Cooling structure for bearing device

What is claimed is: 1. A bearing device having a plurality of axially juxtaposed rolling bearings, each of the rolling bearings having an inner ring mounted on a main shaft and an outer ring accommodated in a housing; an inner ring spacer interposed between the inner rings of the neighboring rolling bearings and mounted on the main shaft; an outer ring spacer interposed between the outer rings of the neighboring rolling bearings and accommodated in the housing; and a cooling structure, wherein the cooling structure comprises: a nozzle provided in the outer ring spacer and configured to supply a cooling fluid to the rolling bearings by blowing the cooling fluid to an outer peripheral surface of the inner ring spacer, the cooling fluid including at least one of air and oil, wherein the nozzle has a discharge port side that is inclined forwardly with respect to a direction of rotation of the main shaft, the outer peripheral surface of the inner ring spacer is shaped to guide the cooling fluid, discharged from the nozzle, towards the neighboring rolling bearings on both sides, and the outer peripheral surface of the inner ring spacer includes a circumferential groove positioned at a portion where the cooling fluid discharged from the nozzle is blown, and a spiral groove on each side of the circumferential groove having one end connected with the circumferential groove and approaching the neighboring rolling bearings as a circumferential phase is displaced in the direction of rotation of the main shaft. 2. The bearing device as claimed in claim 1 , in which an outer diameter of inner ring spacer is smallest at the portion where the cooling fluid discharged from the nozzle is blown, and the outer peripheral surface of the inner ring spacer is inclined from the portion towards the neighboring rolling bearings, and the outer diameter at axial ends of the outer peripheral surface of the inner ring spacer is equal to or larger than the outer diameter of an inner ring spacer side end in the inner ring of the neighboring rolling bearings. 3. The bearing device as claimed in claim 1 , in which the cooling fluid is a compressed air, the nozzle for discharging the compressed air towards the outer peripheral surface of the inner ring spacer is provided in the outer ring spacer so as to incline forwardly with respect to the direction of rotation, and a gap between the inner peripheral surface of the outer ring spacer, where the discharge port of the nozzle exists, and the outer peripheral surface of the inner ring spacer, that confronts the discharge port, is 0.7 mm or larger, but smaller than half the diameter of the nozzle. 4. The bearing device as claimed in claim 3 , further comprising a lubricating nozzle for supplying a lubrication oil into the neighboring rolling bearings provided in the outer ring spacer, in which the lubricating nozzle is configured to discharge the lubricant oil towards a raceway surface of the inner ring of the neighboring rolling bearings. 5. A machine tool in which the bearing device as defined in claim 1 is incorporated. 6. A bearing device having a plurality of axially juxtaposed rolling bearings, each of the rolling bearings having an inner ring mounted on a main shaft and an outer ring accommodated in a housing; an inner ring spacer interposed between the inner rings of the neighboring rolling bearings and mounted on the main shaft; an outer ring spacer interposed between the outer rings of the neighboring rolling bearings and accommodated in the housing; and a cooling structure, wherein the cooling structure comprises: a nozzle provided in the outer ring spacer and configured to supply a cooling fluid to the rolling bearings by discharging the cooling fluid to an outer peripheral surface of the inner ring spacer, the cooling fluid including a compressed air, wherein the outer peripheral surface of the inner ring spacer is shaped to guide the cooling fluid, discharged from the nozzle, towards the neighboring rolling bearings on both sides, the nozzle for discharging the compressed air towards the outer peripheral surface of the inner ring spacer has a discharge port side that is provided in the outer ring spacer so as to incline forwardly with respect to the direction of rotation, and a radially protruding projection is defined in axial opposite side portions of the discharge port of the nozzle in the outer ring spacer or the inner ring spacer, wherein a first gap is formed between a radial tip end portion of the projection and a peripheral surface of the inner ring spacer, and the first gap is made smaller than a second gap present between the inner peripheral surface of the outer ring spacer, where the discharge port exists, and the outer peripheral surface of the inner ring spacer. 7. The bearing device as claimed in claim 6 , in which the projection is provided in a widthwise intermediate portion of the outer peripheral surface of the inner ring spacer, a lubricating nozzle for supplying a lubricant oil into the bearing is provided in the outer ring spacer, and an axial gap is provided between an axial opposite end surface of the projection and an inner end surface of the lubricating nozzle. 8. A bearing device having a plurality of axially juxtaposed rolling bearings, each of the rolling bearings having an inner ring mounted on a main shaft and an outer ring accommodated in a housing; an inner ring spacer interposed between the inner rings of the neighboring rolling bearings and mounted on the main shaft; an outer ring spacer interposed between the outer rings of the neighboring rolling bearings and accommodated in the housing; and a cooling structure, wherein the cooling structure comprises: a nozzle provided in the outer ring spacer and configured to supply a cooling fluid to the rolling bearings by discharging the cooling fluid to an outer peripheral surface of the inner ring spacer, the cooling fluid including a compressed air, wherein the nozzle has a discharge port side that is inclined forwardly with respect to a direction of rotation of the main shaft, the outer peripheral surface of the inner ring spacer is shaped to guide the cooling fluid, discharged from the nozzle, towards the neighboring rolling bearings on both sides, and a plurality of circumferentially juxtaposed holes are provided at a location of the outer peripheral surface of the inner ring spacer where the compressed air is discharged from the discharge port. 9. The bearing device as claimed in claim 8 , in which a groove is provided in the outer peripheral surface or the inner peripheral surface of the inner ring spacer. 10. The bearing device as claimed in claim 8 , in which the outer ring spacer is provided with an air oil supply port for supplying an air oil into the rolling bearing, and the air oil supply port includes a projecting portion configured to project into the rolling bearing so as to confront the outer peripheral surface of the inner ring through an annular gap for the passage of the air oil, and in which the air oil supply port includes an air oil nozzle for discharging the air oil towards the inner ring at an inner diametric side of the projection. 11. The bearing device as claimed in claim 10 , in which the air oil supply port and the discharge port of the compressed air are concurrently utilized. 12. A bearing device having three or more of axially juxtaposed rolling bearings, including an intermediate rolling bearing and an end rolling bearing, each of the rolling bearings having an inner ring mounted on a main shaft and an outer ring accommodated in a housing; inner ring spacers interposed between the inner rings of neighboring rolling bearings and mou