41 |
Process of making reinforced parper boxes. |
US17694017 |
1917-06-26 |
US1258294A |
1918-03-05 |
WRIGHT JACOB P; CARLSON CARL A |
|
42 |
Method of making paper receptacles. |
US1914854689 |
1914-08-03 |
US1198596A |
1916-09-19 |
STRANGE JOHN |
|
43 |
Machine for making paper vessels. |
US1913748338 |
1913-02-14 |
US1158544A |
1915-11-02 |
NORMAN LIONEL |
|
44 |
Method of making up receptacles from cartons. |
US1914849322 |
1914-07-06 |
US1128710A |
1915-02-16 |
MILLER JAMES B |
|
45 |
Container. |
US1912735022 |
1912-12-05 |
US1106004A |
1914-08-04 |
SHEVLIN CHARLES W |
|
46 |
Process of making paper bottles. |
US1911663197 |
1911-12-01 |
US1083263A |
1913-12-30 |
WORMER JOHN R VAN |
|
47 |
Machine for setting up cartons and the like. |
US1908425215 |
1908-04-04 |
US1025880A |
1912-05-07 |
PETERS FRANK M |
|
48 |
Machine for manufacturing box-shells. |
US1907401296 |
1907-11-08 |
US915380A |
1909-03-16 |
PRIMBS GEORGE |
|
49 |
Box-forming machine. |
US1905249062 |
1905-03-08 |
US837325A |
1906-12-04 |
MITCHELL JAMES H |
|
50 |
Machine for lining eyeglass-cases. |
US1902111432 |
1902-06-12 |
US821901A |
1906-05-29 |
TIBBALS FRANK A |
|
51 |
Machine for making collapsible boxes. |
US1902130510 |
1902-11-08 |
US790157A |
1905-05-16 |
ROSE WILLIAM; ROSE HENRY |
|
52 |
Method of making paper boxes. |
US1903151496 |
1903-04-07 |
US737692A |
1903-09-01 |
ALGER JOSEPH |
|
53 |
Cell-case machine. |
US1897639009 |
1897-06-01 |
US659010A |
1900-10-02 |
WILLIAMS WILLIAM ERASTUS |
|
54 |
And william m |
US375264D |
|
US375264A |
1887-12-20 |
|
|
55 |
And eobeet t |
US281958D |
|
US281958A |
1883-07-24 |
|
|
56 |
Method of and means for making cell cases |
US276497D |
|
US276497A |
1883-04-24 |
|
|
57 |
Improvement in the manufacture of boxes |
US124997D |
|
US124997A |
1872-03-26 |
|
|
58 |
INSULATED CONTAINER |
US15436417 |
2017-02-17 |
US20170334622A1 |
2017-11-23 |
Robert W. Menzel, JR. |
An insulated container may include a rigid container surrounding an insulation layer formed from a post-industrial, pre-consumer card waste. The insulation layer may be characterized by a lack of any wrapping material. The insulation layer may be manufactured using a variety of converting processes including, carding, airlay, and needle punch to form a non-woven material for providing consistent density throughout the insulation layer. The insulation layer may include a natural fiber lamination layer on an outer surface of the insulation layer. The insulation layer may be biodegradable in an anaerobic environment. |
59 |
REINFORCED PACKAGE |
US15630061 |
2017-06-22 |
US20170283111A1 |
2017-10-05 |
Raymond S. Kastanek |
A reinforced package comprising a carton comprising a plurality of panels that can comprise a first side panel connected to a front panel along a first fold line, a back panel connected to the first side panel along a second fold line, and a second side panel connected to the front and/or back panels. The reinforced package further can comprise a bag that can have an at least partially open end, an at least partially closed end, and an interior space. The carton can be positionable in non-erect and erect positions, and the carton can be configured to support the bag in the erect position. The first and second side panels can comprise retention features for at least partially retaining the carton in the erect position, and the retention features can comprise at least a V-shaped fold line extending in the first side panel from the first fold line. |
60 |
Process for manufacturing a heat insulation container |
US14698508 |
2015-04-28 |
US09387642B2 |
2016-07-12 |
Sheng-Shu Chang; Hung-Ying Su |
A process for manufacturing a heat insulation container mainly includes preparing a coating material by mixing a binder and a thermo-expandable powder, coating such coating material on a surface of a container and then heating the container to foam the coated material after the container is shaped. The foamed coating material is therefore provides the container with heat insulation property. The thermo-expandable powder consists of a plurality of thermo-expandable microcapsules, each of which consists of a thermoplastic polymer shell and a solvent wrapped by the thermoplastic polymer shell. To obtain a smooth surface, the soften point of the binder is required to be lower than the boiling point of the solvent. |