Controlled blast cell cooling

What is claimed is: 1. A blast cell system, comprising: a plurality of bays that are spaced across the blast cell system, arranged to hold items to be cooled, wherein each bay of the plurality of bays has an entrance and an exit, and is separated from each other bay so as to prevent cross-flow of air from one bay to another bay of the plurality of bays; a plurality of louvers, each covering a different bay of the plurality of bays; one or more entrance sensors positioned at or near the entrance for each of the plurality of bays and one or more exit sensors positioned at or near the exit for each of the plurality of bays, wherein the one or more entrance sensors and the one or more exit sensors each include one or more of: pressure sensors, temperature sensors, or both, positioned to sense differential flow conditions between the entrance and the exit for each of the plurality of bays; and a controller programmed to modulate open-closed positions of each of the plurality of louvers separately from others of the plurality of louvers during the blast cell system's cooling process based on the differential flow conditions sensed by the one or more entrance sensors and the one or more exit sensors, wherein modulating the open-closed positions of each of the plurality of louvers allows for dynamic adjustment of different volumes of cooling air to flow through each respective bay of the plurality of bays during the cooling process. 2. The blast cell system of claim 1 , wherein a plurality of fans are in fluid communication with a single plenum that serves all of the plurality of bays. 3. The blast cell system of claim 1 , wherein a cross-sectional area of the plurality of bays is divided into an m×n grid, where m is a positive integer greater than one and n is a positive integer greater than one. 4. The blast cell system of claim 3 , wherein each bay of plurality of bays includes (a) one or more flow sensors to identify a volume of airflow through a respective bay of plurality of bays and (b) the one or more temperature sensors to identify a temperature of airflow through the respective bay of the plurality of bays, and the controller is programmed to control respective ones of the plurality of louvers so as to provide comparatively greater airflow, as determined based on the volume of airflow identified by the one or more flow sensors for each bay of the plurality of bays, to one or more bays of the plurality of bays that are indicated as having comparatively higher temperature airflows, identified by the one or more temperature sensors, than other bays of the plurality of bays. 5. The blast cell system of claim 4 , wherein the controller is programmed to provide air flow so as to minimize a time between which a first bay of items in the blast cell system have been fully frozen and a last bay of items in the blast cell system have been fully frozen for a given overall level of airflow through the blast cell system. 6. The blast cell system of claim 1 , wherein each bay of the plurality of bays is open from the entrance, where fans supply air to each bay of the plurality of bays, to the exit where air is returned to the fans, and wherein the plurality of louvers are located near the exit of each bay of the plurality of bays. 7. The blast cell system of claim 1 , wherein each bay of the plurality of bays is separated from each other bay of the plurality of bays by vertical panels. 8. The blast cell system of claim 7 , wherein each bay of the plurality of bays is separated from each other bay of the plurality of bays by horizontal panels that extend the substantial length of each bay of the plurality of bays. 9. The blast cell system of claim 1 , further comprising a movable air blockade arranged to selectively block blast cell system air flow from a selected plurality of bays while: permitting access to the selected plurality of bays from outside the blast cell system and permitting air flow to the plurality of bays other than the selected plurality of bays. 10. A method of operating a blast cell system, the method comprising: circulating cooling air with one or more cooling fans through a plurality of bays that are each laterally separated from adjacent the plurality of bays so that cross-flow of air between the plurality of bays is prevented, wherein each bay of the plurality of bays has an entrance and an exit; measuring, by one more entrance sensors positioned at or near the entrance for each bay of the plurality of bays and one or more exit sensors positioned at or near the exit for each bay of the plurality of bays, differential temperature, differential air pressure levels, or both in each bay of the plurality of bays, wherein the one more entrance sensors and the one more exit sensors each include one or more of: pressure sensors, temperature sensors, or both, positioned to sense differential flow conditions between the entrance and the exit for each bay of the plurality of bays; determining, from the measured differential air pressure levels, particular levels of the differential air pressure for each bay of the plurality of bays so as to achieve a desired cooling level; and modulating open-closed positions of a plurality of louvers associated with respective ones of the plurality of bays during the blast cell system's cooling process based on the differential flow conditions sensed by the one more entrance sensors and the one more exit sensors, wherein modulating the open-closed positions of each of the plurality of louvers allows for dynamic adjustment of air flow through each bay of the plurality of bays, wherein the plurality of louvers for a first bay of the plurality of bays are controlled separately from the plurality of louvers for others of the plurality of bays during the cooling process. 11. The method of claim 10 , wherein a plurality of fans are in fluid communication with a single plenum that serves all of the plurality of bays. 12. The method of claim 10 , wherein a cross-sectional area of the plurality of bays is divided into an m×n grid, where m is a positive integer greater than one and n is a positive integer greater than one, and each bay of the plurality of bays in the grid has a louver that is adjusted separately from each other bay of the plurality of bays in the grid. 13. The method of claim 12 , wherein each bay of the plurality of bays includes (a) one or more flow sensors that identify a volume of airflow through a respective bay of the plurality of bays and (b) the one or more temperature sensors that identify a temperature of airflow through the respective bay of the plurality of bays, and the method comprises employing a computer controller to control respective ones of the plurality of louvers so as to provide comparatively greater airflow, as determined based on the volume of airflow identified by the one or more flow sensors for each bay of the plurality of bays, to one or more bays of the plurality of bays that are indicated as having comparatively higher temperature airflows, identified by the one or more temperature sensors, than other sub-areas. 14. The method of claim 13 , wherein the computer controller provides air flow so as to minimize a time between which a first bay of items in the blast cell system have been fully frozen and a last bay of items in the blast cell system have been fully frozen for a given overall level of airflow through the blast cell system. 15. The method of claim 10 , wherein each bay of the plurality of bays is open from the entrance, where fans supply air to each bay of the plurality of bays, to the exit where air is returned to the fans, and wherein the plurality of