Vibration-type actuator and optical device using the same

What is claimed is: 1. A vibration-type linear actuator comprising: a drive unit having an electro-mechanical energy conversion element and a vibration body including a first projection; a driven body in pressure contact with the first projection; and a pressurizing unit configured to apply a pressure force between the first projection and the driven body, the pressurizing unit comprising: a pressurizing member; and a transfer unit configured to transfer the pressure force occurring in the pressurizing member to the vibration body, wherein the vibration body and the driven body are configured to change a relative position of the first projection and the driven body by vibration occurring in the vibration body when a drive voltage is applied to the electro-mechanical energy conversion element, wherein the transfer unit is disposed between the electro-mechanical energy conversion element and the pressurizing member while being in contact with both of the pressurizing member and one surface of the electro-mechanical energy conversion element, the one surface being opposite to a surface on which the vibration body is arranged, and wherein, in a direction that intersects perpendicularly with a relative moving direction of the vibration body and the driven body and that intersects perpendicularly with a pressurizing direction by the pressurizing unit, a length of an area in which the first projection is in contact with the driven body is shorter than a length of an area in which the pressurizing member is in contact with the transfer unit. 2. The vibration-type linear actuator according to claim 1 , further comprising: a vibration-body support member comprising elastic material and configured to support the vibration body; and an exterior member configured to support the vibration-body support member. 3. The vibration-type linear actuator according to claim 1 , wherein the transfer unit is in contact with the pressurizing member on a point or a line. 4. The vibration-type linear actuator according to claim 1 , wherein the transfer unit comprises: a pressure receiving member in contact with the pressurizing member, and a transfer member configured to disperse the pressure force from the pressurizing member, the transfer member being disposed between the electro-mechanical energy conversion element and the pressure receiving member. 5. The vibration-type linear actuator according to claim 1 , wherein the pressurizing member comprises a flat spring. 6. The vibration-type linear actuator according to claim 1 , further comprising: a guide member disposed to overlap with the driven body when viewed in the direction that intersects perpendicularly with the relative moving direction and that intersects perpendicularly with the pressurizing direction, and extends in the relative moving direction. 7. The vibration-type linear actuator according to claim 1 , further comprising a support member configured to support the pressurizing member, wherein the support member has a penetration hole in an area which at least overlaps with a movable area of the pressurizing member. 8. The vibration-type linear actuator according to claim 1 , further comprising a support member configured to support the pressurizing member, wherein the transfer unit includes a second projection, the support member includes a concave portion into which the second projection is fitted, and the concave portion does not regulate movement of the transfer unit in the pressurizing direction. 9. The vibration-type linear actuator according to claim 1 , wherein the vibration body includes two projections being in contact with the driven body, the two projections including the first projection and another projection. 10. The vibration-type linear actuator according to claim 1 , further comprising a support member configured to support the pressurizing member, wherein, in the direction that intersects perpendicularly with the relative moving direction and that intersects perpendicularly with the pressurizing direction, the length of the area in which the first projection is in contact with the driven body is shorter than a length of an area in which the pressurizing member is in contact with the support member. 11. The vibration-type linear actuator according to claim 4 , wherein, in the direction that intersects perpendicularly with the relative moving direction and that intersects perpendicularly with the pressurizing direction, the length of the area in which the first projection is in contact with the driven body is shorter than a length of an area in which the transfer member is in contact with the pressure receiving member. 12. The vibration-type linear actuator according to claim 9 , wherein in the direction that intersects perpendicularly with the relative moving direction and that intersects perpendicularly with the pressurizing direction, a length of an area in which the two projections are in contact with the driven body is shorter than the length of the area in which the pressurizing member is in contact with the transfer unit, and wherein the length of the area in which the two projections are in contact with the driven body is the maximum length including deviation between the two projections. 13. An optical device comprising: a lens; and a vibration-type linear actuator comprising: a drive unit having an electro-mechanical energy conversion element and a vibration body including a first projection; a driven body in pressure contact with the first projection; a pressurizing unit configured to apply a pressure force between the first projection and the driven body, the pressurizing unit comprising: a pressurizing member; and a transfer unit configured to transfer the pressure force occurring in the pressurizing member to the vibration body, wherein the vibration body and the driven body are configured to change a relative position of the first projection and the driven body by vibration occurring in the vibration body when a drive voltage is applied to the electro-mechanical energy conversion element, wherein the transfer unit is disposed between the electro-mechanical energy conversion element and the pressurizing member while being in contact with both of the pressurizing member and one surface of the electro-mechanical energy conversion element, the one surface being opposite to a surface on which the vibration body is arranged, and wherein, in a direction that intersects perpendicularly with a relative moving direction of the vibration body and the driven body and that intersects perpendicularly with a pressurizing direction by the pressurizing unit, a length of an area in which the first projection is in contact with the driven body is shorter than a length of an area in which the pressurizing member is in contact with the transfer unit.