Manufacturing method of optical fiber ribbon, manufacturing device for optical fiber ribbon implementing said manufacturing method, and optical fiber ribbon manufactured with said manufacturing method

What is claimed is: 1. A manufacturing method for an optical fiber ribbon, in which: a plurality of optical fiber core cables are arranged in parallel and the neighboring optical fiber core cables are coupled with each other at certain points with given intervals therebetween in a longitudinal direction to form a subunit that is a unit to be divided; and the optical fiber core cables positioned at side edges of the neighboring subunits are coupled with each other at certain points with given intervals therebetween in the longitudinal direction, comprises: a resin applying step for sending out the plurality of the optical fiber core cables in a parallel manner with intervals provided therebetween, in the lateral direction of the optical fiber core cables, applying an uncured resin to the plurality of the optical fiber core cables, moving a plurality of interrupt members which are included in an intermittent resin-coating device and arranged corresponding to positions between each of the optical fiber core cables to interrupt the uncured resin, and periodically changing positions at which the uncured resin is interrupted and positions at which the uncured resin is ejected without interruption by the interrupt members; and a resin curing step for irradiating positions, at which the plurality of the optical fiber core cables are arranged in parallel, concentrated and in contact with each other, with resin curing energy required for the uncured resin coated on the optical fiber core cables to cure, thereby forming coupled portions at which the optical fiber core cables are coupled to each other, wherein first coupled portions between the subunits and second coupled portions within each subunit adjacent thereto do not overlap in the width direction of the optical fiber ribbon, each interval between the adjacent first coupled portions being longer than each interval between the adjacent second coupled portions, wherein each of the first coupled portions overlaps with at least one of the other first coupled portions in the width direction of the optical fiber ribbon, each of the second coupled portions does not overlap with the other coupled portions within the same subunit in the width direction of the optical fiber ribbon and overlaps with one of the coupled portions within the other subunit in the width direction of the optical fiber ribbon, and wherein a moving period or phase of the interrupt members is changed for adjacent optical fiber core cables. 2. The manufacturing method of the optical fiber ribbon according to claim 1 , wherein upon applying the resin for coupling the optical fiber core cables configuring the subunit with each other, movements of the respective interrupt members are set to a first period and set to different phases with each other, and upon applying the resin for coupling the subunits with each other, movements of the respective interrupt members are set to a second period which is longer than the first period and set to different phases with each other. 3. The manufacturing method of the optical fiber ribbon according to claim 1 , wherein upon applying the resin for coupling the optical fiber core cables configuring the subunit with each other, movements of the respective interrupt members are set to: a first period; and different phases with each other for the coupling of the neighboring optical fiber core cables in a width direction of the optical fiber ribbon, and upon applying the resin for coupling the subunits with each other, movements of the respective interrupt members are set to a second period which is longer than the first period. 4. An optical fiber ribbon manufactured with the manufacturing method of the optical fiber ribbon according to claim 1 . 5. A manufacturing device for an optical fiber ribbon, in which: a plurality of optical fiber core cables are arranged in parallel and the neighboring optical fiber core cables are coupled with each other at certain points with given intervals therebetween in a longitudinal direction to form a subunit that is a unit to be divided; and the optical fiber core cables positioned at side edges of the neighboring subunits are coupled with each other at certain points with given intervals therebetween in the longitudinal direction, wherein the plurality of the optical fiber core cables is sent out in a parallel manner with intervals provided therebetween, in the lateral direction of the optical fiber core cables, an uncured resin is applied to the plurality of the optical fiber core cables, a plurality of interrupt members, which are included in an intermittent resin-coating device and arranged corresponding to positions between each of the optical fiber core cables, are moved to interrupt the uncured resin, and positions are periodically changed at which the uncured resin is interrupted and positions at which the uncured resin is ejected without interruption by the interrupt members; and positions at which the plurality of the optical fiber core cables are arranged in parallel, concentrated and in contact with each other, are irradiated with resin curing energy required for the uncured resin coated on the optical fiber core cables to cure, thereby forming coupled portions at which the optical fiber core cables are coupled to each other wherein first coupled portions between the subunits and second coupled portions within each subunit adjacent thereto do not overlap in the width direction of the optical fiber ribbon, each interval between the adjacent first coupled portions being longer than each interval between the adjacent second coupled portions, and where each of the first coupled portions overlaps with at least one of the other first coupled portions in the width direction of the optical fiber ribbon, each of the second coupled portions does not overlap with the other coupled portions within the same subunit in the width direction of the optical fiber ribbon and overlaps with one of the coupled portions within the other subunit in the width direction of the optical fiber ribbon. 6. The manufacturing device of the optical fiber ribbon according to claim 5 , wherein upon applying the resin for coupling the optical fiber core cables configuring the subunit with each other, movements of the respective interrupt members are set to a first period and set to different phases with each other, and upon applying the resin for coupling the subunits with each other, movements of the respective interrupt members are set to a second period which is longer than the first period and set to different phases with each other. 7. The manufacturing device of the optical fiber ribbon according to claim 5 , wherein upon applying the resin for coupling the optical fiber core cables configuring the subunit with each other, movements of the respective interrupt members are set to: a first period; and different phases with each other for the coupling of the neighboring optical fiber core cables in a width direction of the optical fiber ribbon, and upon applying the resin for coupling the subunits with each other, movements of the respective interrupt members are set to a second period which is longer than the first period. 8. An optical fiber ribbon manufactured with the manufacturing device of the optical fiber ribbon according to claim 5 .