A method of making a texture-coated and/or insulation coated container from a flat paperboard blank in which a heat-hardenable liquid polymeric binder texturizing and or insulating agent coating mixture is applied to one surface of the blank in a pattern of covered and open areas. This coating mixtu
A method of making a texture-coated and/or insulation coated container from a flat paperboard blank in which a heat-hardenable liquid polymeric binder texturizing and or insulating agent coating mixture is applied to one surface of the blank in a pattern of covered and open areas. This coating mixture is subjected to heat to cure the polymeric binder and expand the texturizing and/or insulating agent, optionally treated with moisture, and optionally heated to form the blank into the shape of a container, and the container produced by this method. The containers such as cups, plates, etc., are useful in food service. These containers have a coefficient of static friction which is about 0.2 to 2.0 and over and a kinetic coefficient of friction which is about 0.22 to 1.5.
대표청구항▼
A method of making a texture-coated and/or insulation coated container from a flat paperboard blank in which a heat-hardenable liquid polymeric binder texturizing and or insulating agent coating mixture is applied to one surface of the blank in a pattern of covered and open areas. This coating mixtu
A method of making a texture-coated and/or insulation coated container from a flat paperboard blank in which a heat-hardenable liquid polymeric binder texturizing and or insulating agent coating mixture is applied to one surface of the blank in a pattern of covered and open areas. This coating mixture is subjected to heat to cure the polymeric binder and expand the texturizing and/or insulating agent, optionally treated with moisture, and optionally heated to form the blank into the shape of a container, and the container produced by this method. The containers such as cups, plates, etc., are useful in food service. These containers have a coefficient of static friction which is about 0.2 to 2.0 and over and a kinetic coefficient of friction which is about 0.22 to 1.5. er is conducted for heating by absorption of heat therefrom into the contaminants; and condenser means connected to the vacuum pump means for condensation of the water vapor by cooling in response to transfer of heat therefrom to provide a condensate of the water vapor.4. A system for processing incoming wastewater to obtain therefrom an overboard discharge of contaminant free condensate, comprising: heat exchange means for preheating the wastewater; a flash chamber having upper and bottom sections; orifice means connecting the heat exchange means to the flash chamber for flashing conversion of the wastewater preheated in the heat exchange means into water vapor rising into the upper section of the flash chamber while contaminants are deposited into the bottom section thereof; filter means within the flash chamber for limiting extraction from the rising water vapor to a condensate within the upper section of the flash chamber; tank means operatively connected to the flash chamber for collecting the condensate extracted through the filtering means; pump means connected to the tank means for respectively storing the contaminants and effecting said overboard discharge; said pump means including: a vacuum pump connected to the flash chamber for withdrawal of the rising water vapor from the upper section thereof to establish the vacuum pressure therein inducing said rise of the water vapor; and trough means within the flash chamber for collecting liquefied water vapor separated from the rising water vapor within the upper section to maintain said vacuum pressure therein. 5. A system for processing incoming wastewater to obtain therefrom an overboard discharge of contaminant free condensate, comprising: heat exchange means for preheating the wastewater; a flash chamber having upper and bottom sections; orifice means connecting the heat exchange means to the flash chamber for flashing conversion of the wastewater preheated in the heat exchange means into water vapor rising into the upper section of the flash chamber while contaminants are deposited into the bottom section thereof; filter means within the flash chamber for limiting extraction from the rising water vapor to a condensate within the upper section of the flash chamber; tank means operatively connected to the flash chamber for collecting the condensate extracted through the filtering means; and pump means connected to the tank means for respectively storing the contaminants and effecting said overboard discharge including: a vacuum pump connected to the flash chamber for withdrawal of the rising water vapor from the upper section thereof to establish the vacuum pressure therein inducing said rise of the water vapor; and trough means within the flash chamber for collecting liquefied water vapor separated from the rising water vapor within the upper section to maintain said vacuum pressure therein; and cooling means connected to the vacuum pump for condensing the water vapor received therefrom in a superheated and compressed condition into the condensate. 6. The system as defined in claim 5, wherein said cooling means comprises condenser means connected to the vacuum pump for withdrawal of heat from the water vapor in the superheated and compressed condition; and heat absorber means connected to the condenser means.7. The system as defined in claim 6, including: pressure responsive control means connected to said pump means for regulating operation thereof to limit quantities of the condensate and the contaminants collected within the tank means.8. The system as defined in claim 7, including; a holding tank from which the incoming wastewater is derived; monitoring means connected to the pump means for limiting the overboard discharge to an oil concentrate portion of the collected condensate; and means for returning an oil-reduced content portion of the condensate from the monitoring means to the holding tank. ng an opaque film or a semi-transmission film on a transparent substrate, said method comprising a step of: forming said opaque film or said semi-transmission film onto the substrate by irradiating the substrate with anion generated by an ion generator separately disposed in a film formation chamber during the deposition of the opaque film or the semi-transmission film on the transparent substrate by a sputtering method. 2. The method claimed in claim 1, wherein said step comprises: controlling a film stress of the opaque film or semi-transmission film formed on the substrate; defining (a warp amount of the substrate after film formation)−(a warp amount of the substrate before the film formation)=(a warp amount of the substrate generated by the film formation); and suppressing the warp amount of the substrate generated by the film formation to ±0.1 &mgr;m or less. 3. The method claimed in claim 1, wherein said step comprises: directly introducing an inert gas onto the ion generator from the outside of the film formation chamber; and ionizing said inert gas by the ion generator to irradiate the substrate with the ion. 4. The method claimed in claim 1, wherein said step comprises: directly introducing a reactive gas into the ion generator from the outside of the film formation chamber; and ionizing said reactive gas by the ion generator and irradiating the substrate with the ion. 5. A method of reducing a stress of a film formed on a substrate, comprising the steps of: disposing an ion generator in a chamber together with the substrate; and irradiating, onto the substrate during depositing the film, an ion generated by an ion generator to relax the stress in the film. 6. The method claimed in claim 5, further comprising the steps of: measuring a warp of the substrate to define a warp amount; calculating the stress on the basis of the warp amount; and adjusting an irradiation condition with reference to the calculated stress so as to keep the stress into a predetermined range. 7. The method claimed in claim 6, wherein the predetermined range falls within ±0.1 &mgr;m. silient fibrous insulation blanket that form separable resilient fibrous insulation blanket sections in the faced pre-cut resilient fibrous insulation blanket and the facing is separable along each of the one or more longitudinally extending series of cuts and separable connectors so that the faced pre-cut resilient fibrous insulation blanket can be handled and installed as a unit or separated by hand, along any of the one or more longitudinally extending series of cuts and separable connectors, into faced resilient fibrous insulation blanket sections having widths less than a width of the faced pre-cut resilient fibrous insulation blanket, comprising: providing an uncut resilient fibrous insulation blanket having a width; making at least one longitudinally extending partial cut in the uncut resilient fibrous insulation blanket to form a partially cut resilient fibrous insulation blanket having a plurality of resilient fibrous insulation blankets, including a first resilient fibrous insulation blanket, with widths less than the width of the uncut resilient fibrous insulation blanket the partial cut being made in a major surface of the uncut resilient fibrous insulation blanket that forms the first major surface of the first resilient fibrous insulation blanket to relieve lateral stresses in the first resilient fibrous insulation blanket when the first resilient fibrous insulation blanket is compression-cut; the first resilient fibrous insulation blanket having a substantially planar first major surface, and a substantially planar second major surface and lateral edges; subsequent to making the partially cut resilient fibrous insulation blanket, passing the first resilient fibrous insulation blanket through a compression-cutting assembly and between a first circular compression-cutting blade and an anvil of the compression-cutting assembly; the compression-cutting blade having a series of compression-cutting teeth separated by a series of notches; compression-cutting the first resilient fibrous insulation blanket between the circular compression-cutting blade and the anvil to form a first longitudinally extending series cuts and separable connectors in the first resilient fibrous insulation blanket intermediate the lateral edges of the first resilient fibrous insulation blanket and two separable resilient fibrous insulation blanket sections in the first resilient fibrous insulation blanket; the circular compression-cutting blade penetrating the first resilient fibrous insulation blanket from the first major surface of the first resilient fibrous insulation blanket, the anvil supporting the second major surface of the first resilient fibrous insulation blanket, and the compression-cutting of the first resilient fibrous insulation blanket temporarily depressing the first major surface of the first resilient fibrous insulation blanket along the series of cuts and separable connectors so that the first major surface of the first resilient fibrous insulation blanket is temporarily no longer substantially planar; providing a facing with a first longitudinally extending separable means separable longitudinally by hand intermediate lateral edges of the facing; completely severing the partially cut resilient fibrous insulation blanket at the partial cut in the partially cut resilient fibrous insulation blanket subsequent to compression-cutting the first resilient fibrous insulation blanket and prior to applying and adhering the facing to the second major surface of the first resilient fibrous insulation blanket; and before the first major surface of the first resilient fibrous insulation blanket has recovered to the substantially planar condition, applying and adhering the facing to the second major surface of the first resilient fibrous insulation blanket with the first longitudinally extending separable means of the facing substantially aligned with the first series of cuts and separable connectors in the first res ilient fibrous insulation blanket. 2. The method of making a faced pre-cut resilient fibrous insulation blanket according to claim 1, wherein: the uncut resilient fibrous insulation blanket is a glass fiber insulation blanket between 0.4 and 1.6 pcf; and the uncut resilient fibrous insulation blanket has a nominal thickness of at least 3 inches. 3. The method of making a faced pre-cut resilient fibrous insulation blanket according to claim 1, wherein: the first longitudinally extending separable means of the facing is a perforated line sealed with a bonding agent that bonds the facing to the second major surface of the pre-cut resilient fibrous insulation blanket so that the facing functions as a vapor barrier. 4. The method of making a faced pre-cut resilient fibrous insulation blanket according to claim 3, wherein: the facing includes a pair of longitudinally extending tabs that are separable along the perforated line. 5. The method of making a faced pre-cut resilient fibrous insulation blanket according to claim 1, wherein: the first resilient fibrous insulation blanket is passed between a plurality of laterally spaced circular compression-cutting blades, including the first circular compression-cutting blade, and the anvil in the compression-cutting assembly; and at least two laterally spaced apart longitudinally extending series of cuts and separable connectors, including the first series of cuts and separable connectors, are formed in the first resilient fibrous insulation blanket intermediate the lateral edges of the first resilient fibrous insulation blanket and at least three separable resilient fibrous insulation sections, including the two separable resilient fibrous insulation sections, are formed in the first resilient fibrous insulation blanket; and the facing has a plurality of longitudinally separable means, including the first longitudinally separable means, separable longitudinally by hand at laterally spaced apart locations across a width of the facing; and each of the longitudinally separable means is substantially aligned with one of the plurality of series of cuts and separable connectors in the first resilient fibrous insulation blanket. 6. The method of making a faced pre-cut resilient fibrous insulation blanket according to claim 5, wherein: the uncut resilient fibrous Insulation blanket is a glass fiber insulation blanket between 0.4 and 1.6 pcf; and the uncut resilient fibrous insulation blanket has a nominal thickness of at least 3 inches. 7. The method of making a faced pre-cut resilient fibrous insulation blanket according to claim 5, wherein: each of the longitudinally extending separable means of the facing is a perforated line sealed with a bonding agent that bonds the facing to the second major surface of the pre-cut resilient fibrous insulation blanket so that the facing functions as a vapor barrier. 8. The method of making a faced pre-cut resilient fibrous insulation blanket according to claim 7, wherein: the facing includes pairs of longitudinally extending tabs with each pair of tabs being separable along one of the perforated lines. 9. The method of making a faced pre-cut resilient fibrous insulation blanket according to claim 1, wherein: the uncut resilient fibrous insulation blanket is a glass fiber insulation blanket between 0.4 and 1.6 pcf; the uncut resilient fibrous insulation blanket has a nominal thickness of at least 3 inches; and the partial cut extends at least half way through a thickness of the uncut resilient fibrous insulation blanket. 10. The method of making a faced pre-cut resilient fibrous insulation blanket according to claim 1, wherein: the uncut resilient fibrous insulation blanket is a glass fiber insulation blanket between 0.4 and 1.6 pcf; the uncut resilient fibrous insulation blanket has a nominal thickness of at least 3 inches; and the partial cut extends to within 1½ inches of the second major surface of the uncut resilient fibrous insulat ion blanket. 11. A method of making a faced pre-cut resilient fibrous insulation blanket with a facing adhered to one major surface wherein the faced pre-cut resilient fibrous insulation blanket has one or more longitudinally extending series of cuts and separable connectors intermediate lateral edges of the faced pre-cut resilient fibrous insulation blanket that form separable resilient fibrous insulation blanket sections in the faced pre-cut resilient fibrous insulation blanket and the facing is separable along each of the one or more longitudinally extending series of cuts and separable connectors so that the faced pre-cut resilient fibrous insulation blanket can be handled and installed as a unit or separated by hand, along any of the one or more longitudinally extending series of cuts and separable connectors, into faced resilient fibrous insulation blanket sections having widths less than a width of the faced pre-cut resilient fibrous insulation blanket, comprising: providing an uncut resilient fibrous insulation blanket having a width; making at least one longitudinally extending cut in the uncut resilient fibrous insulation blanket to completely sever the uncut resilient fibrous insulation blanket, to form a plurality of resilient fibrous insulation blankets, including a first resilient fibrous insulation blanket, with widths less than the width of the uncut resilient fibrous insulation blanket, and to relieve lateral stresses in the first resilient fibrous insulation blanket when the first resilient fibrous insulation blanket is compression-cut; the first resilient fibrous insulation blanket having a substantially planar first major surface, a substantially planar second major surface, and lateral edges; subsequent to making the cut in the uncut resilient fibrous insulation blanket, passing the first resilient fibrous Insulation blanket through a compression-cutting assembly and between a first circular compression-cutting blade and an anvil of the compression-cutting assembly; the compression-cutting blade having a series of compression-cutting teeth separated by a series of notches; compression-cutting the first resilient fibrous insulation blanket between the circular compression-cutting blade and the anvil to form a first longitudinally extending series cuts and separable connectors in the first resilient fibrous insulation blanket intermediate the lateral edges of the first resilient fibrous insulation blanket and two separable resilient fibrous insulation blanket sections in the first resilient fibrous insulation blanket; the circular compression-cutting blade penetrating the first resilient fibrous insulation blanket from the first major surface of the first resilient fibrous insulation blanket, the anvil supporting the second major surface of the first resilient fibrous insulation blanket, and the compression-cutting of the first resilient fibrous insulation blanket temporarily depressing the first major surface of the first resilient fibrous insulation blanket along the series of cuts and separable connectors so that the first major surface of the first resilient fibrous insulation blanket is temporarily no longer substantially planar; providing a facing with a first longitudinally extending separable means separable longitudinally by hand intermediate lateral edges of the facing; and before the first major surface of the first resilient fibrous insulation blanket has recovered to the substantially planar condition, applying and adhering the facing to the second major surface of the first resilient fibrous insulation blanket with the first longitudinally extending separable means of the facing substantially aligned with the first series of cuts and separable connectors in the first resilient fibrous insulation blanket. 12. The method of making a faced pre-cut resilient fibrous insulation blanket according to claim 11, wherein: the uncut resilient fibrous insulation blanket is a glass fiber
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (26)
Erland Sandstrom ; Kenneth J. Shanton ; Dean Swoboda, Bulk enhanced paperboard and shaped products made therefrom.
Melber George E. (Buffalo NY) Oswald William A. (Darien IL) Wolinski Leon E. (Buffalo NY), Composition and process for drying and expanding microspheres.
Iioka Akira (Inzaimachi JPX), Method for producing a heat-insulating paper container from a paper coated or laminated with a thermoplastic synthetic r.
Nisser Henrik Gustaf Folke (Falun SW) Petersen Jorgen (Sundsvall SW) Porrvik Sten Erik (Sundsvall SW), Method for the preparation of paper containing plastic particles.
Self Robert W. (Mobile AL) Whillock Allan A. (Mobile AL), Method of making and using heat resistant resin coated paperboard product and product thereof.
Trokhan Paul D. (Hamilton OH) Boutilier Glenn D. (Blue Ash OH), Papermaking belt and method of making the same using differential light transmission techniques.
Konig Joachim (Odenthal DEX) Kopp Jurgen (Odenthal DEX) Hendricks Udo-Winfried (Odenthal DEX) Reiners Jurgen (Leverkusen DEX) Nowak Peter (Dormagen DEX), Process for fixing disruptive substances in papermaking.
Mohan, Krishna K; Goliber, Cynthia A; Hong, Yaoliang; Froass, Peter M; Young, Herbert; Anderson, Dennis W.; Faber, Richard D, Compositions containing expandable microspheres and an ionic compound as well as methods of making and using the same.
Mohan, Krishna K.; Goliber, Cynthia A.; Hong, Yaoliang; Froass, Peter M.; Young, Herbert; Anderson, Dennis W.; Faber, Richard D., Compositions containing expandable microspheres and an ionic compound, as well as methods of making and using the same.
Mohan, Krishna K; Goliber, Cynthia A; Hong, Yaoliang; Froass, Peter M; Young, Herbert; Anderson, Dennis W.; Faber, Richard D, Compositions containing expandable microspheres and an ionic compound, as well as methods of making and using the same.
Hong, Yaoliang; Mohan, Kosaraju Krishna; Dimonie, Victoria Laurentia; Fagan, Mark Edward; Klein, Andrew; Daniels, Eric Scott; Boyars, Brian; Froass, Peter M.; Anderson, Christopher D.; Sudol, Edward David, Expandable microspheres and methods of making and using the same.
Hong, Yaoliang; Mohan, Kosaraju Krishna; Froass, Peter M.; Fagan, Mark; Anderson, Christopher D.; Boyars, Brian; Daniels, Eric Scott; Dimonie, Victoria Laurentia; Sudol, Edward David; Klein, Andrew, Expandable microspheres and methods of making and using the same.
Dixit,Ajit S.; Mitchell,Melvin G.; Paris,Jeanette M.; Andersen,Mark J.; Huggins,Christy M., Formulation for achievement of oil and grease resistance and release paper properties.
Singh, Kapil M.; Anderson, Dennis W.; Froass, Peter M.; Hong, Yaoliang; Mohan, Kosaraju K.; Arnson, Thomas R.; Huang, Yan C., Paper substrates containing high surface sizing and low internal sizing and having high dimensional stability.
Singh, Kapil M.; Anderson, Dennis W.; Froass, Peter M.; Hong, Yaoliang; Mohan, Kosaraju Krishna; Arnson, Thomas R.; Huang, Yan C., Paper substrates containing high surface sizing and low internal sizing and having high dimensional stability.
Singh, Kapil M.; Anderson, Dennis W.; Froass, Peter M.; Hong, Yaoliang; Mohan, Krishna Kosaraju; Arnson, Thomas R.; Huang, Yan C., Paper substrates containing high surface sizing and low internal sizing and having high dimensional stability.
Swerin, Agne; Herman, Michael; Song, Jay C; Yang, Sen; Lee, Peter F; Bednarik, Ladislav, Paper with improved stiffness and bulk and method for making same.
Swerin, Agne; Song, Jay C.; Bednarik, Ladislav; Lee, Peter F.; Herman, Michael C.; Yang, Sen, Paper with improved stiffness and bulk and method for making same.
Theisen, John A.; Unruh, Bruce C.; Feit, Susan L.; Langton, David J.; Orlovsky, Michael A.; Weber, Mark J.; Blanz, John J.; Schultz, Lisa R., Treated paper product, combination food and treated paper product, and methods for manufacturing and using treated paper product.
Kipp, Michael D.; Pugh, Dilworth L.; Ridges, Michael D.; McCarvill, William T., Utility materials incorporating a microparticle matrix formed with a setting agent.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.