1. Field of the Invention
The present invention relates to a manufacturing line for gypsum boards, and in particular to a coating spray apparatus and method of using for a manufacturing line for gypsum boards.
2. Discussion of Related Art
In a conventional gypsum board manufacturing process, a slurry of gypsum is sandwiched between two layers of facing sheets. After the gypsum core sets, the core, together with the facing sheets, is cut into board lengths. The cut boards are then sent through a dryer to substantially dry the gypsum core.
According to WO 02/12144, it is known to apply a coating to one side of the board. WO 02/058902 teaches applying a coating to a wet gypsum board prior to drying the gypsum board. In addition, U.S. Pat. No. 6,663,979 teaches applying a coating to a gypsum board either before or after drying of the board.
However, the gypsum board manufacturing line may be used for making different types of boards. Some of the boards may be coated with coating equipment as discussed above, and some boards may not be coated.
Accordingly, it is an object of one embodiment of the present invention to provide a coating spray apparatus which can be pivoted from an operative position, wherein the spray apparatus is over the gypsum board manufacturing line to an inoperative position, wherein the spray apparatus is remote from the line and does not interfere with regular operations.
It is a further object of the present invention to provide a coating spray apparatus for a gypsum board manufacturing line that is able to apply the spray in a fine, easily controlled manner.
According to a first embodiment of the present invention, a manufacturing line for gypsum boards includes a conveyor for moving gypsum boards in a line; a spray arm having a pivot at one end thereof for supporting a spray arm in a pivotable manner; a base frame mounted adjacent the convey; a support for the pivot mounted on the base frame so that the spray arm can be pivoted from an operative position wherein the spray arm extends over the conveyor to an inoperative position; a plurality of spray nozzles arranged on the spray arm for spraying a coating on the gypsum boards on the conveyor; and a pump system on the base frame to deliver the coating to the plurality of spray nozzles.
According to another embodiment of the present invention, a spray arm for a manufacturing line for gypsum boards includes a support beam; a pivot at one end thereof for supporting the spray arm in a pivotable manner so that the spray arm can be pivoted at least about 90 degrees from an operative position to an inoperative position; and a plurality of spray nozzles arranged on the support beam for spraying a coating on gypsum boards, the plurality of nozzles arranged in clusters and the nozzles in each cluster are staggered so that at least some of the nozzles in each cluster are at different distances from the support beam with respect to each other.
According to another embodiment, a method according to the present invention of spraying a coating on a gypsum board on a gypsum board manufacturing line includes providing a spray arm having a plurality of nozzles attached thereto over the gypsum board manufacturing line; the plurality of nozzles are arranged in clusters and the nozzles in each cluster are staggered so that at least some of the nozzles in each cluster are at different distances from the spray arm with respect to each other, and the nozzles are further arranged such that the spray from each nozzle covers less than an entire width of the gypsum board on the line; emitting a coating from the spray nozzles such that a plurality of overlapping sprays are sprayed onto the gypsum board in succession; and wherein the nozzles are arranged such that a substantially uniform coating is applied to the board.
Turning attention to
In this embodiment, a spray arm 10 of the present invention is arranged above the conveyor assembly 42, prior to the boards 44, 46, 48, 50 reaching the dryer. The spray arm 10 is mounted to a skid or frame 14 in a pivotable manner so that the spray arm 10 can be pivoted at least 90 to 180 degrees from an inoperative position illustrated in solid lines to an operative position illustrated in dashed lines. As best seen in
The coating apparatus includes several components. For example, the skid 14 (
The skid 14 includes a plurality of pumps 28, each of which is driven by a respective pump motor 26. In the preferred embodiment, the pump motors 26 are air driven motors such that the speed of the output thereof can be controlled by the air pressure that is delivered to the pump motors 26. In the preferred embodiment, five pumps and pump motors are provided on the skid. However, only four are actually used for applying the coating. The fifth pump and pump motor are provided to serve as a back-up in the event that one of the four pumps fails. In a preferred embodiment, the pumps are manufactured by Graco.
A suction header 24 delivers a coating formula to each of the pumps 28 via respective hoses 34. The coating formula is delivered to the suction header 24 from pipe 80 (
A control air manifold 20 is also present on the skid 14 adjacent the pump motors 26. Separate hoses 30 connect the control air manifold 20 to the respective pump motors 26 to provide the motive force for the pump motors 26.
As can be best seen in
In a preferred embodiment, the nozzles or spray heads are manufactured by Graco. Various size nozzles have been tried, including #25, 27, 29, 31, 33, and 35. However, the #31 nozzle provides a spray with a width of about twelve inches, as it contacts the board, when the pump motor pressure is about 40 psi and the system pressure is about 2250 psi. At these parameters, about four gallons of coating per 1000 square feet is applied at the rate of about 2.25 gallons per minute. However, the present invention can be practiced with other combinations of nozzles, pressures, and spray widths.
At the right side of
Hose 80 delivers the coating formula from a storage tank 133 located off of the skid 14 to a low pressure pump 82, which pumps the coating formula to the suction header 24. The coating formula may be delivered directly to the suction header 24 through pipes 84 and 90. Alternatively, by the manipulation of the valve 85, pipe 84 may be shut off, and the coating formula may be delivered to pipe 90 through a filter 88 and pipe 86. Thus, by controlling the valves in and about the filter 88, the coating formula may be delivered either directly to the suction header 24 or may be filtered through filter 88 prior to delivery to the suction header 24. The pump 82 is driven by compressed air received from the control air manifold 20.
Another hose 78 is connected to pipe 90 and can be used to deliver unused coating formula back to the storage tank 133, which is illustrated in
At the top of
The control air from the control air delivery pipe 68 is used to turn the nozzles 54, 56, 58, 60 on and off. The air is controlled by a solenoid (not illustrated). The solenoid is controlled by a timer that is coordinated with the drive mechanism for rollers associated with the conveyor 42. Preferably, the timer controls the solenoid and nozzles such that the coating is only sprayed from the nozzles while there is a board below the nozzles, so as to avoid wasting the coating. However, during normal continuous runs, the pumps 28 continue to operate and pressure is maintained in the conduit 64 even when the nozzles are turned off between boards.
The nozzles 54, 56, 58, 60 are air-actuated spray heads. When pressurized air is delivered by the conduit 68 to the nozzles, the nozzles are opened allowing the coating formula and atomizing air to flow through the nozzles. When the pressure in the conduit 68 is dropped, e.g., to atmospheric pressure, the nozzles are closed.
In the lower right corner of
The coating formula in the tank 112 may be circulated or stirred by a propellor blade 127 located within the tank 112. In addition, a drain 125 at the bottom of the tank can be used to recirculate the coating formula by means of a pump 118 and plumbing 124 so that the coating formula can be removed from the bottom of the tank 112 and redelivered to the top of the tank 112 to recirculate or stir the coating formula.
In addition, bypass plumbing 122 can be provided so that the coating formula can be bypassed through a filter 120 during the recirculation process so that the coating formula may be filtered, while it is being recirculated. In addition, pipe 129 can be used to drain off or remove coating formula from the system.
Pipe 131, which is connected to the pump 118 via plumbing 124, is used to deliver the coating formula from the tank 112 to an intermediate tank 133 illustrated schematically. The intermediate tank 133 can be located adjacent the skid 14, or in any convenient location, preferably near the skid.
During the operation of the spray apparatus, the operating pressure from the air control manifold 20 to the pump motors 26 is preferably in the range of 30-40 psi. However, higher or lower pressures may be used, as desired.
Because the spray arm 10 is connected to the skid 14 with a pivot 12, the spray arm 10 can be moved into position over the board conveyor 42, or can be pivoted so that it is no longer over the board conveyor 42.
In addition, as set forth above, the skid 14 can be mounted on wheels 52. However, in an alternative embodiment, the skid 14 may be permanently fixed to the plant floor.
As illustrated in
Although only preferred embodiments are specifically illustrated and described herein, it will be appreciated that many modifications and variations of the present invention are possible in light of the above teachings and within the purview of the appended claims without departing from the spirit and intended scope of the invention.