Abstract: A medical power supply system includes: a medical device including an elongated insertion section, a power receiving unit including a power receiving member and movable relative to the insertion section in a longitudinal direction of the insertion section, and a biasing unit biasing the power receiving unit toward a distal end side of the insertion section; and a guide unit including a power transmitting unit including a power transmitting member, the insertion section being inserted into the guide unit. When the insertion section is inserted into the guide unit to a predetermined amount, the power receiving unit comes in contact with the power transmitting unit with being biased by the biasing unit, and the power transmitting member and the power receiving member face each other in an axial direction of the insertion section and have a positional relation in which wireless power transmission is possible.

Abstract: A light adjusting apparatus includes substrates arranged in parallel, each including an opening to pass light, a rotary shaft member which is rotatable around an axis perpendicular to the substrates and movable in an axial direction, a light adjusting section fixed integrally to the rotary shaft member in a space between the substrates and configured to move to an insertion position or a retracted position along with the rotation of the rotary shaft member and adjust light that passes through the opening, and a holding member configured to restrict the rotation of the light adjusting section that moves to one substrate side in the space from the insertion/retracted position and allow the rotation of the light adjusting section that moves to the other substrate side in the space.

Abstract: A medical power supply includes a medical instrument and a guide tube. The power receiving member is arranged radially outside the insertion portion, and when the insertion portion is inserted into the guide tube to a predetermined length such that the power transmitting member and the power receiving member are close to each other, a power transmitting side proximal end surface of the power transmitting member and a power receiving side distal end surface of the power receiving member face each other in an axial direction of the insertion portion and are in a positional relationship such that wireless power supply is possible.

Abstract: A medical power supply system includes: a medical device including an elongated insertion section, a power receiving unit including a power receiving member and movable relative to the insertion section in a longitudinal direction of the insertion section, and a biasing unit biasing the power receiving unit toward a distal end side of the insertion section; and a guide unit including a power transmitting unit including a power transmitting member, the insertion section being inserted into the guide unit. When the insertion section is inserted into the guide unit to a predetermined amount, the power receiving unit comes in contact with the power transmitting unit with being biased by the biasing unit, and the power transmitting member and the power receiving member face each other in an axial direction of the insertion section and have a positional relation in which wireless power transmission is possible.

Abstract: A light adjusting apparatus including a drive section provided with an axial magnet, a coil core member and a coil, a first substrate provided an opening and a first cut-out portion, a second substrate provided with an opening and a second cut-out portion, located at a predetermined distance from the first substrate, an incident light adjusting section to which the axial magnet is joined, and an axial magnet support member provided with a distance keeping portion that keeps a distance between the coil core member and the axial magnet to within a certain range and a dropout prevention portion that prevents dropout of the axial magnet from the first cut-out portion, the axial magnet support member being fixed to the coil core member, in which the incident light adjusting section is rotated by the drive section for adjusting the incident light.

Abstract: A battery (1) comprises a chargeable and dischargeable battery cell (23); a first electrode (21) and a second electrode (22) connected to the battery cell and electrically connected to an external electrode in a non-contact state; a switching circuit (24) which is provided in a battery circuit comprising the battery cell, the first electrode and the second electrode, and switches the current flowing in the battery circuit to alternating current or direct current; and an insulating housing (10) which houses the battery cell, the first electrode, the second electrode and the switching circuit therein.

Abstract: A light adjusting apparatus includes substrates arranged in parallel, each including an opening to pass light, a rotary shaft member which is rotatable around an axis perpendicular to the substrates and movable in an axial direction, a light adjusting section fixed integrally to the rotary shaft member in a space between the substrates and configured to move to an insertion position or a retracted position along with the rotation of the rotary shaft member and adjust light that passes through the opening, and a holding member configured to restrict the rotation of the light adjusting section that moves to one substrate side in the space from the insertion/retracted position and allow the rotation of the light adjusting section that moves to the other substrate side in the space.

Abstract: A variable hardness actuator includes a first flexible member to which a first electrode is fixed, a second flexible member disposed to be opposed to the first flexible member, a second electrode being fixed to the second flexible member, an insulating member configured to insulate the electrodes, a driving section configured to apply voltages to the electrodes, and an instructing section configured to instruct the driving section to apply a voltage. When the driving section applies the voltage according to the instruction from the instructing section, electrostatic attraction is generated between the electrodes and a frictional force is generated between the flexible members. The flexible members integrally harden against a bending force from an outside.

Abstract: A variable hardness actuator includes a flexible tubular member; plural particles of magnetic powder filling the tubular member; a coil wound around an outer circumference of the tubular member, surrounding the magnetic powder; a drive unit configured to supply electric current to the coil; and a directing unit used to give a direction to the drive unit to supply the electric current, wherein the coil generates a magnetic field using the electric current supplied from the drive unit in response to the direction from the directing unit, causing the plural particles of magnetic powder to magnetize spontaneously, magnetically couple together, and harden.

Abstract: The light control system includes command means (640) for outputting a command signal indicating a direction of rotation of the light control means (300), detection means (630) for detecting electromotive force generated in a coil (510), switch means (610) for connecting the coil to drive means (500, 302, 620) in a driving state in which current is supplied to the coil and connecting the coil to the detection means in a non-driving state in which electromotive force generated in the coil is detected, determination means (660) for determining a rotational state of a rotary shaft member (302), based on an output signal output from the detection means, and control means (650) for outputting a command for causing the drive means to output a drive signal, based on an output signal output from the determination means.

Abstract: A light adjusting apparatus including a drive section provided with an axial magnet, a coil core member and a coil, a first substrate provided an opening and a first cut-out portion, a second substrate provided with an opening and a second cut-out portion, located at a predetermined distance from the first substrate, an incident light adjusting section to which the axial magnet is joined, and an axial magnet support member provided with a distance keeping portion that keeps a distance between the coil core member and the axial magnet to within a certain range and a dropout prevention portion that prevents dropout of the axial magnet from the first cut-out portion, the axial magnet support member being fixed to the coil core member, in which the incident light adjusting section is rotated by the drive section for adjusting the incident light.

Abstract: The apparatus includes an upper substrate and a lower substrate, each of which has an optical aperture, at least one light control unit, a spacer arranged between the upper substrate and the lower substrate to provide a space in which the light control unit can move, and a drive unit arranged on the upper substrate to drive the light control unit. The drive unit includes a magnet arranged at a center of rotation of the light control unit and an electromagnetic drive source including a coil core and a winding coil, the coil core being arranged in such a way as to be opposed to the magnet. A positioning member is provided on the upper substrate. The distance between the coil core and the magnet is kept constant by the positioning member.

Abstract: The light control system includes command means (640) for outputting a command signal indicating a direction of rotation of the light control means (300), detection means (630) for detecting electromotive force generated in a coil (510), switch means (610) for connecting the coil to drive means (500, 302, 620) in a driving state in which current is supplied to the coil and connecting the coil to the detection means in a non-driving state in which electromotive force generated in the coil is detected, determination means (660) for determining a rotational state of a rotary shaft member (302), based on an output signal output from the detection means, and control means (650) for outputting a command for causing the drive means to output a drive signal, based on an output signal output from the determination means.

Abstract: A shape memory alloy actuator system includes a shape memory alloy actuator, a mobile object, an elastic member, a first regulating member, and a second regulating member, a detecting section which detects a resistance value of the shape memory alloy wire, a calculating section which calculates an electric current applied, an output section, a control section which controls the detecting section, the calculating section, the output section. The calculating section calculates a first resistance value at which, a proportion of a resistance change with respect to a change in a unit temperature changes from a first proportion to a second proportion which differs from the first proportion, and the control section carries out a position control of the shape memory alloy actuator by the first resistance value, when the shape memory alloy wire is to be elongated.

Abstract: The apparatus includes an upper substrate and a lower substrate, each of which has an optical aperture, at least one light control unit, a spacer arranged between the upper substrate and the lower substrate to provide a space in which the light control unit can move, and a drive unit arranged on the upper substrate to drive the light control unit. The drive unit includes a magnet arranged at a center of rotation of the light control unit and an electromagnetic drive source including a coil core and a winding coil, the coil core being arranged in such a way as to be opposed to the magnet. A positioning member is provided on the upper substrate. The distance between the coil core and the magnet is kept constant by the positioning member.

Abstract: A shape memory alloy actuator includes a shape memory alloy wire portion, a non-deformable portion, a wire portion which is formed by the shape memory alloy wire portion and the non-deformable portion, and which is inserted into a tube member, a movable body which is movable in a direction in which the length of the shape memory alloy wire portion changes, an elastic member which exerts an external force in a direction in which, the shape memory alloy wire portion elongates, and a fixed member to which, one end of the tube member and one end of the shape memory alloy wire portion are fixed. One end of the non-deformable portion which forms the wire portion is connected to the movable body, and the tube member includes therein the shape memory alloy wire portion, and includes therein at least a part of the non-deformable portion.

Abstract: A shape memory alloy actuator includes a shape memory alloy wire portion, a non-deformable portion, a wire portion which is formed by the shape memory alloy wire portion and the non-deformable portion, and which is inserted into a tube member, a movable body which is movable in a direction in which the length of the shape memory alloy wire portion changes, an elastic member which exerts an external force in a direction in which, the shape memory alloy wire portion elongates, and a fixed member to which, one end of the tube member and one end of the shape memory alloy wire portion are fixed. One end of the non-deformable portion which forms the wire portion is connected to the movable body, and the tube member includes therein the shape memory alloy wire portion, and includes therein at least a part of the non-deformable portion.

Abstract: An inertial driving actuator includes a fixing member, a moving element that is fixed to the fixing member and generates a small displacement by extension and contraction, an oscillation substrate that is fixed to the moving element and is moved linearly reciprocally by the small displacement, and a moving body that is moved by reciprocal movement of the oscillation substrate. The moving body has a first electrode. The oscillation substrate has a second electrode, the area of the facing portion of the second electrode and the first electrode changing continuously as the moving body moves. The actuator further includes a frictional force controller that controls a frictional force generated between the oscillation substrate and moving body, and a position detector that detects the position of the moving body on the basis of the electrostatic capacitance of the facing portion of the first electrode and the second electrode.

Abstract: A shape memory alloy actuator system includes a shape memory alloy actuator which has a shape memory alloy wire, a mobile object which is movable, an elastic member, a first regulating member, and a second regulating member, a detecting section which detects a resistance value of the shape memory alloy wire, a calculating section (a computing section) which calculates an electric current applied, an output section, a control section which controls the detecting section, a calculating section, an output section, and a reference resistance value calculating section. The shape memory alloy actuator, the detecting section, the calculating section, the output section, the control section, and the reference resistance value calculating section collectively form a resistance control circuit which carries out a position control of the shape memory alloy actuator.

Abstract: An inertial drive actuator includes a fixed member, a displacement generating mechanism which is connected to the fixed member, and which generates a minute displacement in a first direction and a second direction, a vibration substrate which reciprocates by the minute displacement generated by the displacement generating mechanism, a mobile object which is disposed on the vibration substrate, and which is movable by inertia, a driving mechanism which is connected to the mobile object, and which controls a frictional force between the mobile object and the vibration substrate by making an electromagnetic force to act in the mobile object by applying a current, a detecting electrode having a position detection function, which is disposed on a flat surface of the vibration substrate, to be facing the mobile object via an insulating body layer, and which is formed such that, an area face-to-face thereof with the mobile object either increases continuously or decreases continuously with the movement of the mobile