System and method for manufacturing cementitious boards with on-line void detection

What is claimed is: 1. A system for manufacturing a cementitious board, the cementitious board having a cementitious core interposed between a pair of cover sheets, the cementitious board having first and second edge segments, the cementitious core including a main portion and first and second edges, the main portion being laterally interposed between the first and second edges, the main portion being made from a main slurry, and the first and second edges being made from an edge slurry the edge slurry being relatively denser than the main slurry, the system comprising: a forming station, the forming station configured to form the cementitious board such that the cementitious board is within a predetermined thickness range; a conveyor, the conveyor configured to convey the cementitious board along a machine direction away from the forming station such that the first and second edge segments of the cementitious board extend along the machine direction and are disposed in lateral spaced relationship to each other along a cross-machine direction, the cross-machine direction being perpendicular to the machine direction; a thermal imaging device, the thermal imaging device disposed downstream of the forming station along the machine direction, the thermal imaging device being positioned relative to the conveyor and being configured to generate thermal image data corresponding to a portion of the cementitious board as the cementitious board is conveyed past the thermal imaging device, the thermal imaging device having a field of view with a cross-machine view distance measured along the cross-machine direction, the cross-machine view distance of the thermal imaging device configured such that the thermal image data includes thermal edge data for both the first and second edge segments of the portion of the cementitious board; a non-transitory, computer-readable medium, the non-transitory, computer-readable medium bearing a void detecting program; a processor, the processor in operable arrangement with the thermal imaging device to receive the thermal image data and in operable arrangement with the non-transitory, computer-readable medium, the processor configured to execute the void detecting program contained on the non-transitory, computer-readable medium; a cutting station, the cutting station disposed downstream of the forming station along the machine direction, the cutting station arranged with respect to the conveyor such that the conveyor carries the cementitious board past the cutting station, the cutting station including a knife configured to periodically cut the cementitious board along the cross-machine direction to define a series of board segments as the cementitious board moves along the machine direction past the cutting station, wherein the thermal imaging device is disposed along the machine direction between the forming station and the cutting station; wherein the void detecting program includes a thermal analysis module configured to analyze the thermal image data to identify each void defined within the portion of the cementitious board between the pair of cover sheets that is greater than a predetermined size, wherein the void detecting program is configured to track a lateral location of each identified void along the cross-machine direction relative to the first and second edge segments of the portion of the cementitious board, and wherein the void detecting program is configured to group each identified void into one of a first edge area, a second edge area, and a field area, the first edge area extending a predetermined distance from the first edge segment toward the second edge segment along the cross-machine direction, the second edge area extending a predetermined distance from the second edge segment toward the first edge segment along the cross-machine direction, and the field area laterally interposed between the first edge area and the second edge area along the cross-machine direction, the first edge area, the second edge area, and the field area each extending along the machine direction from a leading end to a trailing end of the portion of the cementitious board, the first and second edge area being configured to include respectively therein the first and second edges of the cementitious core. 2. The system for manufacturing according to claim 1 , wherein the thermal imaging device is positioned relative to the cementitious board and the field of view of the thermal imaging device is configured such that the cross-machine view distance of the thermal imaging device is greater than a cross-machine board distance of the portion of the cementitious board, the cross-machine board distance measured along the cross-machine direction between the first and second edge segments of the portion of the cementitious board, the thermal image data including at least one edge crop portion defined between one of first and second lateral thermogram edges extending along the machine direction and the first and second edge segments, respectively, of the portion of the cementitious board closest to said lateral thermogram edge, and wherein the void detecting program includes a digital thermogram sizing module configured to exclude each edge crop portion from the void detection analysis of the thermal image data. 3. The system for manufacturing according to claim 1 , wherein the thermal image data includes a temperature value for each of a plurality of digital pixels in the field of view, and the thermal analysis module of the void detecting program is configured to: compute an average temperature for a number of the temperature values corresponding to a set of the digital pixels covering an analyzed portion of the field of view, compare each temperature value in the set of the digital pixels with the average temperature, for each digital pixel in the set of the digital pixels, identify the digital pixel as a void pixel when the temperature value of the digital pixel is a predetermined amount less than the average temperature, group adjacent void pixels together to determine the size of a given void. 4. The system for manufacturing according to claim 1 , wherein the void detecting program is configured to: group each identified void into one of a number of different size ranges. 5. The system for manufacturing according to claim 1 , wherein the portion of the cementitious board comprises a first portion, the thermal image data of the first portion of the cementitious board comprises a first set of thermal image data, the system further comprising: a controller, the controller in operable arrangement with the thermal imaging device, the controller configured to selectively operate the thermal imaging device to generate a second set of thermal image data corresponding to a second portion of the cementitious board, the second portion of the cementitious board in offset longitudinal relationship with the first portion along the machine direction. 6. The system for manufacturing according to claim 5 , wherein the controller is configured to selectively operate the thermal imaging device to generate a series of digital thermograms of a number of consecutively-sequenced portions of the cementitious board as the cementitious board passes underneath the thermal imaging device, each portion of the cementitious board including a leading end and a trailing end, the leading end of each portion in spaced relationship to the respective trailing end along the machine direction, the leading end of each respective trailing portion of the consecutively-sequenced portions being substantially aligned with the trailing end of the respective leading portion of the consecutively-sequenced portions. 7. The system for manufacturing according to claim 1 , wherein the thermal imaging device is posit