A packaging material for fruits and vegetables contains cellulose acylate having an acyl group. The cellulose acylate is cellulose acylate in which the hydroxy group of cellulose is esterified with a carboxylic acid, and has an acyl group. In the cellulose acylate of the packaging material for fruits and vegetable, an acyl group substitution degree, which is a rate of esterification of the hydroxy group of cellulose with a carboxylic acid, is within a range of from 2.00 to 2.97.

A filtration system is arranged to safely vent a storage room into which a fog mixture is introduced. Venting the storage room reduces and/or prevents a substantial increase in the internal pressure of the storage room. To control the pressure differential between the storage room and the ambient air pressure, a venting manifold with an in-line duct fan is used, for example, to exhaust storage room air into the atmosphere. The exhausted storage room air is filtered to reduce the exfiltration of chemicals and/or other contaminants from the environmentally sealed storage room.

A filtration system is arranged to safely vent a storage room into which a fog mixture is introduced. Venting the storage room reduces and/or prevents a substantial increase in the internal pressure of the storage room. To control the pressure differential between the storage room and the ambient air pressure, a venting manifold with an in-line duct fan is used, for example, to exhaust storage room air into the atmosphere. The exhausted storage room air is filtered to reduce the exfiltration of chemicals and/or other contaminants from the environmentally sealed storage room.

Examples provide a fruit ripening rack having a plurality of chambers for on-site produce ripening at a retail location. A controller component generates predicted demand for ripened fruit on a selected date at a selected location based on transaction history data and/or seasonal demand. The controller component calculates the quantity of fruit based on the predicted demand. The controller component determines conditions within each chamber to accelerate ripening of the calculated quantity of one or more types of fruit to one or more selected levels of ripeness on the selected date. The conditions include amount of ethylene gas in each chamber, length of exposure to the ethylene gas, temperature inside the chamber and/or humidity level inside the chamber. The fruit ripening rack controls internal conditions within each chamber to provide variable fruit ripening in accordance with per-chamber configurations to satisfy predicted daily demand at the selected location.

Examples provide a fruit ripening rack having a plurality of chambers for on-site produce ripening at a retail location. A controller component generates predicted demand for ripened fruit on a selected date at a selected location based on transaction history data and/or seasonal demand. The controller component calculates the quantity of fruit based on the predicted demand. The controller component determines conditions within each chamber to accelerate ripening of the calculated quantity of one or more types of fruit to one or more selected levels of ripeness on the selected date. The conditions include amount of ethylene gas in each chamber, length of exposure to the ethylene gas, temperature inside the chamber and/or humidity level inside the chamber. The fruit ripening rack controls internal conditions within each chamber to provide variable fruit ripening in accordance with per-chamber configurations to satisfy predicted daily demand at the selected location.

An inspection apparatus includes a container, a detector, and a controller. The container stores a specimen. In accordance with an inspection operation, the detector detects a substance emitted by the specimen stored in the container. The controller judges a quality of the specimen on the basis of the substance detected by the detector.

An inspection apparatus includes a container, a detector, and a controller. The container stores a specimen. In accordance with an inspection operation, the detector detects a substance emitted by the specimen stored in the container. The controller judges a quality of the specimen on the basis of the substance detected by the detector.

The present invention is direct to an edible composition in which fruit, vegetables and/or nuts, in conjunction with a hydrocolloid, are treated with pressure and/or heat to form an edible composition that is dimensionally stable, ambient stable for at least 12 months, has a moisture content greater than 50 wt. %, has a pH less than 4.5, has a water activity greater than 0.5, is commercially sterile, is free of artificial flavors, has a solids content greater than 10 wt. %, and does not exhibit syneresis. Also provided is a method for preparation of the edible composition.

The present invention is direct to an edible composition in which fruit, vegetables and/or nuts, in conjunction with a hydrocolloid, are treated with pressure and/or heat to form an edible composition that is dimensionally stable, ambient stable for at least 12 months, has a moisture content greater than 50 wt. %, has a pH less than 4.5, has a water activity greater than 0.5, is commercially sterile, is free of artificial flavors, has a solids content greater than 10 wt. %, and does not exhibit syneresis. Also provided is a method for preparation of the edible composition.

Disclosed are embodiments of a composition including propanoic acid, a C.sub.4 acid salt, and a component selected from a C.sub.2-C.sub.5 acid ester and a C.sub.2-C.sub.5 aldehyde and combinations thereof. The composition is provided in an aqueous medium. Each of the propanoic acid and the C.sub.4 acid salt are independently present in an amount at least partially sufficient to provide to said composition a pH greater than about 4.4.