total volume of the porous membrane B becomes small, and sufficient adhesion of the fluororesin to the porous membrane A may not be obtained.
無機粒子としては、炭酸カルシウム、リン酸カルシウム、非晶性シリカ、結晶性のガラスフィラー、カオリン、タルク、二酸化チタン、アルミナ、シリカーアルミナ複合酸化物粒子、硫酸バリウム、フッ化カルシウム、フッ化リチウム、ゼオライト、硫化モリブデン、マイカなどが挙げられる。また、耐熱性高分子粒子としては、架橋ポリスチレン粒子、架橋アクリル系樹脂粒子、架橋メタクリル酸メチル系粒子、ベンゾグアナミン・ホルムアルデヒド縮合物粒子、メラミン・ホルムアルデヒド縮合物粒子、ポリテトラフルオロエチレン粒子などが挙げられる。 Inorganic particles include calcium carbonate, calcium phosphate, amorphous silica, crystalline glass filler, kaolin, talc, titanium dioxide, alumina, silica-alumina composite oxide particles, barium sulfate, calcium fluoride, lithium fluoride, zeolite , Molybdenum sulfide, mica and the like. Examples of the heat resistant polymer particles include crosslinked polystyrene particles, crosslinked acrylic resin particles, crosslinked methyl methacrylate particles, benzoguanamine / formaldehyde condensate particles, melamine / formaldehyde condensate particles, and polytetrafluoroethylene particles. .
ワニスの水分率は0.5重量%以下、好ましくは0.3重量%以下とすることが重要である。0.5重量%を超えるとワニス保管中もしくは塗布直後にフッ素系樹脂成分が凝固しやすくなるため、多孔質膜Aへの必要量のフッ素系樹脂の染みこみができない場合がある。ワニスの水分率を0.5重量%以下にする方法としては、フッ素系樹脂および溶媒、さらには無機粒子等の添加剤の水分率を0.5重量%以下にする方法が挙げられ、具体的には、それぞれの原料を脱水処理、または乾燥処理して用いることが好ましい。また、ワニスは調合から塗工までの間、極力外気に触れさせないように保管することが望ましい。なお、ワニスの水分率はカールフィッシャー法を用いて測定することができる。 It is important that the moisture content of the varnish is 0.5% by weight or less, preferably 0.3% by weight or less. If it exceeds 0.5% by weight, the fluororesin component is likely to coagulate during storage of varnish or immediately after coating, so that the porous film A may not be able to soak the necessary amount of fluororesin. Examples of the method of setting the moisture content of the varnish to 0.5% by weight or less include a method of setting the moisture content of additives such as fluorine resins and solvents, and inorganic particles to 0.5% by weight or less. For this, it is preferable to use each raw material after dehydration or drying. In addition, it is desirable to store the varnish so that it is not exposed to outside air as much as possible from the preparation to the coating. The moisture content of the varnish can be measured using the Karl Fischer method.
また、多孔質膜Bの膜厚は好ましくは1〜5μm、さらに好ましくは1〜4μm、最も好ましくは1〜3μmである。膜厚が1μmよりも薄い場合、多孔質膜Aが融点以上で溶融・収縮した際の破膜強度と絶縁性を確保できないおそれがあり、5μmよりも厚い場合、複合多孔質膜中の多孔質膜Aの占める割合が少なく、十分な孔閉塞機能が得られず、異常反応を抑制できないことがある。また、巻き嵩が大きくなり、今後、進むであろう電池の高容量化には適さないおそれがある。 The film thickness of the porous membrane B is preferably 1 to 5 μm, more preferably 1 to 4 μm, and most preferably 1 to 3 μm. If the film thickness is less than 1 μm, there is a possibility that the membrane breaking strength and insulation properties cannot be secured when the porous film A is melted or shrunk at a melting point or higher, and if it is thicker than 5 μm, the porosity in the composite porous film The ratio occupied by the membrane A is small, a sufficient pore blocking function cannot be obtained, and abnormal reactions may not be suppressed. Moreover, there is a possibility that the volume of winding becomes large and it is not suitable for increasing the capacity of a battery that will be advanced in the future.
多孔質膜Bの空孔率は30〜90%が好ましく、更に好ましくは40〜70%である。空孔率が30%未満では、膜の電気抵抗が高くなり、大電流を流しにくくなる。一方、90%を超えると、膜強度が弱くなる傾向にある。また、多孔質膜Bの透気抵抗度は、JIS−P8117に準拠した方法により測定した値が1〜1000秒/100ccAirであることが好ましい。より好ましくは50〜800秒/100ccAir、さらに好ましくは100〜700秒/100ccAirである。透気抵抗度が1秒/100ccAir未満では膜強度が弱くなり、1000秒/100ccAirを越えるとサイクル特性が悪くなることがある。 The porosity of the porous membrane B is preferably 30 to 90%, more preferably 40 to 70%. If the porosity is less than 30%, the electrical resistance of the film increases and it becomes difficult to pass a large current. On the other hand, if it exceeds 90%, the film strength tends to be weak. Moreover, it is preferable that the value measured by the method based on JIS-P8117 is the air permeability resistance of the porous membrane B is 1-1000 second / 100ccAir. More preferably, it is 50-800 second / 100ccAir, More preferably, it is 100-700 second / 100ccAir. When the air resistance is less than 1 second / 100 cc Air, the film strength becomes weak, and when it exceeds 1000 seconds / 100 cc Air, the cycle characteristics may be deteriorated.
本発明の複合多孔質膜は、多孔質膜Aの透気抵抗度(X秒/100ccAir)と複合多孔質膜全体の透気抵抗度(Y秒/100ccAir)の差(Y−X)が20秒/100ccAir≦Y−X≦100秒/100ccAirの関係を有する。Y−Xが20秒/100ccAir未満では、十分なフッ素系樹脂層の密着性が得られない。また、100秒/100ccAirを超えると、透気抵抗度の大幅な上昇を招き、その結果、電池に組み込んだ際に、イオン透過性が低下するため、高性能電池には適さないセパレーターとなる。 In the composite porous membrane of the present invention, the difference (Y−X) between the air permeability resistance (X seconds / 100 cc Air) of the porous membrane A and the air permeability resistance (Y seconds / 100 cc Air) of the entire composite porous membrane is 20 Second / 100 cc Air ≦ Y−X ≦ 100 seconds / 100 cc Air If Y-X is less than 20 seconds / 100 cc Air, sufficient adhesion of the fluororesin layer cannot be obtained. On the other hand, if it exceeds 100 seconds / 100 cc Air, the air permeability resistance is significantly increased. As a result, the ion permeability is lowered when the battery is incorporated in the battery, so that the separator is not suitable for a high-performance battery.
さらに複合多孔質膜の透気抵抗度は、好ましくは70〜1100秒/100ccAir、さらに好ましくは200〜800秒/100ccAir、最も好ましくは300〜700秒/100ccAirである。70秒/100ccAirよりも透気抵抗度の値が低い場合、十分な絶縁性が得られず異物詰まりや短絡、破膜を招く可能性があり、1100秒/100ccAirよりも値が高い場合には膜抵抗が高く実使用可能な範囲の充放電特性、寿命特性が得られない場合がある。 Further, the air resistance of the composite porous membrane is preferably 70 to 1100 seconds / 100 cc Air, more preferably 200 to 800 seconds / 100 cc Air, and most preferably 300 to 700 seconds / 100 cc Air. If the value of air permeability resistance is lower than 70 seconds / 100 cc Air, sufficient insulation cannot be obtained, which may cause clogging of foreign matter, short circuit, and film breakage. If the value is higher than 1100 seconds / 100 cc Air, In some cases, the membrane resistance is high, and charge / discharge characteristics and life characteristics in a practically usable range cannot be obtained.
次に本発明の複合多孔質膜の製造方法について説明する。
本発明の複合多孔質膜の製造方法では、まず、ポリエステル系フィルム又はポリオレフィン系フィルム等の基材フィルム上にワニス(フッ素系樹脂溶液)を塗布した後、低湿度ゾーンに通過させる。この間にワニス中のフッ素系樹脂と該樹脂を溶解させている溶剤とを相分離させる。
Next, the manufacturing method of the composite porous membrane of this invention is demonstrated.
In the method for producing a composite porous membrane of the present invention, first, a varnish (fluorine resin solution) is applied on a base film such as a polyester film or a polyolefin film, and then passed through a low humidity zone. During this period, the fluororesin in the varnish and the solvent in which the resin is dissolved are phase-separated.
前記ワニスを塗布する方法としては例えば、リバースロールコート法、グラビアコート法、キスコート法、ロールブラッシュ法、スプレーコート法、エアナイフコート法、ワイヤーバーバーコート法、パイプドクター法、ブレードコート法およびダイコート法などが挙げられ、これらの方法を単独であるいは組み合わせて行うことができる。 Examples of the method for applying the varnish include reverse roll coating, gravure coating, kiss coating, roll brushing, spray coating, air knife coating, wire barber coating, pipe doctor method, blade coating method, and die coating method. These methods can be carried out alone or in combination.
本発明でいう低湿度ゾーンとは、絶対湿度が6g/m3未満に調整されたゾーンである。絶対湿度の好ましい上限は4g/m3、さらに好ましくは3g/m3であり、下限は好ましくは0.5g/m3、より好ましくは0.8g/m3である。絶対湿度が0.5g/m3未満では相分離が十分に行われないため最終的に多孔質膜になりにくく、透気抵抗度上昇幅が大きくなってしまう場合がある。また、絶対湿度が6g/m3以上では相分離と平行してフッ素系樹脂の凝固が始まり、多孔質膜Aを張り合わせる際、多孔質膜Aへのフッ素系樹脂の浸透が十分行われず、十分なフッ素系樹脂の密着性が得られない。低湿度ゾーンの通過時間は、3秒以上20秒以下であることが好ましい。3秒未満では前記相分離が十分行われないおそれがあり、一方、20秒を超えるとフッ素系樹脂の凝固が進行しすぎるおそれがある。 The low humidity zone in the present invention is a zone whose absolute humidity is adjusted to less than 6 g / m 3 . The upper limit of absolute humidity is preferably 4 g / m 3 , more preferably 3 g / m 3 , and the lower limit is preferably 0.5 g / m 3 , more preferably 0.8 g / m 3 . If the absolute humidity is less than 0.5 g / m 3 , phase separation is not sufficiently performed, so that it is difficult to finally become a porous membrane, and the increase in air resistance may be increased. In addition, when the absolute humidity is 6 g / m 3 or more, the solidification of the fluororesin starts in parallel with the phase separation, and when the porous membrane A is pasted, the permeation of the fluororesin into the porous membrane A is not sufficiently performed. Sufficient adhesion of fluororesin cannot be obtained. The passage time in the low humidity zone is preferably 3 seconds or more and 20 seconds or less. If it is less than 3 seconds, the phase separation may not be sufficiently performed. On the other hand, if it exceeds 20 seconds, the solidification of the fluororesin may proceed excessively.
次いで、該塗布フィルムを高湿度ゾーンに通過させて基材フィルム上に半ゲル状のフッ素系樹脂膜を形成させる。本発明で言う高湿度ゾーンとは、絶対湿度の下限が6g/m3、好ましくは7g/m3、さらに好ましくは8g/m3、上限が25g/m3、好ましくは17g/m3、さらに好ましくは15g/m3に調整されたゾーンである。絶対湿度が6g/m3未満ではゲル状化(非流動状化)が十分に行われないため、多孔質膜Aを張り合わせる際、多孔質膜Aへのフッ素系樹脂の浸透が進み過ぎ、透気抵抗度上昇幅が大きくなる。絶対湿度が25g/m3を超えるとフッ素系樹脂の凝固が進み過ぎ、多孔質膜Aへのフッ素系樹脂の浸透が小さくなりすぎ、十分な密着性が得られない場合がある。高湿度ゾーンの通過時間は、3秒以上10秒以下であることが好ましい。3秒未満ではゲル状化(非流動状化)が十分に行われないため、多孔質膜Aを張り合わせる際、多孔質膜Aへのフッ素系樹脂の浸透が進みすぎ、透気抵抗度上昇幅が大きくなるおそれがあり、一方、10秒を超えるとフッ素系樹脂の凝固が進みすぎ、多孔質膜Aへのフッ素系樹脂の浸透が小さくなりすぎ、十分な密着性が得られないおそれがある。 Next, the coated film is passed through a high-humidity zone to form a semi-gel fluorinated resin film on the base film. The high humidity zone referred to in the present invention has a lower limit of absolute humidity of 6 g / m 3 , preferably 7 g / m 3 , more preferably 8 g / m 3 , an upper limit of 25 g / m 3 , preferably 17 g / m 3 , The zone is preferably adjusted to 15 g / m 3 . When the absolute humidity is less than 6 g / m 3 , gelation (non-fluidization) is not sufficiently performed. Therefore, when the porous membrane A is pasted, penetration of the fluororesin into the porous membrane A proceeds too much, Increase in air resistance increases. If the absolute humidity exceeds 25 g / m 3 , the solidification of the fluororesin proceeds too much, the penetration of the fluororesin into the porous film A becomes too small, and sufficient adhesion may not be obtained. The passage time in the high humidity zone is preferably 3 seconds or more and 10 seconds or less. In less than 3 seconds, gelation (non-fluidization) is not sufficiently performed. Therefore, when the porous membrane A is pasted, the penetration of the fluororesin into the porous membrane A proceeds too much, and the air permeability resistance increases. On the other hand, if the width exceeds 10 seconds, the solidification of the fluororesin proceeds too much, the penetration of the fluororesin into the porous film A becomes too small, and sufficient adhesion may not be obtained. is there.
なお、低湿度ゾーン、高湿度ゾーンともに温度条件は、絶対湿度が上記範囲内であれば特に限定されないが、省エネルギーの観点から20℃以上、50℃以下が好ましい。また、前記フィルム基材の厚さは平面性を維持できる厚さであれば特に限定されないが、25μmから100μmの厚さが好適である。25μm未満では十分な平面性が得られない場合がある。また、100μmを超えても平面性は向上しない。 The temperature condition for both the low humidity zone and the high humidity zone is not particularly limited as long as the absolute humidity is within the above range, but is preferably 20 ° C. or more and 50 ° C. or less from the viewpoint of energy saving. The thickness of the film substrate is not particularly limited as long as it can maintain the flatness, but a thickness of 25 μm to 100 μm is preferable. If it is less than 25 μm, sufficient planarity may not be obtained. Moreover, even if it exceeds 100 micrometers, planarity does not improve.
一方、三層からなりかつ最表層の少なくとも一方がポリプロピレン樹脂からなる多孔質膜Aを用意し、次に、この多孔質膜Aの最表層のポリプロピレン樹脂の表面に対して上述のようにして形成された半ゲル状のフッ素系樹脂膜を、気泡を含まないように貼り合わせる。貼り合わせる方法としては、二方向から来たフィルムを一つの金属ロールの面上で合わせる方法がフィルムに与えるダメージが少なく好ましい。ここで半ゲル状とは、雰囲気中の水分の吸収による、フッ素系樹脂溶液のゲル化が進行する過程でゲル化した領域と、溶液状態を保持している領域が混在している状態を言う。 On the other hand, a porous membrane A comprising three layers and at least one of the outermost layers comprising a polypropylene resin is prepared, and then formed on the surface of the outermost polypropylene resin of the porous membrane A as described above. The semi-gel-like fluororesin film thus formed is bonded so as not to contain bubbles. As a method of laminating, a method of laminating a film coming from two directions on the surface of one metal roll is preferable because it causes less damage to the film. Here, the semi-gel form means a state in which a gelled region and a region holding the solution state are mixed in the process of gelation of the fluororesin solution due to absorption of moisture in the atmosphere. .
半ゲル状のフッ素系樹脂膜上に、多孔質膜Aを張り合わせる時期は高湿度ゾーンを通過した直後、少なくとも10秒以内に張り合わせるのが好ましい。10秒を超えるとフッ素系樹脂膜の凝固が進み十分な多孔質膜Bの密着性が得られない場合がある。 The porous film A is preferably laminated on the semi-gelled fluorine-based resin film within at least 10 seconds immediately after passing through the high humidity zone. If it exceeds 10 seconds, solidification of the fluororesin film proceeds and sufficient adhesion of the porous film B may not be obtained.
フッ素系樹脂膜の形成後、基材フィルムを剥離してもよいが、本発明の方法では、基材フィルムを剥離することなく多孔質膜Aをフッ素系樹脂膜に貼り合わせることが好ましい。この方法を用いる場合、弾性率が低く、加工時の張力によってネッキングするような柔らかい多孔質膜Aを用いる場合でも複合多孔質膜の製造が可能になる。具体的には、ガイドロール通過時に複合多孔質膜にシワ、折れが入らない、乾燥時のカールを低減できるなど工程作業性に優れる特徴が期待できる。この時、基材と複合多孔質膜を同時に巻き取っても、乾燥工程を通過してから基材と複合多孔質膜を別々の巻き取りロールに巻き取っても良いが、後者の巻き取り方法の方が巻きズレの恐れが少なく好ましい。 After the formation of the fluororesin film, the base film may be peeled off. However, in the method of the present invention, it is preferable to attach the porous film A to the fluororesin film without peeling off the base film. When this method is used, a composite porous membrane can be produced even when a soft porous membrane A that has a low elastic modulus and is necked by the tension during processing is used. Specifically, it can be expected that the composite porous membrane does not wrinkle or bend when passing through the guide roll, and curling during drying can be reduced. At this time, the base material and the composite porous membrane may be wound up at the same time, or after passing through the drying step, the base material and the composite porous membrane may be wound up on separate winding rolls. Is preferable because there is little risk of winding deviation.
次に、貼り合わされた多孔質膜Aとフッ素系樹脂膜を凝固浴に浸漬させて、フッ素系樹脂膜を相転換させて多孔質膜Bに変換させる。凝固浴の組成は、特に限定されないが、例えば、多孔質膜Bを構成するフッ素系樹脂に対する良溶媒を1〜20重量%、さらに好ましくは5〜15重量%含有する水溶液であることができる。凝固浴への浸漬により、多孔質膜Bは、全面に渡って多孔質膜Aに転写され、未洗浄の複合多孔質膜が得られる。これは多孔質膜Bの一部が多孔質膜Aの細孔に適度に食い込みアンカー効果が発現しているためである。 Next, the bonded porous film A and fluororesin film are immersed in a coagulation bath, and the fluororesin film is phase-converted to be converted into a porous film B. The composition of the coagulation bath is not particularly limited. For example, the coagulation bath may be an aqueous solution containing 1 to 20% by weight, more preferably 5 to 15% by weight of a good solvent for the fluororesin constituting the porous membrane B. By immersion in the coagulation bath, the porous membrane B is transferred to the porous membrane A over the entire surface, and an unwashed composite porous membrane is obtained. This is because a part of the porous membrane B appropriately bites into the pores of the porous membrane A and the anchor effect is expressed.
さらに、上記の未洗浄多孔質膜を、純水などを用いた洗浄工程、及び100℃以下の熱風などを用いた乾燥工程に供し、最終的な複合多孔質膜を得ることができる。 Furthermore, the above-mentioned unwashed porous membrane can be subjected to a washing step using pure water or the like and a drying step using hot air at 100 ° C. or lower, and the final composite porous membrane can be obtained.
洗浄については、加温、超音波照射やバブリングといった一般的な手法を用いることができる。さらに、各浴槽内の濃度を一定に保ち、洗浄効率を上げるためには、浴間で多孔膜内部の溶液を取り除く手法が有効である。具体的には、空気または不活性ガスで多孔層内部の溶液を押し出す手法、ガイドロールによって物理的に膜内部の溶液を絞り出す手法などが挙げられる。 For cleaning, general techniques such as heating, ultrasonic irradiation, and bubbling can be used. Furthermore, in order to keep the concentration in each bath constant and increase the cleaning efficiency, it is effective to remove the solution inside the porous membrane between the baths. Specifically, a method of extruding the solution inside the porous layer with air or an inert gas, a method of physically squeezing out the solution inside the membrane with a guide roll, and the like can be mentioned.
なお、少なくともワニスを塗工する側の基材フィルム表面の線状オリゴマーの量は、20μg/m2以上100μg/m2以下であることが好ましく、さらに好ましくは30μg/m2以上80μg/m2以下である。基材フィルム表面の線状オリゴマーの量が20μg/m2未満では、貼り合わされた状態の多孔質膜Aと多孔質膜Bの複合多孔質膜を基材フィルムから剥離する際に、多孔質膜Bが基材フィルムに残存してしまう場合があり、一方、100μg/m2を超えると多孔質膜Bの塗工時に塗布斑が発生しやすくなるだけでなく、基材フィルム表面の線状オリゴマーによって搬送ロール等の工程汚染が発生する場合があり好ましくない。換言すれば、少なくともワニスを塗工する側の基材フィルム表面の線状オリゴマーの量が上記範囲であれば、多孔質膜Bの塗布時の均一性と、貼り合わされた状態の多孔質膜Aと多孔質膜Bの複合多孔質膜を基材フィルムから剥離する際の良好な転写性が両立しやすくなる。 The amount of linear oligomers of the side of the substrate film surface for applying at least varnish, 20 [mu] g / m is preferably 2 or more 100 [mu] g / m 2 or less, more preferably 30 [mu] g / m 2 or more 80 [mu] g / m 2 It is as follows. When the amount of the linear oligomer on the surface of the base film is less than 20 μg / m 2 , when the composite porous film of the porous film A and the porous film B in a bonded state is peeled from the base film, the porous film In some cases, B may remain on the base film. On the other hand, if it exceeds 100 μg / m 2 , not only coating spots are likely to be generated when the porous film B is applied, but also a linear oligomer on the base film surface. May cause process contamination such as a transport roll, which is not preferable. In other words, if the amount of the linear oligomer on the surface of the base film on the side on which the varnish is applied is within the above range, the uniformity when the porous film B is applied and the porous film A in a bonded state And good transferability when the composite porous membrane of the porous membrane B is peeled from the substrate film.
ここで言う線状オリゴマーの量とは、基材フィルムの原料となるポリエステル樹脂に由来する線状二量体、線状三量体、線状四量体の合計量をいう。例えばテレフタル酸とエチレングリコールを原料とするエチレンテレフタレートを主繰返し単位とするポリエステルの場合、線状二量体とは、一分子中にテレフタル酸単位を二つ有し、かつカルボン酸末端あるいは水酸基末端を持つオリゴマーを意味する。また、同様に線状三量体とは、一分子中にテレフタル酸単位を三つ有し、線状四量体とは、四つ有する以外は線状二量体と同様の末端基を有するものを意味する。 The amount of the linear oligomer referred to here means the total amount of the linear dimer, linear trimer, and linear tetramer derived from the polyester resin used as the raw material for the base film. For example, in the case of a polyester having ethylene terephthalate as the main repeating unit and starting from terephthalic acid and ethylene glycol, the linear dimer has two terephthalic acid units in one molecule and has a carboxylic acid terminal or a hydroxyl terminal. Means an oligomer having Similarly, the linear trimer has three terephthalic acid units in one molecule, and the linear tetramer has the same end group as the linear dimer except that it has four. Means things.
線状オリゴマーを付与させるための表面処理方法は特に限定されないが、例えばコロナ放電処理、グロー放電処理、火炎処理、紫外線照射処理、電子線照射処理、オゾン処理が挙げられる。中でもコロナ放電処理は比較的容易にできるため特に好ましい。 The surface treatment method for imparting the linear oligomer is not particularly limited, and examples thereof include corona discharge treatment, glow discharge treatment, flame treatment, ultraviolet irradiation treatment, electron beam irradiation treatment, and ozone treatment. Among these, the corona discharge treatment is particularly preferable because it can be relatively easily performed.
本発明の方法によれば、多孔質膜Aの最表層が比較的空孔率の小さいポリプロピレン樹脂からなる場合においても、密着性と透気抵抗度のバランスに優れた複合多孔質膜が得られる。 According to the method of the present invention, even when the outermost layer of the porous membrane A is made of a polypropylene resin having a relatively low porosity, a composite porous membrane having an excellent balance between adhesion and air resistance can be obtained. .
本発明の複合多孔質膜は、目的幅にスリットされたポリプロピレン系多孔質膜を多孔質膜Aとして用いて作成することもできるが、ポリプロピレン多孔質膜作製時にオンラインで続いて加工することも可能である。ここでオンラインとは、ポリプロピレン多孔質膜の製造工程(具体的には、洗浄後の乾燥工程)後に、連続して多孔質膜Bを積層し、凝固、洗浄、スリットの各工程を経て目的とする複合多孔質膜を得る手段を言う。上記オンライン塗工を行うことで、大量生産が可能となり、コスト面で非常にメリットがある。 The composite porous membrane of the present invention can be prepared using a polypropylene-based porous membrane slit to a desired width as the porous membrane A, but can also be processed on-line at the time of producing the polypropylene porous membrane. It is. Here, “online” means that after the production process of the polypropylene porous membrane (specifically, the drying step after washing), the porous membrane B is continuously laminated, followed by the solidification, washing, and slitting steps. Means for obtaining a composite porous membrane. By performing the above-mentioned online coating, mass production becomes possible, which is very advantageous in terms of cost.
本発明の複合多孔質膜は、乾燥状態で保存することが望ましいが、絶乾状態での保存が困難な場合は、使用の直前に100℃以下の減圧乾燥処理を行うことが好ましい。 Although it is desirable to store the composite porous membrane of the present invention in a dry state, if it is difficult to store in a completely dry state, it is preferable to perform a vacuum drying treatment at 100 ° C. or lower immediately before use.
本発明の複合多孔質膜は、ニッケル−水素電池、ニッケル−カドミウム電池、ニッケル−亜鉛電池、銀−亜鉛電池、リチウム二次電池、リチウムポリマー二次電池等の二次電池、およびプラスチックフィルムコンデンサ、セラミックコンデンサ、電気二重層コンデンサなどのセパレーターとして用いることができるが、特にリチウム二次電池のセパレーターとして用いるのが好ましい。以下にリチウム二次電池を例にとって説明する。 The composite porous membrane of the present invention includes a nickel-hydrogen battery, a nickel-cadmium battery, a nickel-zinc battery, a silver-zinc battery, a lithium secondary battery, a secondary battery such as a lithium polymer secondary battery, and a plastic film capacitor, Although it can be used as a separator for ceramic capacitors, electric double layer capacitors, etc., it is particularly preferred to be used as a separator for lithium secondary batteries. Hereinafter, a lithium secondary battery will be described as an example.
リチウム二次電池は、正極と負極がセパレーターを介して積層されており、セパレーターは電解液(電解質)を含有している。電極の構造は特に限定されず、公知の構造であることができる。例えば、円盤状の正極及び負極が対向するように配設された電極構造(コイン型)、平板状の正極及び負極が交互に積層された電極構造(積層型)、帯状の正極及び負極が重ねられて巻回された電極構造(巻回型)等の構造とすることができる。 In a lithium secondary battery, a positive electrode and a negative electrode are laminated via a separator, and the separator contains an electrolytic solution (electrolyte). The structure of the electrode is not particularly limited, and may be a known structure. For example, an electrode structure (coin type) in which disc-shaped positive electrodes and negative electrodes are opposed to each other, an electrode structure in which flat plate-like positive electrodes and negative electrodes are alternately stacked (stacked type), and belt-shaped positive electrodes and negative electrodes are stacked. It can be set as a structure such as a wound electrode structure (winding type).
正極は、集電体とその表面に形成されたリチウムイオンを吸蔵放出可能な正極活物質を含む正極活物質層とを有する。正極活物質としては、遷移金属酸化物、リチウムと遷移金属との複合酸化物(リチウム複合酸化物)、遷移金属硫化物等の無機化合物等が挙げられ、遷移金属としては、V、Mn、Fe、Co、Ni等が挙げられる。正極活物質の中でリチウム複合酸化物の好ましい例としては、ニッケル酸リチウム、コバルト酸リチウム、マンガン酸リチウム、α−NaFeO2型構造を母体とする層状リチウム複合酸化物等が挙げられる。 The positive electrode has a current collector and a positive electrode active material layer containing a positive electrode active material capable of occluding and releasing lithium ions formed on the current collector. Examples of the positive electrode active material include transition metal oxides, composite oxides of lithium and transition metals (lithium composite oxides), and inorganic compounds such as transition metal sulfides. Transition metals include V, Mn, and Fe. , Co, Ni and the like. Preferred examples of the lithium composite oxide among the positive electrode active materials include lithium nickelate, lithium cobaltate, lithium manganate, and a layered lithium composite oxide based on an α-NaFeO 2 type structure.
負極は、集電体とその表面に形成された負極活物質を含む負極活物質層とを有する。負極活物質としては、天然黒鉛、人造黒鉛、コークス類、カーボンブラック等の炭素質材料が挙げられる。電解液はリチウム塩を有機溶媒に溶解することにより得られる。リチウム塩としては、LiClO4、LiPF6、LiAsF6、LiSbF6、LiBF4、LiCF3SO3、LiN(CF3SO2)2、LiC(CF3SO2)3、Li2B10Cl10、LiN(C2F5SO2)2、LiPF4(CF3)2、LiPF3(C2F5)3、低級脂肪族カルボン酸リチウム塩、LiAlCl4等が挙げられる。これらは単独で用いても2種以上を混合して用いてもよい。有機溶媒としては、エチレンカーボネート、プロピレンカーボネート、エチルメチルカーボネート、γ−ブチロラクトン等の高沸点及び高誘電率の有機溶媒や、テトラヒドロフラン、2−メチルテトラヒドロフラン、ジメトキシエタン、ジオキソラン、ジメチルカーボネート、ジエチルカーボネート等の低沸点及び低粘度の有機溶媒が挙げられる。これらは単独で用いても2種以上を混合して用いてもよい。特に高誘電率の有機溶媒は粘度が高く、低粘度の有機溶媒は誘電率が低いため、両者を混合して用いるのが好ましい。 The negative electrode has a current collector and a negative electrode active material layer including a negative electrode active material formed on the surface of the current collector. Examples of the negative electrode active material include carbonaceous materials such as natural graphite, artificial graphite, cokes, and carbon black. The electrolytic solution can be obtained by dissolving a lithium salt in an organic solvent. Lithium salts include LiClO 4 , LiPF 6 , LiAsF 6 , LiSbF 6 , LiBF 4 , LiCF 3 SO 3 , LiN (CF 3 SO 2 ) 2 , LiC (CF 3 SO 2 ) 3 , Li 2 B 10 Cl 10 , Examples include LiN (C 2 F 5 SO 2 ) 2 , LiPF 4 (CF 3 ) 2 , LiPF 3 (C 2 F 5 ) 3 , lower aliphatic carboxylic acid lithium salt, LiAlCl 4 and the like. These may be used alone or in admixture of two or more. Examples of the organic solvent include organic solvents having a high boiling point and a high dielectric constant such as ethylene carbonate, propylene carbonate, ethyl methyl carbonate, and γ-butyrolactone, tetrahydrofuran, 2-methyltetrahydrofuran, dimethoxyethane, dioxolane, dimethyl carbonate, diethyl carbonate, and the like. Examples include organic solvents having a low boiling point and a low viscosity. These may be used alone or in admixture of two or more. In particular, a high dielectric constant organic solvent has a high viscosity, and a low viscosity organic solvent has a low dielectric constant. Therefore, it is preferable to use a mixture of both.
電池を組み立てる際に、セパレーター(複合多孔質膜)に電解液を含浸させる。これによりセパレーターにイオン透過性を付与することができる。通常、含浸処理は多孔質膜を常温で電解液に浸漬して行う。例えば、円筒型電池を組み立てる場合、まず正極シート、セパレーター(複合多孔質膜)、及び負極シートをこの順に積層し、この積層体を一端より巻き取って巻回型電極素子とする。次にこの電極素子を電池缶に挿入し、上記電解液を含浸させ、さらに安全弁を備えた正極端子を兼ねる電池蓋を、ガスケットを介してかしめることにより電池を得ることができる。 When assembling the battery, the separator (composite porous membrane) is impregnated with the electrolytic solution. Thereby, ion permeability can be imparted to the separator. Usually, the impregnation treatment is performed by immersing the porous membrane in an electrolytic solution at room temperature. For example, when assembling a cylindrical battery, first, a positive electrode sheet, a separator (composite porous membrane), and a negative electrode sheet are laminated in this order, and this laminate is wound from one end to form a wound electrode element. Next, a battery can be obtained by inserting this electrode element into a battery can, impregnating with the above electrolyte, and caulking a battery lid also serving as a positive electrode terminal provided with a safety valve via a gasket.
以下、実施例を示して具体的に説明するが、本発明はこれらの実施例によって何ら制限されるものではない。なお、実施例中の測定値は以下の方法で測定した。 Hereinafter, although an example is shown and explained concretely, the present invention is not restrict | limited at all by these examples. In addition, the measured value in an Example was measured with the following method.
(1)膜厚
接触式膜厚計(ソニーマニュファクチュアリング社製 デジタルマイクロメーター M−30)を使用して測定した。
(1) Film thickness It measured using the contact-type film thickness meter (Sony Manufacturing Co., Ltd. digital micrometer M-30).
(2)多孔質膜Aと多孔質膜B界面の剥離強度
実施例及び比較例で得られたセパレーターの多孔質膜B面に粘着テープ(ニチバン社製、405番;24mm幅)を貼り、幅24mm、長さ150mmに裁断し、試験用サンプルを作製した。
(2) Peel strength at the interface between porous membrane A and porous membrane B Adhesive tape (Nichiban Co., Ltd., No. 405; 24 mm width) is applied to the porous membrane B surface of the separator obtained in the examples and comparative examples, and the width It cut | judged to 24 mm and length 150mm, and produced the sample for a test.
23℃、50%RH条件下で引張り試験機[エー・アンド・デイ社製「テンシロンRTM−100」]を用いて、ピール法(剥離速度500mm/分、T型剥離)にて多孔質膜Aと多孔質膜B界面の剥離強度を測定した。測定開始から測定終了までの100mmの間において、経時的に測定し、測定値の平均値を算出し、幅25mm当たりの値に換算して剥離強度とした。なお、前記剥離界面において、多孔質膜A側に多孔質膜B面が残存する場合があるが、この場合も多孔質膜Aと多孔質膜B界面の剥離強度として算出した。 Porous film A using a tensile tester [“Tensilon RTM-100” manufactured by A & D Co., Ltd.] under the conditions of 23 ° C. and 50% RH by a peel method (peeling speed 500 mm / min, T-type peeling). And the peel strength at the interface of the porous membrane B were measured. The measurement was performed over time during 100 mm from the start of measurement to the end of measurement, the average value of the measured values was calculated, and converted to a value per 25 mm width to obtain the peel strength. In addition, although the porous membrane B surface may remain on the porous membrane A side at the peeling interface, the peeling strength at the interface between the porous membrane A and the porous membrane B is also calculated in this case.
(3)平均孔径
多孔質膜Aの平均孔径は以下の方法で測定した。試験片を測定用セルに上に両面テープを用いて固定し、プラチナまたは金を数分間真空蒸着させ、適度な倍率で測定を行った。SEM測定で得られた画像上で最も手前に観察される任意の10箇所を選択し、それら10箇所の孔径の平均値を試験片の平均孔径とした。なお、孔が略円形でない場合には、長径と短径を足して2で割った値を孔径とした。
(3) Average pore diameter The average pore diameter of the porous membrane A was measured by the following method. The test piece was fixed to the measuring cell using double-sided tape, platinum or gold was vacuum-deposited for several minutes, and the measurement was performed at an appropriate magnification. Arbitrary 10 places observed most foremost on the image obtained by SEM measurement were selected, and the average value of the pore diameters at these 10 places was defined as the average pore diameter of the test piece. In addition, when the hole was not substantially circular, the value obtained by adding the major axis and the minor axis and dividing by 2 was defined as the hole diameter.
(4)透気抵抗度
テスター産業(株)社製のガーレー式デンソメーターB型を使用して、複合多孔質膜をクランピングプレートとアダプタープレートの間にシワが入らないように固定し、JIS P−8117に従って測定した。試料としては10cm角のものを2枚用意し、それぞれの試料について、試料の中央部と4隅を測定点として合計10点の測定を行い、10点の平均値を透気抵抗度[秒/100ccAir]として用いた。なお、試料の1辺の長さが10cmに満たない場合は5cm間隔で10点測定した値を用いてもよい。
(4) Air permeability resistance Using a Gurley-type densometer type B manufactured by Tester Sangyo Co., Ltd., the composite porous membrane is fixed so that no wrinkles are formed between the clamping plate and the adapter plate. Measured according to P-8117. Two samples of 10 cm square were prepared as samples, and for each sample, a total of 10 points were measured with the central part and four corners of the sample as measurement points, and the average value of 10 points was measured for air resistance [seconds / second] 100 cc Air]. When the length of one side of the sample is less than 10 cm, a value obtained by measuring 10 points at intervals of 5 cm may be used.
(5)対数粘度
フッ素系樹脂0.5gを100mlのNMPに溶解した溶液を25℃でウベローデ粘度管を用いて測定した。
(5) Logarithmic viscosity A solution of 0.5 g of fluororesin dissolved in 100 ml of NMP was measured at 25 ° C. using an Ubbelohde viscosity tube.
(6)融点
エスアイアイ・ナノテクノロジー(株)社製の示差走査熱量計(DSC)DSC6220を用い、窒素ガス雰囲気下で樹脂試料5mgを昇温速度20℃/分で昇温したとき観察される融解ピークの頂点温度を融点とした。
(6) Melting point This is observed when 5 mg of a resin sample is heated at a heating rate of 20 ° C./min in a nitrogen gas atmosphere using a differential scanning calorimeter (DSC) DSC 6220 manufactured by SII Nanotechnology Inc. The peak temperature of the melting peak was taken as the melting point.
(7)空孔率
10cm角の試料を用意し、その試料体積(cm3)と質量(g)を測定し、得られた結果から次式を用いて空孔率(%)を計算した。なお、10cm角試料の試料体積(cm3)は、10(cm)×10(cm)×多孔質膜Aの厚み(cm)で求めることができる。
空孔率=(1−質量/(樹脂密度×試料体積))×100
(7) Porosity A 10 cm square sample was prepared, its sample volume (cm 3 ) and mass (g) were measured, and the porosity (%) was calculated from the obtained result using the following formula. Note that the sample volume (cm 3 ) of the 10 cm square sample can be obtained by 10 (cm) × 10 (cm) × the thickness (cm) of the porous film A.
Porosity = (1−mass / (resin density × sample volume)) × 100
(8)基材フィルム表面の線状オリゴマーの量
フィルム2枚の抽出したい面同士を向かい合わせ、1枚につき25.2cm×12.4cm面積を抽出できるようスペーサーをはさんで枠に固定した。エタノール30mlを抽出面間に注入し、25℃で3分間、フィルム表面の線状オリゴマーを抽出した。抽出液を蒸発乾固した後、得られた抽出液の乾固残渣をジメチルホルムアミド200μlに定容した。次いで高速液体クロマトグラフィーを用いて、下記に示す方法で予め求めておいた検量線から線状オリゴマーを定量した。なお、線状オリゴマーの量は二量体、三量体、四量体の合計値とした。
(8) Amount of linear oligomer on the surface of the base film The faces of the two films to be extracted face each other and fixed to a frame with a spacer so that an area of 25.2 cm × 12.4 cm can be extracted per sheet. 30 ml of ethanol was injected between the extraction surfaces, and linear oligomers on the film surface were extracted at 25 ° C. for 3 minutes. After evaporating the extract to dryness, the dry residue of the resulting extract was made up to 200 μl of dimethylformamide. Subsequently, the linear oligomer was quantified from the analytical curve previously calculated | required by the method shown below using the high performance liquid chromatography. In addition, the quantity of the linear oligomer was taken as the total value of a dimer, a trimer, and a tetramer.
(測定条件)
装置:ACQUITY UPLC(Waters製)
カラム:BEH−C18 2.1×150mm(Waters製)
移動相:溶離液A:0.1%ギ酸(v/v)
溶離液B:アセトニトリル
グラジエントB%:10→98→98%(0→25→30分)
流速:0.2ml/分
カラム温度:40℃
検出器:UV−258nm
(Measurement condition)
Apparatus: ACQUITY UPLC (manufactured by Waters)
Column: BEH-C18 2.1 × 150 mm (manufactured by Waters)
Mobile phase: Eluent A: 0.1% formic acid (v / v)
Eluent B: Acetonitrile
Gradient B%: 10 → 98 → 98% (0 → 25 → 30 minutes)
Flow rate: 0.2 ml / min Column temperature: 40 ° C
Detector: UV-258nm
参考例1
フッ素系樹脂としてポリフッ化ビニリデン(融点175 ℃、呉羽化学工業(株)社製、商品名:KFポリマー♯1120(ポリフッ化ビニリデン 12% N−メチルピロリドン溶液)をN−メチル−2−ピロリドンで希釈して、ワニス(a−1)(固形分濃度5.8重量%)を調合した。一連の作業は湿度10%以下の乾燥気流中で行い、吸湿を極力防止した。ワニス(a−1)の水分率は0.2重量%であった。厚み50μm、表面線状オリゴマー量68μg/m2のポリエチレンテレフタレート樹脂フィルム表面にワニス(a−1)をブレードコート法にて塗布し、温度25℃、絶対湿度1.8g/m3の低湿度ゾーンを8秒間、引き続き温度25℃、絶対湿度12g/m3の高湿度ゾーンを5秒間で通過させて半ゲル状のフッ素系樹脂膜を形成させ、1.7秒後に多孔質膜A(ポリプロピレン製、厚み20μm、空孔率40%、平均孔径0.10μm、透気抵抗度600秒/100ccAir)を、上記の半ゲル状フッ素系樹脂膜に重ね、N−メチル−2−ピロリドンを5重量%含有する水溶液中に進入させ、その後、純水で洗浄した後、70℃の熱風乾燥炉を通過させることで乾燥し、最終厚み22.9μmの複合多孔質膜を得た。
Reference example 1
Polyvinylidene fluoride (melting point: 175 ° C., Kureha Chemical Industry Co., Ltd., trade name: KF polymer # 1120 (polyvinylidene fluoride 12% N-methylpyrrolidone solution) diluted with N-methyl-2-pyrrolidone as fluorine resin Then, varnish (a-1) (solid content concentration 5.8% by weight) was prepared, and a series of operations were performed in a dry air flow with a humidity of 10% or less to prevent moisture absorption as much as possible. The varnish (a-1) was applied to the surface of a polyethylene terephthalate resin film having a thickness of 50 μm and a surface linear oligomer amount of 68 μg / m 2 by a blade coating method, and the temperature was 25 ° C. A semi-gel-like fluororesin is passed through a low-humidity zone with an absolute humidity of 1.8 g / m 3 for 8 seconds, followed by a high-humidity zone with a temperature of 25 ° C. and an absolute humidity of 12 g / m 3 for 5 seconds. A membrane was formed, and after 1.7 seconds, porous membrane A (made of polypropylene, thickness 20 μm, porosity 40%, average pore diameter 0.10 μm, air resistance 600 seconds / 100 cc Air) Overlaid on a resin film, it was allowed to enter an aqueous solution containing 5% by weight of N-methyl-2-pyrrolidone, then washed with pure water, and then dried by passing through a hot air drying oven at 70 ° C. to obtain a final thickness. A 22.9 μm composite porous membrane was obtained.
参考例2
低湿度ゾーンの絶対湿度を4.0g/m3とした以外は参考例1と同様にして複合多孔質膜を得た。
Reference example 2
A composite porous membrane was obtained in the same manner as in Reference Example 1 except that the absolute humidity of the low humidity zone was 4.0 g / m 3 .
参考例3
低湿度ゾーンの絶対湿度を5.5g/m3とした以外は参考例1と同様にして複合多孔質膜を得た。
Reference example 3
A composite porous membrane was obtained in the same manner as in Reference Example 1 except that the absolute humidity in the low humidity zone was 5.5 g / m 3 .
参考例4
高湿度ゾーンの絶対湿度を7.0g/m3とした以外は参考例1と同様にして複合多孔質膜を得た。
Reference example 4
A composite porous membrane was obtained in the same manner as in Reference Example 1 except that the absolute humidity of the high humidity zone was 7.0 g / m 3 .
参考例5
高湿度ゾーンの絶対湿度を16.0g/m3とした以外は参考例1と同様にして複合多孔質膜を得た。
Reference Example 5
A composite porous membrane was obtained in the same manner as in Reference Example 1 except that the absolute humidity of the high-humidity zone was 16.0 g / m 3 .
参考例6
低湿度ゾーン及び高湿度ゾーンの通過時間をそれぞれ5.3秒、3.0秒とし、高湿度ゾーン出口から多孔質膜Aを貼り合わせるまでの時間を1.1秒とした以外は参考例1と同様にして複合多孔質膜を得た。
Reference Example 6
Reference Example 1 except that the passage times of the low-humidity zone and the high-humidity zone were 5.3 seconds and 3.0 seconds, respectively, and the time from the exit of the high-humidity zone to the bonding of the porous membrane A was 1.1 seconds. In the same manner, a composite porous membrane was obtained.
参考例7
低湿度ゾーン及び高湿度ゾーンの通過時間をそれぞれ16.0秒、10.0秒とし、高湿度ゾーン出口から多孔質膜Aを貼り合わせるまでの時間を3.4秒とした以外は参考例1と同様にして複合多孔質膜を得た。
Reference Example 7
Reference Example 1 except that the passage times of the low humidity zone and the high humidity zone were 16.0 seconds and 10.0 seconds, respectively, and the time from the exit of the high humidity zone to the bonding of the porous membrane A was 3.4 seconds. In the same manner, a composite porous membrane was obtained.
実施例1
多孔質フィルムAとしてポリプロピレン/ポリエチレン/ポリプロピレンの3層構造を有する多孔質膜(厚み25μm(ポリプロピレン/ポリエチレン/ポリプロピレン=8μm/9μm/8μm)、空孔率40%、平均孔径0.10μm、透気抵抗度620秒/100ccAir)を用いた以外は参考例1と同様にして複合多孔質膜を得た。
Example 1
Porous film A having a three-layer structure of polypropylene / polyethylene / polypropylene (thickness 25 μm (polypropylene / polyethylene / polypropylene = 8 μm / 9 μm / 8 μm), porosity 40%, average pore diameter 0.10 μm, air permeability A composite porous membrane was obtained in the same manner as in Reference Example 1 except that the resistivity was 620 seconds / 100 cc Air).
実施例2
多孔質フィルムAとしてポリプロピレン/ポリエチレン/ポリプロピレンの3層構造を有する多孔質膜(厚み20.5μm(ポリプロピレン/ポリエチレン/ポリプロピレ=6μm/8.5μm/6μm)、空孔率50%、平均孔径0.10μm、透気抵抗度320秒/100ccAir)を用いた以外は参考例1と同様にして複合多孔質膜を得た。
Example 2
The porous film A has a three-layer structure of polypropylene / polyethylene / polypropylene (thickness 20.5 μm (polypropylene / polyethylene / polypropylene = 6 μm / 8.5 μm / 6 μm), porosity 50%, average pore size 0. A composite porous membrane was obtained in the same manner as in Reference Example 1 except that 10 μm and air resistance of 320 seconds / 100 cc Air) were used.
参考例8
フッ素系樹脂としてポリ(ビニリデンフロライド―ヘキサフルオロプロピレン)共重合体(エルフ・アトケム・ジャパン社製KYNAR2800)に代えたワニス(b)(固形分濃度5.3重量%)を用いた以外は参考例1と同様にして複合多孔質膜を得た。
Reference Example 8
Fluorine-based resin as the poly - except for using (vinylidene fluoride hexafluoropropylene) copolymer (Elf Atochem Japan Co. KYNAR2800) in place of the varnish (b) (solid concentration 5.3 wt%) Reference A composite porous membrane was obtained in the same manner as in Example 1.
参考例9
フッ素系樹脂としてポリフッ化ビニリデン(融点175 ℃、呉羽化学工業(株)社製、商品名:KFポリマー♯1120(ポリフッ化ビニリデン 12% N−メチルピロリドン溶液)32.6質量部及び平均粒径0.5μmのアルミナ粒子10.5質量部をN−メチル−2−ピロリドン48.4質量部で希釈して、さらにエチレングリコール8.5質量部を加え、酸化ジルコニウムビーズ(東レ社製、商品名「トレセラムビーズ」、直径0.5mm)と共に、ポリプロピレン製の容器に入れ、ペイントシェーカー(東洋精機製作所製)で6時間分散させた。次いで、濾過限界5μmのフィルターで濾過し、ワニス(c)(固形分濃度31.0重量%)を調合した。ワニス(a−1)をワニス(c)に代えた以外は参考例1と同様にして複合多孔質膜を得た。
Reference Example 9
Polyvinylidene fluoride (melting point: 175 ° C., manufactured by Kureha Chemical Industries, Ltd., trade name: KF polymer # 1120 (polyvinylidene fluoride 12% N-methylpyrrolidone solution) 32.6 parts by mass and average particle size 0 10.5 parts by mass of 0.5 μm alumina particles were diluted with 48.4 parts by mass of N-methyl-2-pyrrolidone, and 8.5 parts by mass of ethylene glycol was further added. Together with “Traceram beads” (diameter: 0.5 mm), the mixture was placed in a polypropylene container and dispersed for 6 hours with a paint shaker (manufactured by Toyo Seiki Seisakusho), followed by filtration with a filter having a filtration limit of 5 μm, and varnish (c) ( A solid porosity of 31.0% by weight was prepared in the same manner as in Reference Example 1 except that varnish (a-1) was replaced with varnish (c). A membrane was obtained.
参考例10
アルミナ粒子を酸化チタン粒子(チタン工業社製、商品名「KR−380」、平均粒子径0.38μm)に代えたワニス(d)(固形分濃度31.0重量%)を用いた以外は参考例9と同様にして複合多孔質膜を得た。
Reference Example 10
Reference was made except that the varnish (d) (solid content concentration 31.0% by weight) in which the alumina particles were replaced with titanium oxide particles (manufactured by Titanium Industry Co., Ltd., trade name “KR-380”, average particle size 0.38 μm). A composite porous membrane was obtained in the same manner as in Example 9 .
参考例11
多孔質膜Bの塗布量を調整し、最終厚み21.9μmとした以外は参考例1と同様にして複合多孔質膜を得た。
Reference Example 11
A composite porous membrane was obtained in the same manner as in Reference Example 1 except that the coating amount of the porous membrane B was adjusted to a final thickness of 21.9 μm.
参考例12
参考例1で得られたフッ素系樹脂溶液(a−1)を該樹脂溶液の体積比で10倍の水浴中に投入し、樹脂成分を沈降させた。次いで、樹脂固形物を十分水洗してNMPを除去した後、真空乾燥機を用いて180℃、24時間の条件で乾燥させた。その後、固形分濃度が14重量%となるようにN−メチル−2−ピロリドンで希釈してワニス(a−2)を調合した。ワニス(a−2)の水分率は0.05重量%であった。ワニス(a−1)をワニス(a−2)に代えた以外は参考例1と同様にして複合多孔質膜を得た。
Reference Example 12
The fluororesin solution (a-1) obtained in Reference Example 1 was put into a water bath 10 times the volume ratio of the resin solution to precipitate the resin component. Next, the resin solid was sufficiently washed with water to remove NMP, and then dried using a vacuum dryer at 180 ° C. for 24 hours. Then, it diluted with N-methyl-2-pyrrolidone so that solid content concentration might be 14 weight%, and varnish (a-2) was prepared. The moisture content of the varnish (a-2) was 0.05% by weight. A composite porous membrane was obtained in the same manner as in Reference Example 1 except that the varnish (a-1) was replaced with the varnish (a-2).
参考例13
低湿度ゾーンの絶対湿度を1.2g/m3とした以外は参考例1と同様にして複合多孔質膜を得た。
Reference Example 13
A composite porous membrane was obtained in the same manner as in Reference Example 1 except that the absolute humidity of the low-humidity zone was 1.2 g / m 3 .
参考例14
多孔質膜Bの塗布量を調整し、最終厚みを25.0μmとした以外は参考例1と同様にして複合多孔質膜を得た。
Reference Example 14
A composite porous membrane was obtained in the same manner as in Reference Example 1 except that the coating amount of the porous membrane B was adjusted and the final thickness was 25.0 μm.
参考例15
表面線状オリゴマー量68μg/m2のポリエチレンテレフタレート樹脂フィルムの代わりに表面線状オリゴマー量25μg/m2のポリエチレンテレフタレート樹脂フィルムを用いた以外は参考例1と同様にして複合多孔質膜を得た。
Reference Example 15
Except for using a polyethylene terephthalate resin film of the surface linear oligomers amount 25 [mu] g / m 2 in place of the polyethylene terephthalate resin film of the surface linear oligomers amount 68μg / m 2 in the same manner as in Reference Example 1 to obtain a composite porous membrane .
比較例1
低湿度ゾーンを温度25℃、絶対湿度7.0g/m3とした以外は参考例1と同様にして複合多孔質膜を得た。
Comparative Example 1
A composite porous membrane was obtained in the same manner as in Reference Example 1 except that the low humidity zone was set at a temperature of 25 ° C. and an absolute humidity of 7.0 g / m 3 .
比較例2
高湿度ゾーンを温度25℃、絶対湿度5.0g/m3とした以外は参考例1と同様にして複合多孔質膜を得た。
Comparative Example 2
A composite porous membrane was obtained in the same manner as in Reference Example 1 except that the high humidity zone was set to a temperature of 25 ° C. and an absolute humidity of 5.0 g / m 3 .
比較例3
参考例1で用いた多孔質膜Aにワニス(a−1)をブレードコート法にて塗布し、温度25℃、絶対湿度1.8g/m3の低湿度ゾーンを8秒間、引き続き温度25℃、絶対湿度12g/m3の高湿度ゾーンを5秒間で通過させ、次いで2秒後に、N−メチル−2−ピロリドンを5重量%含有する水溶液中に進入させ、その後、純水で洗浄した後、70℃の熱風乾燥炉を通過させることで乾燥し、最終厚み22.9μmの複合多孔質膜を得た。
Comparative Example 3
Varnish (a-1) was applied to the porous membrane A used in Reference Example 1 by a blade coating method, a low humidity zone having a temperature of 25 ° C. and an absolute humidity of 1.8 g / m 3 was applied for 8 seconds, and subsequently a temperature of 25 ° C. After passing through a high humidity zone with an absolute humidity of 12 g / m 3 for 5 seconds, and then 2 seconds later, it was allowed to enter an aqueous solution containing 5% by weight of N-methyl-2-pyrrolidone and then washed with pure water. Then, it was dried by passing it through a hot air drying oven at 70 ° C. to obtain a composite porous membrane having a final thickness of 22.9 μm.
比較例4
参考例1で用いた多孔質フィルムAを事前にN−メチル−2−ピロリドンに浸漬して細孔内をN−メチル−2−ピロリドンで満たして用いた以外は比較例3と同様にして複合多孔質膜を得た。
比較例5
基材フィルムとして表面線状オリゴマー量68μg/m2のポリエチレンテレフタレート樹脂フィルムの代わりに表面線状オリゴマー量3μg/m2ポリエチレンテレフタレート樹脂フィルムを用いた以外は参考例1と同様にして複合多孔質膜の作製を試みたが、基材フィルムから、貼り合わされた状態の多孔質膜Aと多孔質膜Bの複合多孔質膜を剥離する際に、多孔質膜Bがフィルム基材に残存し、複合多孔質膜は得られなかった。
Comparative Example 4
The composite was made in the same manner as in Comparative Example 3 except that the porous film A used in Reference Example 1 was previously immersed in N-methyl-2-pyrrolidone and the pores were filled with N-methyl-2-pyrrolidone. A porous membrane was obtained.
Comparative Example 5
Except for using the surface linear oligomer content 3 [mu] g / m 2 polyethylene terephthalate resin film in place of the polyethylene terephthalate resin film of the surface linear oligomers amount 68μg / m 2 as a base film in the same manner as in Reference Example 1 composite porous membrane However, when the composite porous film of the porous film A and the porous film B in a bonded state is peeled from the base film, the porous film B remains on the film base material, A porous membrane was not obtained.
比較例6
高湿度ゾーンの絶対湿度25.5g/m3とした以外は参考例1と同様にして複合多孔質膜を得た。
Comparative Example 6
A composite porous membrane was obtained in the same manner as in Reference Example 1 except that the absolute humidity of the high humidity zone was 25.5 g / m 3 .
参考例1〜15、実施例1〜2、比較例1〜6の複合多孔質膜の製造条件、並びに多孔質膜A及び複合多孔質膜の特性を表1に示す。 Table 1 shows the production conditions of the composite porous membranes of Reference Examples 1 to 15, Examples 1 to 2 and Comparative Examples 1 to 6, and the characteristics of the porous membrane A and the composite porous membrane.
本発明の複合多孔質膜は、優れたフッ素系樹脂層の密着性と小さい透気抵抗度上昇幅が両立しており、電池の高容量化、高イオン透過性、および、電池組み立て加工工程における高速加工性に適し、特に電池用セパレーターに好適な複合多孔質膜である。 The composite porous membrane of the present invention has both excellent adhesion of the fluorine-based resin layer and a small increase in air permeability resistance, and has high battery capacity, high ion permeability, and battery assembly processing steps. It is a composite porous membrane suitable for high-speed processability and particularly suitable for battery separators.
Claims (8)
0.01μm≦多孔質膜Aの平均孔径≦1.0μm ・・・・・式(A)
30%≦多孔質膜Aの空孔率≦70% ・・・・・式(B)
多孔質膜Aと多孔質膜Bの界面での剥離強度≧1.0N/25mm・・・・・式(C)
20≦Y−X≦100 ・・・・・式(D)
(Xは多孔質膜Aの透気抵抗度(秒/100ccAir)、Yは複合多孔質膜全体の透気抵抗度(秒/100ccAir)である) A composite porous membrane in which a porous membrane B containing a fluororesin is laminated on the surface of the outermost polypropylene resin of the porous membrane A composed of three layers and at least one of the outermost layers is made of polypropylene resin. The porous membrane A satisfies the following formulas (A) and (B), the composite porous membrane satisfies the following formulas (C) and (D), and the porous membrane A is polypropylene / polyethylene / A composite porous membrane characterized in that three layers of polypropylene are laminated.
0.01 μm ≦ average pore diameter of porous membrane A ≦ 1.0 μm Formula (A)
30% ≦ Porosity of porous membrane A ≦ 70% Formula (B)
Peel strength at the interface between porous membrane A and porous membrane B ≧ 1.0 N / 25 mm Formula (C)
20 ≦ Y−X ≦ 100 Formula (D)
(X is the air permeability resistance of the porous membrane A (second / 100 cc Air), Y is the air resistance of the entire composite porous membrane (second / 100 cc Air))
工程(i):基材フィルム上にフッ素系樹脂溶液を塗布した後、絶対湿度6g/m3未満の低湿度ゾーンを通過させ、次いで、絶対湿度6g/m3以上25g/m3以下の高湿度ゾーンを通過させて基材フィルム上にフッ素系樹脂膜を形成する工程、
工程(ii):三層からなりかつ最表層の少なくとも一方がポリプロピレン樹脂からなる多孔質膜Aを用意する工程、および
工程(iii):工程(ii)の多孔質膜Aの最表層のポリプロピレン樹脂の表面に対して工程(i)で形成されたフッ素系樹脂膜を貼り合わせた後、凝固浴に浸漬させてフッ素系樹脂膜を多孔質膜Bに変換させ、洗浄、乾燥し、複合多孔質膜を得る工程。 The method for producing a composite porous membrane according to claim 1, comprising the following steps (i) to (iii).
Step (i): After applying the fluororesin solution on the base film, it is passed through a low-humidity zone having an absolute humidity of less than 6 g / m 3 , and then high in an absolute humidity of 6 g / m 3 or more and 25 g / m 3 or less. Forming a fluororesin film on the base film by passing through the humidity zone;
Step (ii): Step of preparing a porous membrane A comprising three layers and at least one of the outermost layers comprising a polypropylene resin, and Step (iii): Polypropylene resin of the outermost layer of the porous membrane A in Step (ii) After the fluororesin film formed in step (i) is bonded to the surface of the film, it is immersed in a coagulation bath to convert the fluororesin film into a porous film B, washed and dried, and composite porous A step of obtaining a film.
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WO2007097249A1 (en) * | 2006-02-20 | 2007-08-30 | Daicel Chemical Industries, Ltd. | Porous film and layered product including porous film |
KR100727248B1 (en) * | 2007-02-05 | 2007-06-11 | 주식회사 엘지화학 | Organic/inorganic composite separator having porous active coating layer and electrochemical device containing the same |
KR101174986B1 (en) * | 2007-10-12 | 2012-08-17 | 토레이 밧데리 세퍼레이터 필름 고도 가이샤 | Microporous membranes and methods for making and using such membranes |
JP4993504B2 (en) * | 2008-04-02 | 2012-08-08 | 三井・デュポンポリケミカル株式会社 | Laminate sheet for solar cell and solar cell module using the same |
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