Inlet Door Flood Gate Material Spreader

What is claimed is: 1 . A deck inlet for a sifter, comprising: a pan that is oriented at an angle from about 2° to about 20° with respect to a horizontal plane; and a spreader coupled to or integral with an upper surface of the pan, wherein the spreader is configured to spread a material substantially evenly across a width of the pan. 2 . The deck inlet of claim 1 , wherein the spreader is configured to spread the material substantially evenly across a width of a screen that is positioned downstream from the pan. 3 . The deck inlet of claim 1 , wherein the spreader is substantially V-shaped and points toward an upstream end of the pan. 4 . The deck inlet of claim 3 , wherein the spreader comprises a first arm and a second arm that are oriented at an angle with respect to one another from about 90° to about 179°. 5 . The deck inlet of claim 1 , wherein the spreader extends from about 60% to about 90% across the width of the pan. 6 . The deck inlet of claim 1 , wherein the spreader comprises a plurality of studs that extend upward from the upper surface of the pan, and wherein each pair of adjacent studs defines a gap therebetween. 7 . The deck inlet of claim 6 , wherein a ratio of a width of one of the studs to a width of one of the gaps is from about 1:1 to about 1:5. 8 . The deck inlet of claim 6 , wherein a width of a first gap is less than a width of a second gap, and wherein the first gap is closer to a middle portion of the spreader than the second gap. 9 . The deck inlet of claim 6 , wherein the studs comprise a first stud and a second stud, wherein a height of the first stud is greater than a height of the second stud, and wherein the first stud is closer to a middle portion of the spreader than the second stud. 10 . The deck inlet of claim 6 , wherein the studs each have a substantially circular cross-sectional shape. 11 . A gyratory sifter, comprising: a housing; an upper deck positioned at least partially within the housing, the upper deck comprising: an upper deck inlet, wherein the upper deck inlet comprises: a pan that is oriented at an angle from about 2° to about 20° with respect to a horizontal plane; and a spreader coupled to or integral with an upper surface of the pan, wherein the spreader is substantially V-shaped and facing an upstream end of the pan; a first upper screen positioned downstream from the upper deck inlet, wherein the spreader is configured to spread a material substantially evenly across a width of the first upper screen; and a first lower screen positioned at least partially below the first upper screen; a lower deck positioned at least partially within the housing and below the upper deck, wherein the lower deck comprises: a lower deck inlet; a second upper screen positioned downstream from the lower deck inlet; and a second lower screen positioned at least partially below the second upper screen; and a motion generator positioned at least partially within the housing, wherein the motion generator is configured to cause the upper deck and the lower deck to move. 12 . The gyratory sifter of claim 11 , wherein the spreader comprises a first arm and a second arm that are oriented at an angle with respect to one another from about 90° to about 179°. 13 . The gyratory sifter of claim 12 , wherein a height of the spreader decreases proceeding from the point along the first arm, from the point along the second arm, or both. 14 . The gyratory sifter of claim 13 , wherein the spreader comprises a plurality of studs that extend upward from the upper surface of the pan, wherein a cross-sectional shape of the studs is at least partially rounded, wherein each pair of adjacent studs defines a gap therebetween, and wherein a ratio of a width of one of the studs to a width of one of the gaps is from about 1:1 to about 1:2. 15 . The gyratory sifter of claim 14 , wherein the width of the gaps decreases proceeding from the point along the first arm, from the point along the second arm, or both. 16 . A method for sifting a material, comprising: receiving the material via a housing inlet of a vibratory sifter; causing at least a portion of the vibratory sifter to move; distributing the material from the housing inlet to an upper deck of the vibratory sifter and a lower deck of the vibratory sifter, wherein the upper deck and the lower deck each comprise a pan, a spreader, and a screen; spreading the material across a width of the screen of the upper deck using the spreader of the upper deck; and sifting the material using the screen of the upper deck to produce a first portion of the material and a second portion of the material. 17 . The method of claim 16 , wherein the spreader of the upper deck is substantially V-shaped and comprises a point and two arms extending from opposing sides thereof, wherein the spreader of the upper deck comprises a plurality of studs, wherein each pair of adjacent studs defines a gap therebetween. 18 . The method of claim 17 , wherein a width of the gaps increases proceeding from the point along the two arms to distribute the material substantially evenly along the width of the screen of the upper deck. 19 . The method of claim 18 , wherein a height of the spreader of the upper deck decreases proceeding from the point along the two arms to distribute the material substantially evenly along the width of the screen of the upper deck. 20 . The method of claim 19 , wherein the material flows through the gaps, but not over the studs, when a flow rate of the material is less than a predetermined rate, and wherein the material flows through the gaps and over the studs when the flow rate of the material is greater than the predetermined rate.