A method for manufacturing a vibration actuator includes forming an elastic body integrally with a projection protruding from a surface of the elastic body, by press working. Forming the elastic body includes forming a bonding portion surrounding the projection, forming a contact portion at a top portion of the projection, forming a spring portion between the contact portion and the bonding portion, and forming a standing portion having a hollow structure, between the spring portion and the contact portion, so that the standing portion has a ring shape in a cross-sectional view in a direction parallel to the surface of the elastic member and that a space surrounded by the contact portion, the spring portion, and the standing portion. The spring portion is formed by press working, and the bonding portion is formed by press working.

A vibration type actuator includes a first member that has a vibrator; a second member that extends in a predetermined direction and has a friction sliding surface where the vibrator is press-contacted; a third member that rotatably holds the second member with respect to an axis parallel to the predetermined direction; and a pressing unit that generates a first force for rotating the second member with respect to the axis relative to the third member. The first member is sandwiched between the second member and the third member by the first force. The first member is driven in a driving direction parallel to the predetermined direction relative to the second member by the vibration of the vibrator.

A driving device includes a plurality of motive power generators that receive electric power supply and generate motive power, the plurality of motive power generators form a plurality of sets of motive power generators in which two or more of the motive power generators are electrically parallel-connected, and the plurality of sets of motive power generators are electrically series-connected. A driving device includes a plurality of vibrators that receive electric power supply and vibrate and provide drive power for driving a driven member to the driven member, the plurality of vibrators form a plurality of sets of vibrators in which two or more of the vibrators are electrically parallel-connected, and the plurality of sets of vibrators are electrically series-connected.

A manufacturing method of a vibrator includes processing a tip of a contact part arranged on an elastic body of the vibrator by lapping or grinding processing so that part of the tip has a plane shape in part of a spherical shape.

A multi-spoke-type ultrasonic motor has: a rotating shaft (1), a fastening sleeve cylinder (2), a spring (3), a rotor (4), a stator (5), a fastening screw (6), and piezoelectric ceramics (7). The rotor (4), the stator (5), the spring (3), and the fastening sleeve cylinder (2) are sequentially connected via the rotating shaft (1). The stator (5) is an annular metal plate having internal spoke-like teeth. The upper surface and the lower surface of the stator (5) are provided with identical stator spoke-like teeth for contacting the rotor (4). The rotor (4) and the stator (5) are in close contact under the effect of prestressing of the spring (3). The piezoelectric ceramics (7) are annular plates; upper and lower plates respectively, are affixed on the upper and lower surfaces of the stator (5). The motor is capable of increasing the output power of the ultrasonic motor.

A vibration actuator can be reduced in manufacturing cost and size thereof without using a magnet. An elastic body of a vibration element includes a base portion joined to an electromechanical energy conversion element, and a pair of contact portions extending from the base portion. The contact portions are brought into pressure contact with a driven element, by elastic deformation, in a third direction orthogonal to both of a first direction of relative motion of the vibration element and the driven element and a second direction as a thickness direction of the conversion element. When driving vibration is excited in the vibration element by applying a predetermined AC voltage to the conversion element, the contact portions apply frictional driving forces to the driven element, for moving the vibration element and the driven element relative to each other in the first direction.

A vibration wave motor includes an annular oscillator, and an annular moving member provided so as to be in press contact with the oscillator. The oscillator includes an annular vibrating plate, and an annular piezoelectric element provided on a first surface of the vibrating plate. The vibrating plate is in contact with the moving member via a second surface of the vibrating plate, which is opposite of the first surface. The piezoelectric element has a plurality of drive phase electrodes. When a driving region represents a region of the oscillator in which each drive phase electrode is provided, and a non-driving region represents a remaining region of the oscillator, a contact area ratio S1 between the vibrating plate and the moving member in the non-driving region is less than a contact area ratio S2 between the vibrating plate and the moving member in the driving region.

A vibrator including an electro-mechanical transducer and an elastic body that is fixed to the electro-mechanical transducer and that is provided with a projection, the projection having a hollow structure. The projection includes a contact portion having a first surface at a tip, the first surface being parallel to a first plane, a wall portion projecting towards an opposite side with respect to the electro-mechanical transducer, and a connection portion connecting the wall portion and the contact portion to each other. The connection portion having a spring property, and the contact portion includes a portion of which a cross-sectional area in a second plane that is parallel to the first plane increases as an increase of a distance between the portion and the first surface.

A driving device includes a vibrator; a friction member; a first guide portion that guides the vibrator or the friction member in a first direction when the vibrator vibrates so that the vibrator and the friction member move relative to each other, the first guide portion enabling rotation of the vibrator and the friction member around an axis in the first direction; a moving member that moves when the vibrator and the friction member move relative to each other, the moving member being connected to the member to be driven; and a second guide portion that guides the member to be driven in a second direction when the moving member moves. The moving member is connected to the member to be driven such that the moving member is rotatable and movable in a direction orthogonal to the first direction with respect to the member to be driven.

Provided is a vibration wave motor including: a first holding member; a second holding member; a first regulating region; and a second regulating region, wherein a position of a first contact region of the first holding member, which comes into contact with the first regulating region, is different from a position of a second contact region of the second holding member, which comes into contact with the second regulating region, and wherein a position of the first regulating region is different from a position of the second regulating region in the relative movement direction so that, in the relative movement direction, a difference between a distance from the first contact region to the first regulating region and a distance from the second contact region to the second regulating region is smaller than a difference between the position of the first contact region and the position of the second contact region.