A device for preserving beverages with a measuring device is provided which is suitable and intended to determine a flow rate of a liquid flowing through a beverage line, and with a pump device which conveys a preservative, in particular dialkyl dicarbonate, into the beverage line, into the beverage line, the pump device being controllable as a function of a flow rate determined by the measuring device, the device having a venting device for venting the pump device, wherein the venting device has a valve device.

A device for preserving beverages with a measuring device is provided which is suitable and intended to determine a flow rate of a liquid flowing through a beverage line, and with a pump device which conveys a preservative, in particular dialkyl dicarbonate, into the beverage line, into the beverage line, the pump device being controllable as a function of a flow rate determined by the measuring device, the device having a venting device for venting the pump device, wherein the venting device has a valve device.

Embodiments of the present disclosure provide an auger dip apparatus for the application of antimicrobial solution to raw food. Embodiments of the present disclosure may use an auger as a single moving part to move the food work pieces through the application area for antimicrobial solution. Embodiments of the present disclosure are simple with only one moving auger part to move the food pieces, and the bearing for the moving part, supporting the shaft of the auger, may be configured to be outside of the cabinet with the reservoir of the antimicrobial solution, so that the bearing is not in contact with the antimicrobial solution. This provides for less maintenance and downtime, particularly unscheduled downtime, than a system using more complicated exposed parts. The present disclosure also permits a more compact and lighter configuration for an assembled application unit.

A baking production system for control of preservative concentration during production of baked products includes a preservative control system, including a preservative control unit, a flow control valve, a flow meter, first and second conductive probes, first and second acidity sensors, a metering pump, a water mixer, a temperature sensor, a moisture sensor, which is configured to mix the water with the preservative solution, thereby creating a water preservative mixture; and a production line, including a dough mixer, which is configured to receive a baking mixture and mix the baking mixture with the water preservative mixture, thereby creating a dough. Also disclosed is a method for preservative concentration control, including calculating water preservative concentration, optimizing preservative solution flow, calculating dough preservative concentration, and optimizing source water flow.

A baking production system for control of preservative concentration during production of baked products includes a preservative control system, including a preservative control unit, a flow control valve, a flow meter, first and second conductive probes, first and second acidity sensors, a metering pump, a water mixer, a temperature sensor, a moisture sensor, which is configured to mix the water with the preservative solution, thereby creating a water preservative mixture; and a production line, including a dough mixer, which is configured to receive a baking mixture and mix the baking mixture with the water preservative mixture, thereby creating a dough. Also disclosed is a method for preservative concentration control, including calculating water preservative concentration, optimizing preservative solution flow, calculating dough preservative concentration, and optimizing source water flow.

Embodiments of the present disclosure relate generally to systems and methods for combing ozone and water to deliver ozonated water in a rinse stream. The ozone rain pan finds particular use for rinsing food products traveling along a conveyor line with ozonated water.

A capture unit for use with an antimicrobial application unit may include an upstream filter and a downstream filter. The upstream filter may be positioned to receive effluent from the application unit and to filter solid components from the effluent. The resultant upstream effluent filtrate may then be passed downstream to the downstream filter. The downstream filter may be used to filter an antimicrobial component from the upstream effluent filtrate and the resultant downstream effluent filtrate may be suitable for disposal as wastewater discharge. The antimicrobial is preferably a quaternary ammonium compound, is more preferably an alkylpyridinium chloride, and is most preferably cetylpyridinium chloride.

A method for sanitizing food products on a production line (201), and a production line (100) for processing food products (103), comprising: a first processing enclosure (101) and a second processing enclosure (102) and a conveyor system (103) configured to move a food product through the first processing enclosure (101) and onwards through the second processing enclosure (102). The first processing enclosure (101) is coupled to a gas supply system (113) delivering a flow of gas at a gas temperature above 70 degrees Celsius via an orifice (113; 114) to generate a first processing atmosphere within the first processing enclosure (101) exposing at least a portion of the surface of the food products, while travelling through the first processing enclosure, to a first processing temperature (Ts) which is above 60 degrees Celsius. The second processing enclosure (102) is configured with an atomizing nozzle (106; 107) to deliver a spray of a supply of an antimicrobial chemical agent (123) towards the food products (103) travelling through the second processing enclosure.

A method for sanitizing food products on a production line (201), and a production line (100) for processing food products (103), comprising: a first processing enclosure (101) and a second processing enclosure (102) and a conveyor system (103) configured to move a food product through the first processing enclosure (101) and onwards through the second processing enclosure (102). The first processing enclosure (101) is coupled to a gas supply system (113) delivering a flow of gas at a gas temperature above 70 degrees Celsius via an orifice (113; 114) to generate a first processing atmosphere within the first processing enclosure (101) exposing at least a portion of the surface of the food products, while travelling through the first processing enclosure, to a first processing temperature (Ts) which is above 60 degrees Celsius. The second processing enclosure (102) is configured with an atomizing nozzle (106; 107) to deliver a spray of a supply of an antimicrobial chemical agent (123) towards the food products (103) travelling through the second processing enclosure.

The present invention relates an aqueous ozone disinfection system. An aqueous ozone generator receives water and an electrochemical medium catalyst that are combined forming a mixture. An electrochemical generator includes an ion exchange material and is integrated into the aqueous ozone generator. The electrochemical generator receives the mixture, and generates from the mixture an ozonated concentrate liquid. An electrochemical medium catalyst governor regulates the ratiometric mixture of amount of the electrochemical medium catalyst in the water, controlling the conductivity of the water, within a desired conductivity range, enhancing the electrochemical production of aqueous ozone by the electrochemical generator. And, a flow governor regulates an aqueous ozone production dwell time of the mixture through the electrochemical generator, controlling an ozone concentration level of the ozonated concentrate liquid within a desired ozone concentration range.