Abstract: The vehicle control system, in response to transmission of a command from a remote assistance apparatus to a vehicle, sets a cancellable period during which the command can be cancelled by the remote assistance apparatus. Also, the vehicle control system acquires a communication delay time between the vehicle and the remote assistance apparatus. The vehicle control system adjusts a control amount of the vehicle related to a speed in accordance with the communication delay time on condition that current time is within the cancellable period and the communication delay time is equal to or greater than a predetermined time.

Abstract: A rotating device includes: a hub mounting a recording disk; a base rotatably supporting the hub via a bearing, a core fixedly mounted on the base, and having a circular portion and salient poles protruding radially outward; a coil wound around the salient poles; and an FPC including driving lines. The base has a wire hole that communicates between an upper face that faces the coil in the axial direction and an opposite lower face. The lower face has a bottom recess portion surrounding a hub rotational axis, and regions facing each other across the rotational axis. The FPC includes an arc section housed in the bottom recess portion. Each lead wire is drawn out from the coil to the lower-face side via the wire hole, and is connected to the driving line on a connection land formed at an interval from the wire hole in the circumferential direction.

Abstract: A rotating device comprises a hub, a shaft, and a bearing unit. The bearing unit includes a surrounding portion arranged to surround the shaft, and a facing portion arranged to face an end of the shaft. A gap between the shaft and the surrounding portion includes two dynamic pressure generation portions and an intermediate portion arranged between the two dynamic pressure generation portions. The bearing unit further includes a path of a lubricant arranged to connect one side of one dynamic pressure generation portion and the intermediate portion. The shaft and the bearing unit are arranged so that the lubricant pushed out of the other dynamic pressure generation portion towards a gap between the end of the shaft and the facing portion stays in the gap.

Abstract: A disk drive device includes a base plate, a hub, and a bearing unit. The bearing unit includes an outer sleeve, an inner sleeve, a shaft, a radial dynamic pressure groove, and a lubricant agent. In the joined portion of the outer sleeve and the hub, there are formed a recessed portion, which is a binding region, where the outer sleeve and the hub are joined together with a hardening resin present between the outer sleeve and the hub and a tilt preventing portion, provided on both the sides of the recessed portion in the axial direction of the outer, which is a raised region that forms a portion narrower than a gap, between the outer sleeve and the hub, corresponding to the recessed portion.

Abstract: The rotating device comprises the rotor to which the magnetic recording disk is to be mounted and a stator rotatably supporting the rotor. The stator includes: a bearing unit rotatably supporting the rotor by generating dynamic pressure in lubricant that intervenes between the rotor and the stator; and a base on which a central hole is formed, the center of the central hole being along the rotational axis of the rotor and the bearing unit being fixed to the central hole. The bearing unit includes the housing and the sleeve. The housing includes: a first outer surface joining the central hole; and a second outer surface formed more radially outward from the rotational axis than the first outer surface, the second outer surface partly overlapping the first outer surface in the axial direction.

Abstract: A disk drive device includes a base plate, a hub, and a bearing unit. The bearing unit includes an outer sleeve, an inner sleeve, a shaft, a radial dynamic pressure groove, and a lubricant agent. In the joined portion of the outer sleeve and the hub, there are formed a recessed portion, which is a binding region, where the outer sleeve and the hub are joined together with a hardening resin present between the outer sleeve and the hub and a tilt preventing portion, provided on both the sides of the recessed portion in the axial direction of the outer, which is a raised region that forms a portion narrower than a gap, between the outer sleeve and the hub, corresponding to the recessed portion.

Abstract: A rotary device according to an aspect of the invention includes: a sleeve having an inner cylindrical surface, a first end portion and a second end portion at respective ends of the inner cylindrical surface; a shaft that is accommodated in the inner cylindrical surface in a manner rotatable relative to the inner cylindrical surface; a fluid present in a space between the shaft and the sleeve; a first pump portion formed in a middle portion of the inner cylindrical surface and configured to cause the fluid to flow toward the first end portion by the relative rotation of the shaft and the sleeve; a first radial narrow gap formed at a region of the inner cylindrical surface on a side of the first end portion with respect to the first pump portion; and a first circulation path communicated with the first pump portion.

Abstract: This lubricant for a fluid dynamic bearing has a base oil containing a phosphate triester represented by a general formula (I) (wherein, RA, RB and RC respectively represent alkyl groups), wherein in the base oil, a phosphate triester in which the three alkyl groups in the general formula (I) are saturated hydrocarbon groups and number of carbon atoms of one of the three saturated hydrocarbon groups differs from number of carbon atoms of the other two saturated hydrocarbon groups is contained as a primary base oil.

Abstract: An illuminating apparatus according to the present invention comprises a controller, a power supply cable and a plurality of light-emitting units. The plurality of light-emitting units shown are a first light-emitting unit, a second light-emitting unit, a third light-emitting unit, a fourth light-emitting unit, a fifth light-emitting unit, a sixth light-emitting unit, a seventh light-emitting unit and an eighth light-emitting unit. Each light-emitting unit is provided with a red LED, a green LED and a blue LED. A diode is connected to the red LED whose forward voltage is lower.

Abstract: An illuminating apparatus according to the present invention comprises a controller, a power supply cable and a plurality of light-emitting units. The plurality of light-emitting units shown are a first light-emitting unit, a second light-emitting unit, a third light-emitting unit, a fourth light-emitting unit, a fifth light-emitting unit, a sixth light-emitting unit, a seventh light-emitting unit and an eighth light-emitting unit. Each light-emitting unit is provided with a red LED, a green LED and a blue LED. A diode is connected to the red LED whose forward voltage is lower.

Abstract: A reliable hydrodynamic bearing having high rotational accuracy is offered. The hydrodynamic bearing for a small-sized motor is made of a special nonmagnetic steel material that is excellent in terms of machinability, wear resistance, and corrosion resistance. This special steel material contains 14.00% Cr, 8.00% Mn, 0.20% C, 2.00% Ni, 0.35% Si, and less than 0.05% P. This special steel material has high machinability and so machining accuracies such as surface roughness and squareness can be enhanced. Consequently, the rotational accuracy of the hydrodynamic bearing can be enhanced. This special steel material also has such a property that when pressure is applied to plastically deform it, the pressed surface hardens. Using this nature, the surfaces at which rotating and stationary parts of the bearing contact with each other are pressed. Thus, the surfaces are hardened. Hence, the wear resistance is improved.

Abstract: In a hydraulic bearing motor, by means of dynamic pressure generating grooves provided on a thrust shaft with a larger diameter not only on the end face thereof but also on the shaft surface thereof, pressures generated in oil when rotating a shaft body are made to be applied not only in the axial direction but also in the radial direction with high magnitude. This can provide the hydraulic bearing motor as being capable of satisfying features of exhibiting small NRRO, and vibration and shock resistance even with a thinned hydraulic bearing motor.

Abstract: A hydraulic dynamic pressure bearing motor has a rotational shaft mounted to undergo rotation about a rotational axis and having a shaft section and a flange section. A sleeve has a cavity for receiving the rotational shaft. A cover member is disposed over an open end of the sleeve cavity. A hydraulic dynamic pressure bearing includes minute radial and thrust clearances disposed between outer surface portions of the shaft and flange sections of the rotational shaft and inner surface portions of the sleeve and the cover member. A lubricating fluid is disposed in the minute radial and thrust clearances. The minute radial and thrust clearances are dimensioned so that during a non-rotational state of the rotational shaft, the flange section of the rotational shaft contacts preselected inner surface portions of the sleeve and the cover member while the shaft section of the rotational shaft does not contact any portion of the sleeve and an inner peripheral surface of the cover member.

Abstract: In a spindle motor, a core with a specified thickness is formed by laminating thinnest possible magnetic steel sheets to allow consumed current to be reduced. For example, by providing a structure of a core of a spindle motor with seven 0.2 mm thick steel sheets being laminated, it becomes possible to make consumed current smaller than that for a core laminated with four 0.35 mm thick steel sheets. Thus, a spindle motor is provided as being suited for downsizing an HDD and possible to reduce consumed power.

Abstract: In a thin dynamic pressure hydraulic bearing motor used for a compact HDD device which motor is provided with a thin hydraulic dynamic pressure bearing comprising a flanged rotary shaft comprising a shaft and a flange, a sleeve into which the flanged rotary shaft is rotatably inserted, a ring-like lid 35, and lubricating oil filling minute clearances formed by those bearing components, the thrust clearance c is determined as being equal to or less than a value for which a product md of the maximum vertical shift m at a rim of a magnetic disk and a diameter d of the flange of the flanged rotary shaft is divided by 4r, four times a radius r of the magnetic disk. Thus, even when no bearing stiffness is provided for the hydraulic dynamic pressure bearing motor at rest, the magnetic disk is made so as not to contact with a head supporting system such as a head loading arm.

Abstract: In a hydraulic bearing motor, by means of dynamic pressure generating grooves provided on a thrust shaft with a larger diameter not only on the end face thereof but also on the shaft surface thereof, pressures generated in oil when rotating a shaft body are made to be applied not only in the axial direction but also in the radial direction with high magnitude. This can provide the hydraulic bearing motor as being capable of satisfying features of exhibiting small NRRO, and vibration and shock resistance even with a thinned hydraulic bearing motor.

Abstract: A motor has a support member, a bearing member mounted in a hollow space of the support member for undergoing rotation, a rotor member having a shaft portion disposed in a hollow space of the bearing member for rotation therewith, at least one magnet connected to one of the support member and the rotor member, and electromagnets connected to the other of the support member and the rotor member and in confronting relation to the magnet for generating a rotational magnetic field that coacts with the magnet to rotate the rotor member. At least one of an inner peripheral surface of the bearing member and an outer peripheral surface of the shaft portion of the rotor member has contact portions disposed in contact with the other of the inner peripheral surface and the outer peripheral surface to form lubricating gaps each disposed between an adjacent pair of contact portions and between the inner and outer peripheral surfaces.

Abstract: The problem is to provide a motor that a stator coil can be firmly supported with high rigidity and is less in vibration and noise, a method for manufacturing same and a rotary apparatus. A motor is provided as solving means, which comprises: a base 10 having a cylindrical fit portion 10a; a sleeve 20 having one end firmly fixed in the fit portion 10a; a hub shaft 30 including a hub portion 32 supporting a hard disk, a shaft portion 31 extended from a hub portion 32 center and inserted in the sleeve 20, and an annular portion 33 annularly extended from a peripheral edge of the hub portion 32 in a same direction as the shaft portion 31; a bearing ring 52 coaxially fixed on a tip of the shaft portion 31; an engaging ring 51 fixed at the other end of the sleeve 20 and abutted against the bearing ring 52 thereby regulating axial movement of the shaft portion 31; a rotor magnet 60 fixed on an inner peripheral wall of the annular portion 33; and a stator coil 40 fixed on an outer peripheral wall of the sleeve 20.

Abstract: A double sleeve type dynamic bearing comprises a fixed shaft having at least one end fixedly mountable to an apparatus in which the bearing is utilized, a rotary sleeve arranged coaxially with the fixed shaft so that a first fine gap is formed therebetween, a fixed sleeve arranged coaxially with the rotary sleeve so that a second fine gap is formed therebetween, and a lubrication oil filled in the fine gaps. The first fine gap and the second fine gap each have an open end exposed to air outside the bearing and an opposite end that is not exposed to the air, the opposite ends being in communication with each other. A holding member holds the fixed shaft and the fixed sleeve and is disposed adjacent to a lower end surface of the rotary sleeve to form a third fine gap between the holding member and the lower end surface of the rotary sleeve. The third fine gap is formed with a thrust dynamic pressure producing groove, and opposite ends of the first and second fine gaps meet each other through the third fine gap.

Abstract: A method for lubricating a part without leaving air bubbles includes the steps of assembling components so that an open end is formed for application of lubricating fluid and a fluid path is provided through which the lubricating fluid is to be circulated, introducing the lubricating fluid into the open end and applying a centrifugal force to the component by moving the component about a circular path so that the centrifugal force causes the lubricating fluid to be urged throughout the fluid path. The method is used in an embodiment to lubricate a dynamic pressure bearing having a gap between relatively moving parts. The gap has an open end into which the lubrication fluid is dripped and a closed end. During movement of the bearing about a circular path, the fluid is urged from the open end to the closed end.