Microporous polyolefin film with improved meltdown property and preparing method thereof

Abstract

The present invention is related to microporous polyolefin films that may be used for battery separators and the methods of manufacturing the same. These microporous polyolefin films are characterized by being manufactured in a method comprising the steps of melt-extruding a composition, comprised of 20-50 weight % of a resin composition, comprised of 90-98 weight % of polyethylene (Component I) having a weight average molecular weight of 2×105˜4×105 and less than 5 weight % of molecules of which molecular weight is less than 1×104 and less than 5 weight % of molecules of which molecular weight is greater than 1×106, and 2-10 weight % of polypropylene (Component II) of which weight average molecular weight is 3.0×104˜8.0×105 and the peak of the melting point is higher than 145° C., and 80-50 weight % of a diluent (Component III), to mold in the form of sheets; stretching the above sheets to the form of films; extracting the diluent from the above films; and heat-setting the above films. They are also characterized by having a puncture strength of greater than 0.14 N/μm, Darcy's permeability constant of greater than 1.5×10−5 Darcy, shut-down temperature of microporous films of lower than 140° C., and melt-down temperature of higher than 160° C. They can enhance the performance and stability of batteries using them as well as the productivity of microporous films owing to their high thermal stability and superior extrusion compoundability and physical properties.

Description

Claims

1. A method of manufacturing microporous polyolefin films having a puncture strength greater than 0.14 N/μm, Darcy's permeability constant greater than 1.5×10−5 Darcy, shut-down temperature lower than 140° C., and melt-down temperature higher than 160° C. comprising the steps of: melt-extruding a composition, comprised of 20-50 weight % of a resin composition, comprised of 90-98 weight % of polyethylene (Component I) having a weight average molecular weight of 2×105˜4×105 and less than 5 weight % of molecules of which molecular weight is less than 1×104 and less than 5 weight % of molecules of which molecular weight is greater than 1×106, and 2-10 weight % of polypropylene (Component II) of which weight average molecular weight is 3.0×104˜8.0×105 and the peak of the melting point is higher than 145° C., and 80-50 weight % of a diluent (Component III), to mold in the form of sheets;stretching said sheets to mold in the form of films;extracting said diluent from said films; andheat-setting said films.

2. Microporous polyolefin films in claim 1, characterized by that said microporous polyolefin films have a weight average molecular weight of 2.0×105˜4.5×105 and the peak of the melting point of higher than 145° C.

3. The method of manufacturing microporous polyolefin films in claim 1, characterized by that said Component I is homopolyethylene or polyethylene co-polymers containing less than 20 weight % of alpha-olefin having 3-8 carbon atoms or their mixture as comonomers, or the mixture of said homopolyethylene and said polyethylene co-polymer.

4. The method of manufacturing microporous polyolefin films in claim 1, characterized by that said Component II is homopolypropylene; or random polypropylene containing ethylene or alpha-olefin having 3-8 carbon atoms or the mixture of said ethylene and alpha-olefin as comonomers; or polypropylene containing polypropylene copolymers containing ethylene or alpha-olefin having 3-8 carbon atoms or their mixture of said ethylene and alpha-olefin as comonomers; or the mixture of said homopolypropylene, said random polypropylene, and said polypropylene, which is a polypropylene having the peak of the melting point higher than 145° C.

5. The method of manufacturing microporous polyolefin films in claim 1, characterized by that the ratio of said Component I and said Component 11 is 95-97 weight % to 3-5 weight %.

6. The method of manufacturing microporous polyolefin films in claim 1, characterized by that said Component III is one or more components selected from aliphatic or cyclic hydrocarbons such as nonane, decane, decalin, paraffin oil, etc.; phthalic acid esters such as dibutyl phthalate, dioctyl phthalate, etc.; aromatic ethers such as diphenyl ether, etc.; fatty acids having 10 to 20 carbon atoms such as stearic acid, oleic acid, linoleic acid, linolenic acid, etc.; fatty acid alcohols having 10 to 20 carbon atoms such as stearic acid alcohol, oleic acid alcohol, etc.; and one or more fatty acid esters in which one or more fatty acids selected from saturated and unsaturated fatty acids having 4 to 26 carbon atoms in the fatty acid group such as palmitic acid mono-, di-, or tri-ester, stearic acid mono-, di-, or tri-ester, oleic acid mono-, di-, or tri-ester, linoleic acid mono-, di-, or tri-ester, etc. are ester-bonded with alcohols having 1 to 8 hydroxy radicals and 1 to 10 carbon atoms.

7. The method of manufacturing microporous polyolefin films in claim 1, characterized by that said step of stretching is done within a temperature range at which 30-80 weight % of the crystal portion of said Component I is molten in the machine and transverse directions greater than 3 times each at the total stretching ratio of 25-50 times.

8. Microporous polyolefin films manufactured according to said method of manufacturing in claims 1.

9. Microporous polyolefin films manufactured according to said method of manufacturing in claim 2.

10. Microporous polyolefin films manufactured according to said method of manufacturing in claim 3.

11. Microporous polyolefin films manufactured according to said method of manufacturing in claim 4.

12. Microporous polyolefin films manufactured according to said method of manufacturing in claim 5.

13. Microporous polyolefin films manufactured according to said method of manufacturing in claim 6.

14. Microporous polyolefin films manufactured according to said method of manufacturing in claim 7.