Optical fiber manufacturing method using relative bulk densities

What is claimed is: 1. An optical fiber manufacturing method for manufacturing an optical fiber that includes a core portion made of glass and a cladding portion made of glass and formed on outer periphery of the core portion, the optical fiber manufacturing method comprising: setting such that a first holding member and a core rod are placed inside a glass pipe constituting the cladding portion, the first holding member being one of a pair of holding members that are made of glass and have a plurality of holes formed thereon, the core rod including a core forming portion serving as the core portion and including a cladding forming portion serving as a portion adjacent to the core portion across outer periphery of the core portion, in such a way that the core rod is supported by the first holding member; filling glass particles in a gap between the core rod and an inner wall of the glass pipe; holding the core rod such that a second holding member of the pair of holding members is placed inside the glass pipe, in such a way that the core rod is held in a sandwiched manner in between the first holding member and the second holding member, and the core rod and the filled glass particles are housed in an area enclosed by the inner wall of the glass pipe, the first holding member, and the second holding member, and sealing one end portion of the glass pipe and manufacturing an intermediate object; and manufacturing an optical fiber using the intermediate object, wherein a bulk density of the first holding member and the second holding member is set to be within a predetermined range with reference to bulk density of a filling portion filled with the glass particles, and the predetermined range is determined according to a permissible variation range for a core diameter in longitudinal direction of the optical fiber. 2. The optical fiber manufacturing method according to claim 1 , further comprising dehydroxylating by circulating a reducing gas inside the glass pipe through the plurality of holes. 3. The optical fiber manufacturing method according to claim 1 , wherein the first holding member and the second holding member are glass plates having the plurality of holes formed therein. 4. The optical fiber manufacturing method according to claim 1 , wherein the first holding member as well as the second holding member is a glass powder molded body and is a glass porous body having the plurality of holes formed therein. 5. The optical fiber manufacturing method according to claim 4 , wherein the glass porous body includes a molding portion of glass powder with average particle diameter Da equal to or greater than 0.3 μm. 6. The optical fiber manufacturing method according to claim 1 , wherein the optical fiber includes a plurality of the core portion, the setting includes placing, inside the glass pipe, the first holding member and a plurality of the core rod in such a way that the plurality of the core rods are supported by the first holding member, the filling glass particles includes filling the glass particles in gaps between the inner wall face and the plurality of core rods, and the holding includes housing the plurality of the core rods and the filled glass particles in an area enclosed by the inner wall of the glass pipe, the first holding member, and the second holding member, and holding the plurality of the core rods in a sandwiched manner in between the first holding member and the second holding member. 7. The optical fiber manufacturing method according to claim 1 , wherein the glass particles that are filled in the filling glass particles have average particle diameter equal to or greater than 50 μm and equal to or smaller than 500 μm. 8. The optical fiber manufacturing method according to claim 1 , wherein the manufacturing the optical fiber includes a sintering process that includes heating the intermediate object while depressurizing internal atmosphere of the glass pipe through the plurality of holes, consolidating the first holding member, the second holding member, and the filled glass particles, and manufacturing an optical fiber preform, and a wiredrawing process that includes heat-melting the optical fiber preform and wiredrawing an optical fiber. 9. The optical fiber manufacturing method according to claim 1 , wherein the manufacturing the optical fiber includes a sintering process that includes heating the intermediate object while controlling internal atmosphere of the glass pipe through the plurality of holes, consolidating the first holding member and the second holding member, forming, as an independent bubble, an isolated bubble among the glass particles while sintering the filled glass particles, and manufacturing an optical fiber preform that includes a sintering area of the glass particles in which a plurality of the independent bubble is included, and a wiredrawing process that heat-melts the optical fiber preform, and wiredrawing the optical fiber that includes treating sintering area of the glass particles as an independent bubble area that is a part of the cladding portion and that is formed at a distant position from the core portion with the plurality of the independent bubbles formed therein. 10. The optical fiber manufacturing method according to claim 1 , wherein the manufacturing the optical fiber includes a wiredrawing process that includes heating the intermediate object while depressurizing internal atmosphere of the glass pipe through the plurality of holes, melting the glass pipe and the core rod, consolidating the first holding member, the second holding member, and the filled glass particles, and wiredrawing an optical fiber. 11. The optical fiber manufacturing method according to claim 1 , wherein the manufacturing the optical fiber includes heating the intermediate object while controlling internal atmosphere of the glass pipe through the plurality of holes, melting the glass pipe and the core rod, consolidating the first holding member and the second holding member, forming; as an independent bubble, an isolated bubbles among the glass particles while sintering the filled glass particles, and wiredrawing an optical fiber, and the wiredrawing the optical fiber includes treating sintering area of the glass particles, in which a plurality of the independent bubbles is formed, as an independent bubble area that is a part of the cladding portion and that is formed at a distant position from the core portion with the plurality of the independent bubbles formed therein.