Method and apparatus of manufacturing exhaust gas-purifying catalyst and nozzle used therefor

What is claimed is: 1. A method of manufacturing an exhaust gas-purifying catalyst, comprising: discharging via a nozzle a fluid containing a raw material of a catalytic layer to a substrate using a nozzle, wherein the nozzle comprises: a hollow portion defining an internal space therein and provided with first and second openings connecting the internal space and an external space outside the hollow portion with each other, the hollow portion being configured such that the fluid is supplied to the internal space through the first opening, and a plate-like portion covering the second opening and provided with the discharge ports, the discharge ports configured to discharge the fluid toward the first end face of the substrate, wherein the discharge ports have greater diameters at a periphery of an arrangement of the discharge ports than at a center of the arrangement of the discharge ports, and wherein a ratio of the diameter of the discharge ports that are arranged at the center of the arrangement with respect to the diameter of the discharge ports that are arranged at the periphery of the arrangement is 0.7 or less, and wherein the substrate has first and second end faces and is provided with holes each extending from the first end face toward the second end face, and transferring the substrate to a position opposite to the nozzle before the fluid is discharged, and after fluid discharge is complete, transferring the substrate to a distant position from the position opposite to the nozzle, the nozzle being provided with discharge ports each discharging the fluid toward the first end face of the substrate. 2. The method of manufacturing an exhaust gas-purifying catalyst according to claim 1 , wherein the discharge ports are arranged to form concentric patterns. 3. The method of manufacturing an exhaust gas-purifying catalyst according to claim 1 , wherein each edge of the discharge ports that is adjacent to a space outside the nozzle is beveled to form a beveled portion having a width of 0.5 mm or less. 4. The method of manufacturing an exhaust gas-purifying catalyst according to claim 1 , wherein the nozzle further comprises a deflector located in the hollow body. 5. The method of manufacturing an exhaust gas-purifying catalyst according to claim 4 , wherein the deflector divides the internal space into a downstream region adjacent to the plate-like portion and an upstream region interposed between the downstream region and the first opening, the deflector being provided with through-holes connecting the upstream and downstream regions with each other. 6. The method of manufacturing an exhaust gas-purifying catalyst according to claim 5 , wherein the deflector includes a center portion provided with first through-holes as some of the through-holes and a peripheral portion surrounding the center portion and provided with second through-holes as the remainders of the through-holes, a ratio of a total area occupied by the first through holes with respect to an area of the center portion being smaller than a ratio of a total area occupied by the second through-holes with respect to an area of the peripheral portion. 7. The method of manufacturing an exhaust gas-purifying catalyst according to claim 1 , wherein when supposing a first convex polygon having a smallest area surrounding all the discharge ports and a second convex polygon having an area of 0.6 times the area of the first convex polygon and located inside the first polygon such that a distance from the second convex polygon to an outline of the first convex polygon is constant at all locations on an outline of the second convex polygon, a ratio of a total area occupied by the discharge ports arranged between the outlines of the first and second convex polygons with respect to a total area occupied by all the discharge ports is 0.1 or more. 8. The method of manufacturing an exhaust gas-purifying catalyst according to claim 7 , wherein a minimum distance between the discharge ports is 5 mm or more. 9. The method of manufacturing an exhaust gas-purifying catalyst according to claim 1 , wherein supplying the fluid to the substrate is performed using an apparatus comprising a support supporting the substrate and the nozzle. 10. The method of manufacturing an exhaust gas-purifying catalyst according to claim 9 , wherein the apparatus further comprises a fluid supply device including a tank storing the fluid and an outlet discharging the fluid to be supplied to the nozzle; and a conduit including first and second end portions, the first end portion being connected with the cutlet and supplied with the fluid from the fluid supply device, the second end portion being connected with the nozzle and supplying the fluid to the nozzle, wherein when supposing a curve obtained by connecting points with one another in a flow direction of the fluid in the conduit, each of the points being on a line of interaction of a plane perpendicular to the flow direction and an interior wall of the conduit and having a maximum height from a plane perpendicular to a direction of gravity, the height monotonically decreases from a position at which the conduit and the outlet are connected with each other to a position at which the conduit and the nozzle are connected with each other. 11. The method of manufacturing an exhaust gas-purifying catalyst according to claim 9 , wherein the apparatus comprises: a fluid supply device performing a supply operation of supplying a certain amount of the fluid to the nozzle and a suction operation of sucking back a part of the fluid in the nozzle; and a controller controlling operation of the fluid supply device such that the supply operation is repeated during a continuous production and the suction operation is performed when suspending the continuous production, wherein the fluid supply device comprises: a tank storing the fluid; a syringe including a cylinder and a piston linearly movable in the cylinder; a drive mechanism causing the piston to linearly move in and relative to the cylinder; a first port communicated with the tank; a second port communicated with the cylinder; a third port communicated with the nozzle; and a switch mechanism switching connection of the first to third ports between a first state in which the first and second ports are connected with each other and the third port is disconnected from the first and second ports and a second state in which the second and third ports are connected with each other and the first port is disconnected from the second and third ports, and wherein the method further comprises controlling operation of the switch and drive mechanisms such that first and second operations are alternately performed during the continuous production and that a third operation is performed when the continuous production is suspended, the first operation including setting the connection of the first to third ports into the first state and causing the piston to linearly move relative to the cylinder such that a front end of the piston moves away from a bottom of the cylinder so as to extract a part of the fluid from the tank into the syringe, the second operation including setting the connection of the first to third ports into the second state and causing the piston to linearly move with respect to the cylinder such that the front end of the piston moves closer to the bottom of the cylinder so as to supply a certain amount of the fluid to the nozzle, the third operation including setting the connection of the first to third ports into the second state and causing the piston to linearly move relative to the cylinder such that the front end of the piston moves away from the bottom of the cyl