Method and apparatus of manufacturing exhaust gas-purifying catalyst

What is claimed is: 1. A method of manufacturing an exhaust gas purifying catalyst including a substrate, the substrate having a first end face and a second end face and provided with a plurality of holes each extending from the first end face toward the second end face, comprising: locating a reservoir attachment having a frame shape with respect to the substrate such that the reservoir attachment surrounds a region adjacent to the first end face to form, together with the first end face, a reservoir capable of storing slurry in the region; supplying the slurry to the reservoir; reducing a pressure in a region adjacent to the second end face relative to a pressure in a region adjacent to the substrate with the slurry in the reservoir interposed therebetween to guide the slurry in the reservoir into the plurality of holes and generate flows of the slurry from the first end face toward the second end face in the plurality of holes; and moving a gas flow control tool from a first position where the gas flow control tool faces the first end face with the slurry in the reservoir interposed therebetween and is spaced apart from the slurry in the reservoir to a second position where the gas flow control tool faces the first end face with a distance from the first end face shorter than that in the first position, in a period during which the slurry flows from the first end face's side toward the second end face's side, the gas flow control tool being configured to generate a distribution of linear velocities of gas flows when the gas flow control tool faces the first end face and gas is passed therethrough toward the first end face. 2. The manufacturing method of claim 1 , wherein the gas flow control tool includes a plate having a first through hole at a center and a plurality of second through holes around the first through hole, each of the second through holes having a diameter smaller than a diameter of the first through hole. 3. The manufacturing method of claim 2 , wherein the gas flow control tool further includes a partition extending from an edge of the plate at the first through hole toward the second end face. 4. An apparatus of manufacturing an exhaust gas purifying catalyst including a substrate, the substrate having a first end face and a second end face and provided with a plurality of holes each extending from the first end face toward the second end face, comprising: a reservoir attachment having a frame shape, a first transfer mechanism which includes a first transfer device and a conveyance device, the first transfer device including a first support that supports the reservoir attachment, and the conveyance device including a second support that detachable supports the substrate, the first transfer mechanism is configured to cause a change in a relative position between the substrate and the reservoir attachment being changeable between a first state in which the reservoir attachment and the substrate are located away from each other and a second state in which the reservoir attachment surrounds a region adjacent to the first end face to form, together with the first end face, a reservoir capable of storing slurry in the region; a supply device including a nozzle having one or more discharge ports and configured to supply the slurry to the reservoir; a pressure adjuster including a conduit having a first end connected to the second end face of the substrate and a second end and configured to reduce a pressure in a region adjacent to the second end face relative to a pressure in a region adjacent to the substrate with the slurry in the reservoir interposed therebetween to guide the slurry in the reservoir into the plurality of holes and generate flows of the slurry from the first end face toward the second end face in the plurality of holes, the pressure adjuster being brought into operation after the supply device supplies the slurry to the reservoir; and a gas flow control tool including a plate and configured to generate a distribution of linear velocities of gas flows when the gas flow control tool faces the first end face and gas is passed therethrough toward the first end face, a second transfer mechanism including a third transfer device, the third transfer device including a third support that supports the gas-flow control tool, and the second transfer mechanism is configured to move the gas flow control tool being movable between a first position where the gas flow control tool faces the first end face with the slurry in the reservoir interposed therebetween and is spaced apart from the slurry in the reservoir and a second position where the gas flow control tool faces the first end face with a distance from the first end face shorter than that in the first position, and an electric controller unit configured to control operations of the first transfer mechanism and the supply device and further control operations of the pressure adjuster and the second transfer mechanism such that the pressure adjuster is brought into operation after the supply device supplies the slurry to the reservoir and that the gas flow control tool moving from the first position to the second position in a period during which the slurry flows from the first end face's side toward the second end face's side. 5. The manufacturing apparatus of claim 4 , wherein the plate of the gas flow control tool includes a first through hole at a center and a plurality of second through holes around the first through hole, each of the second through holes having a diameter smaller than a diameter of the first through hole. 6. The manufacturing apparatus of claim 5 , wherein the gas flow control tool further includes a partition extending from an edge of the plate at the first through hole toward the second end face. 7. The manufacturing apparatus of claim 5 , wherein the pressure adjuster further comprises a suction device connected to the second end of the conduit.