A digital pressure canner and related methods of operation that provide for improved safety and consistency during a food canning process by reducing temperature over and undershoot. The digital pressure canner includes a digital control operating with inputs from digital sensors to accurately control the canning temperature during the canning process. By reducing over and undershoot of canning temperatures, foods within the pressure canner are maintained at temperatures sufficient to kill any bacteria or microorganisms for the entire canning cycle. In order to verify operation of the digital canner at sufficient canning temperatures, mechanical safety devices, for example, a pressure relief valve can be utilized in conjunction with digital controllers and sensors to provide audible and visual feedback to a user during the canning process.

Heart of palm may be harvested from palm trees as a source of food. The core of a heart of palm heart is more desirable than the base of the palm heart due to its more favorable characteristics, resulting in under-utilization and waste of the base. The base and core may be processed in ways that advantageously utilize the base and overcome differences in density and inherent taste properties between the two sections. In an example, the base is treated with a cleaning solution and pieces are formed from the base. In this example, the pieces are immersed in an acid solution and packaged in an oxygen-impermeable packaging medium. The resulting heart of palm base pieces have favorable taste and mouthfeel and the pieces derived from the base are indistinguishable from pieces derived from the core.

A digital pressure canner and related methods of operation that provide for improved safety and consistency during a food canning process by reducing temperature over and undershoot. The digital pressure canner includes a digital control operating with inputs from digital sensors to accurately control the canning temperature during the canning process. By reducing over and undershoot of canning temperatures, foods within the pressure canner are maintained at temperatures sufficient to kill any bacteria or microorganisms for the entire canning cycle. In order to verify operation of the digital canner at sufficient canning temperatures, mechanical safety devices, for example, a pressure relief valve can be utilized in conjunction with digital controllers and sensors to provide audible and visual feedback to a user during the canning process.

A container includes a metal end applied and sealed to an all-thermoplastic container body by a crimp-seaming or double-seaming operation. The metal end has an outer curl joined to a chuck wall that extends down from the curl. One or both of the inner surface of the container side wall and the outer surface of the chuck wall has/have a heat-sealable material thereon. The metal end is crimp-seamed or double-seamed to the container body and the heat-sealable material(s) are heated to soften or melt such that the interface between the chuck wall and the side wall is fused. The interface is oriented along a direction relative to internal pressure exerted on the metal end such that stress on the interface caused by the internal pressure is predominantly shear stress.

The present invention relates to a vacuum-packed coconut, a preparation method thereof and a ready-to-drink trimmed coconut. The preparation method comprises the following steps: removing a shell of a fresh coconut to obtain a peeled coconut; letting the peeled coconut stand-still at room temperature for at least 10 hours to obtain a still-stood coconut; heating the still-stood coconut with a fluid at a temperature from 70 to 110? C. for 15 minutes to 40 minutes to obtain a fluid-heated coconut; and putting the fluid-heated coconut into a packing bag and then vacuuming the packing bag to obtain a vacuum-packed coconut. The advantages of the present invention include no air-pollution, stable quality, hygiene and prolonged storage period of the coconut products while maintaining the rich flavor of traditional roasted coconut.

The present invention relates to a vacuum-packed coconut, a preparation method thereof and a ready-to-drink trimmed coconut. The preparation method comprises the following steps: removing a shell of a fresh coconut to obtain a peeled coconut; letting the peeled coconut stand-still at room temperature for at least 10 hours to obtain a still-stood coconut; heating the still-stood coconut with a fluid at a temperature from 70 to 110? C. for 15 minutes to 40 minutes to obtain a fluid-heated coconut; and putting the fluid-heated coconut into a packing bag and then vacuuming the packing bag to obtain a vacuum-packed coconut. The advantages of the present invention include no air-pollution, stable quality, hygiene and prolonged storage period of the coconut products while maintaining the rich flavor of traditional roasted coconut.

A container includes a metal end applied and sealed to an all-thermoplastic container body by a crimp-seaming or double-seaming operation. The metal end has an outer curl joined to a chuck wall that extends down from the curl. One or both of the inner surface of the container side wall and the outer surface of the chuck wall has/have a heat-sealable material thereon. The metal end is crimp-seamed or double-seamed to the container body and the heat-sealable material(s) are heated to soften or melt such that the interface between the chuck wall and the side wall is fused. The interface is oriented along a direction relative to internal pressure exerted on the metal end such that stress on the interface caused by the internal pressure is predominantly shear stress.

The present disclosure provides methods for manufacturing a shelf-stable food product. In a general embodiment, the methods include acoustically mixing the food product with an acoustic mixing device during thermal processing of the food product. The methods of the present disclosure provide several advantages including, but not limited to, rapid achievement of a uniform temperature distribution during thermal processing, retention of nutrient content and organoleptic properties of the food product, and retention of particle integrity in the food product during and after mixing.

A container includes a metal end applied and sealed to an all-thermoplastic container body by a crimp-seaming or double-seaming operation. The metal end has an outer curl joined to a chuck wall that extends down from the curl. One or both of the inner surface of the container side wall and the outer surface of the chuck wall has/have a heat-sealable material thereon. The metal end is crimp-seamed or double-seamed to the container body and the heat-sealable material(s) are heated to soften or melt such that the interface between the chuck wall and the side wall is fused. The interface is oriented along a direction relative to internal pressure exerted on the metal end such that stress on the interface caused by the internal pressure is predominantly shear stress.

A digital pressure canner and related methods of operation that provide for improved safety and consistency during a food canning process by reducing temperature over and undershoot. The digital pressure canner includes a digital control operating with inputs from digital sensors to accurately control the canning temperature during the canning process. By reducing over and undershoot of canning temperatures, foods within the pressure canner are maintained at temperatures sufficient to kill any bacteria or microorganisms for the entire canning cycle. In order to verify operation of the digital canner at sufficient canning temperatures, mechanical safety devices, for example, a pressure relief valve can be utilized in conjunction with digital controllers and sensors to provide audible and visual feedback to a user during the canning process.