Hydrostatic bearing apparatus, machine-tool main-spindle apparatus including hydrostatic bearing apparatus, and method for manufacturing hydrostatic bearing apparatus

What is claimed is: 1. A hydrostatic bearing apparatus comprising: a rotating shaft; and a bearing metal with a hydrostatic portion that allows the rotating shaft to be rotatably supported; wherein the hydrostatic portion has a bearing clearance disposed between a surface of the rotating shaft and the bearing metal and filled with a lubricating solution, a bearing surface portion faces the surface of the rotating shaft, a plurality of pockets are recessed in the bearing surface portion adjacently to one another in a circumferential direction of the bearing surface portion, and partition plates each housed in a corresponding one of the pockets and partition a bottom portion of the pocket from the surface of the rotating shaft, clearances are each formed between the partition plate and an edge of the pocket in a rotating direction of the rotating shaft, the clearances are formed in the pocket at upstream and downstream ends of the partition plate in the rotating direction, the bearing clearance includes a first bearing clearance between the surface of the rotating shaft and the bearing surface portion and a second bearing clearance between the surface of the rotating shaft and the partition plate, and the second bearing clearance is larger than the first bearing clearance, the clearances are each formed as a slit that extends parallel to an axial direction of the rotating shaft, the slit includes a first slit and a second slit that are located downstream and upstream, respectively, in the rotating direction of the rotating shaft, and the first slit and the second slit each have an opening width in the rotating direction larger than the second bearing clearance. 2. The hydrostatic bearing apparatus according to claim 1 , wherein when a density of the lubricating solution is denoted by ρ, a viscosity coefficient of the lubricating solution is denoted by μ, a peripheral velocity of the rotating shaft is denoted by U, and a size of the second bearing clearance is denoted by H, a Reynolds number for the second bearing clearance is expressed by Re=ρUH/μ, and for a flow of the lubricating solution occurring through the second bearing clearance when the rotating shaft is rotatably supported, Re<2000. 3. The hydrostatic bearing apparatus according to claim 1 , wherein the lubricating solution is water, or a water solution in which 90% or more of its composition is water, or low-viscosity mineral oil. 4. The hydrostatic bearing apparatus according to claim 1 , wherein the lubricating solution flowing through the second bearing clearance when the rotating shaft is rotatably supported forms a laminar flow along the rotating direction of the rotating shaft, and the lubricating solution flowing through a third bearing clearance between the bottom portion of the pocket and the partition plate forms a flow in a direction opposite to the rotating direction of the rotating shaft. 5. The hydrostatic bearing apparatus according to claim 1 , wherein the partition plate and the bearing metal are provided separately from each other. 6. A machine-tool main-spindle apparatus comprising the hydrostatic bearing apparatus according to claim 1 . 7. A hydrostatic bearing apparatus comprising: a rotating shaft; and a bearing metal with a hydrostatic portion that allows the rotating shaft to be rotatably supported; wherein the hydrostatic portion has a bearing clearance disposed between a surface of the rotating shaft and the bearing metal and filled with a lubricating solution, a bearing surface portion faces the surface of the rotating shaft, a plurality of pockets are recessed in the bearing surface portion adjacently to one another in a circumferential direction of the bearing surface portion, and partition plates each housed in a corresponding one of the pockets and partition a bottom portion of the pocket from the surface of the rotating shaft, clearances are each formed between the partition plate and an edge of the pocket in a rotating direction of the rotating shaft, the clearances are formed in the pocket at upstream and downstream ends of the partition plate in the rotating direction, the bearing clearance includes a first bearing clearance between the surface of the rotating shaft and the bearing surface portion and a second bearing clearance between the surface of the rotating shaft and the partition plate, and the second bearing clearance is larger than the first bearing clearance, wherein the partition plate and the bearing metal are formed of different materials, and the partition plate is formed of a material having a lower strength than a material of the bearing metal. 8. The hydrostatic bearing apparatus according to claim 7 , wherein when a density of the lubricating solution is denoted by ρ, a viscosity coefficient of the lubricating solution is denoted by μ, a peripheral velocity of the rotating shaft is denoted by U, and a size of the second bearing clearance is denoted by H, a Reynolds number for the second bearing clearance is expressed by Re=ρUH/μ, and for a flow of the lubricating solution occurring through the second bearing clearance when the rotating shaft is rotatably supported, Re<2000. 9. The hydrostatic bearing apparatus according to claim 7 , wherein the lubricating solution is water, or a water solution in which 90% or more of its composition is water, or low-viscosity mineral oil. 10. The hydrostatic bearing apparatus according to claim 7 , wherein the lubricating solution flowing through the second bearing clearance when the rotating shaft is rotatably supported forms a laminar flow along the rotating direction of the rotating shaft, and the lubricating solution flowing through a third bearing clearance between the bottom portion of the pocket and the partition plate forms a flow in a direction opposite to the rotating direction of the rotating shaft. 11. A machine-tool main-spindle apparatus comprising the hydrostatic bearing apparatus according to claim 7 .