JP2020032922A - Deposit removal device - Google Patents

Abstract

To provide a deposit removal device which improves performance of removing deposits while inhibiting increase in its size and costs.SOLUTION: A deposit removal device includes: a driving member which is driven by a motor; a moving member which is coupled to the driving member and moved by driving force of the motor; a pump which is coupled to the moving member which has been moved and is operated by the driving force of the motor to pump a pumped body; a nozzle part having a jet hole which jets the pumped body to an optical sensor; a wiper which is coupled to the moving member, has a wiping part for wiping the optical sensor, and moves with the moving member when the moving member moves to wipe the optical sensor with the wiping part.SELECTED DRAWING: Figure 6

Description

  The present invention relates to an attached matter removing device that removes attached matter attached to an optical sensor.

  In the attached matter removing device described in Patent Literature 1 below, compressed air or a cleaning liquid is jetted from a nozzle toward a camera (optical sensor) to remove the attached matter attached to the camera.

  Here, for example, by adding a wiper for wiping the camera to the attached matter removing device, it is possible to improve the performance of removing attached matter.

JP-A-2017-128188

  However, when a wiper is added to the attached matter removing device, a drive source (motor) for driving the wiper is required separately from a drive source (motor) for the pump for pumping compressed air or cleaning liquid. . For this reason, there is a problem that the size and cost of the attached matter removing device are increased.

  The present invention has been made in consideration of the above-described circumstances, and has as its object to provide an attached matter removing apparatus capable of improving the ability to remove attached matter while suppressing an increase in size and cost.

  One or more embodiments of the present invention are an adhering matter removing apparatus for removing an adhering matter attached to an optical sensor, wherein the motor, a driving member driven by the motor, and the driving member, A moving member that moves by a driving force of a motor, a pump that is connected to the moving member after the movement, and that operates by the driving force of the motor to pump the pressure-feeding object, and directs the pressure-feeding object toward the optical sensor. A nozzle unit having an ejection hole for ejecting, and a wiping unit connected to the moving member for wiping the optical sensor, wherein the wiping unit moves together with the moving member when the moving member moves, and And a wiper for wiping the sensor.

  One or more embodiments of the present invention are the attached matter removing device, wherein the nozzle portion is formed integrally with the wiper, and the wiping portion is provided in the nozzle portion.

  One or more embodiments of the present invention are the deposit removing device, wherein the wiping unit is disposed on one side of the wiper in the moving direction of the wiper.

  One or more embodiments of the present invention include a housing that houses the motor, the drive member, and the moving member, wherein the wiper is provided inside the housing and is connected to the moving member. , A connecting member movably supported by the housing, and an arm provided outside the housing and having the nozzle portion and connected to the connecting member so as to be integrally movable. It is an attached matter removing device.

  In one or more embodiments of the present invention, the wiper moves from a standby position separated from the optical sensor to an ejection position approaching the optical sensor when the moving member moves to one side in the moving direction. The pump is provided on one side in the moving direction of the moving member, and is provided on the other side in the moving direction of the moving member, and an air pump for pumping compressed air to the nozzle portion by operating. A cleaning liquid pump that pressure-flushes the cleaning liquid to the nozzle unit, wherein when the cleaning liquid pump is operated, the nozzle unit is prohibited from injecting the cleaning liquid that is pressure-fed to the outside, and when the air pump is operated, An adhering matter removing device that permits the jet of the cleaning liquid or compressed air fed to the outside in the nozzle portion.

  In one or more embodiments of the present invention, a nozzle valve is provided at the tip of the nozzle portion, and when the cleaning liquid pump is operated, the cleaning liquid pumped by the nozzle valve is discharged to the outside. This is a deposit removing device that prohibits the injection of the cleaning liquid or the compressed air that is injected by the nozzle valve when the air pump is operated.

  According to one or more embodiments of the present invention, it is possible to improve the performance of removing adhering substances while suppressing an increase in size and cost.

(A) is a front view showing the attached matter removing device according to the present embodiment as viewed from the front side, and (B) is a side view showing the attached matter removing device of (A) as seen from the right side. 1A is a side sectional view (an enlarged sectional view taken along the line 2A-2A in FIG. 1A) showing the right side of the attached matter removing apparatus shown in FIG. FIG. 2 is a side cross-sectional view (an enlarged cross-sectional view taken along line 2B-2B in FIG. 1A) showing the vicinity of the center of the attached matter removing apparatus shown in FIG. FIG. 1A is a cross-sectional view (an enlarged cross-sectional view taken along the line 3A-3A in FIG. 1A) showing the lower part of the attached matter removing apparatus shown in FIG. 1A is a cross-sectional view (an enlarged cross-sectional view taken along line 3B-3B in FIG. 1A) of the air pump of the attached matter removing apparatus shown in FIG. It is sectional drawing seen from the front side which fractured 3C part shown to (A). FIG. 2 is a front view showing the housing main body shown in FIG. 1A is a front view showing an initial state of the attached matter removing apparatus shown in FIG. 1A with a cover removed, and FIG. 1B is a rear view showing the state of FIG. FIG. 5A is a front view showing a state where the planetary gear is revolved to the first connection position from the state shown in FIG. 5A, and FIG. 5B is a rear view showing the state shown in FIG. FIG. (A) is explanatory drawing for demonstrating the operation | movement at the time of rotating a motor forward in the initial state of a deposit removal device, (B) is a figure when rotating a motor reversely from the state of (A). It is explanatory drawing for demonstrating operation | movement, (C) is explanatory drawing for demonstrating the state when a planetary gear revolves to one side of a revolving direction from the state of (B). FIG. 7A is an explanatory diagram for explaining a state in which the planetary gear is further revolved to one side in the revolving direction from the state of FIG. 7C and is arranged at the first connection position, and FIG. FIG. 5 is an explanatory diagram for explaining a state in which the internal gear is displaced upward from the state of FIG.

  Hereinafter, the attached matter removing device 10 according to the present embodiment will be described with reference to the drawings. The attached matter removing device 10 is mounted on a vehicle (automobile), and is configured as a device that sprays compressed air or a cleaning liquid onto a camera 90 as an “optical sensor” to remove attached matter attached to the camera 90. In the drawings, arrows UP, FR, and RH, which are appropriately shown, indicate the upper side, the front side, and the right side (one side in the width direction) of the attached matter removing apparatus 10, respectively. Further, in the following description, when the description is made using the directions of up and down, front and rear, and left and right, unless otherwise noted, the vertical direction, the front and rear direction of the attached matter removing apparatus 10, and the left and right direction of the apparatus are shown.

(About the entire attached matter removing apparatus 10)
As shown in FIGS. 1 and 5, the attached matter removing device 10 is generally formed in a substantially rectangular box shape having a thickness direction in the front-rear direction. A camera 90 is provided on the rear side of the lower part of the attached matter removing device 10. The camera 90 is formed in a substantially cylindrical shape as a whole, and the camera 90 is arranged such that the axis of the camera 90 is inclined downward toward the left side when viewed from the rear side. The base end of the camera 90 is fixed to the attached matter removing device 10 via a bracket 92. On the other hand, a lens 90 </ b> A is provided at the tip of the camera 90, and the lens 90 </ b> A is exposed from the camera 90 so that an image can be taken.

  The attached matter removing device 10 includes a housing 20 that forms an outer shell of the attached matter removing device 10, an air pump 50 as a “pump”, and a cleaning liquid pump 60 as a “pump”. Further, the attached matter removing device 10 transmits the driving force to the air pump 50 or the cleaning liquid pump 60 by switching the driving mechanism 30 for operating the air pump 50 and the cleaning liquid pump 60 and the transmission path of the driving force of the driving mechanism 30. And a switching mechanism 40. Further, the attached matter removing device 10 includes a wiper 70 having a nozzle portion 72B, and a tube 80 for connecting the air pump 50 and the cleaning liquid pump 60 to the wiper 70. Then, the compressed air as the “pressurized body” pumped by the air pump 50 or the cleaning liquid as the “pressurized body” pumped by the cleaning liquid pump 60 is injected into the spray hole 72C of the nozzle portion 72B of the wiper 70 (see FIG. 2). From the camera 90 (lens 90A) to clean the camera 90 (lens 90A). Hereinafter, each configuration of the attached matter removing device 10 will be described.

(About the housing 20)
As shown in FIGS. 1 to 3, the housing 20 is divided into two in the front-rear direction. Specifically, the housing 20 is configured to include a housing body 22 that forms a rear part of the housing 20 and a cover 24 that forms a front part of the housing 20.

<About the housing body 22>
As shown in FIG. 4, the housing body 22 is formed in a substantially rectangular box shape opened to the front side. A substantially central portion of the housing body 22 is configured as a gear housing portion 22A. In the gear housing portion 22A, a planetary gear 41 of the switching mechanism 40, an air pump gear 52 of the air pump 50, and a cleaning liquid pump gear 62 of the cleaning liquid pump 60, which will be described later. Is to be accommodated.

  A carrier accommodating portion 22B for accommodating a carrier 71 of the wiper 70 described later is formed at a substantially central portion of the gear accommodating portion 22A, and the carrier accommodating portion 22B is located rearward of the gear accommodating portion 22A. It is formed in a concave shape with one step down. The carrier accommodating portion 22B includes a circular first carrier accommodating portion 22B1 and a second carrier accommodating portion 22B2 extending leftward from the first carrier accommodating portion 22B1 when viewed from the front as viewed from the front side. It is configured. A circular support hole 22C for rotatably supporting a wiper 70 (carrier 71) described later is formed through the center of the bottom wall of the first carrier accommodating portion 22B1.

  The second carrier accommodating portion 22B2 is formed in a substantially fan shape centered on the central axis of the support hole 22C in a front view. Thus, a first arc surface 22D centering on the central axis of the support hole 22C is formed on the inner peripheral surface on the left side of the second carrier accommodating portion 22B2. A pair of upper and lower first moderation grooves 22EU and 22EL configured to be engageable with a wiper moderation mechanism 73, which will be described later, are formed in the first arcuate surface 22D. The pair of first moderation grooves 22EU and 22EL are formed in a substantially V-shape that is opened radially inward of the first arc surface 22D in a front view, and are spaced apart in the circumferential direction of the first arc surface 22D. Have been.

  Further, an internal gear housing 22F for housing an internal gear 42 of the switching mechanism 40 described later is formed in the housing body 22 at a position on the left side of the gear housing 22A. 22F is formed in a concave shape that is one step lower than the gear housing portion 22A. Further, the internal gear housing portion 22F extends in the up-down direction when viewed from the front, and is curved in an arc shape about the center axis of the support hole 22C. As a result, a second arc surface 22G is formed on the inner peripheral surface on the right side of the internal gear housing 22F at a position radially outside the first arc surface 22D, and the second arc surface 22G is It is formed in an arc shape that forms a concentric circle with the first arc surface 22D when viewed. A second moderation groove 22H configured to be engageable with a later-described switching moderation mechanism 44 is formed in a circumferential central portion of the second circular arc surface 22G, and the second moderation groove 22H is the second moderation groove 22H in a front view. It is formed in a substantially V-shape opened radially outward of the arc surface 22G.

  The right side portion of the housing body 22 is configured as a motor housing portion 22J for housing a motor 31 of the drive mechanism 30 described later, and the upper left side portion of the housing body 22 houses a control board 32 described later. Is configured as a substrate accommodating portion 22K. The motor housing 22J and the board housing 22K are partitioned by a partition wall 22L.

<About the cover 24>
As shown in FIGS. 1 to 3, the cover 24 is formed in a substantially rectangular plate shape with the front-rear direction being the plate thickness direction, and the outer shape of the cover 24 when viewed from the front is the same as the outer shape of the housing body 22. It is formed to form. The cover 24 is fixed to the housing body 22 so as to close the opening of the housing body 22.

  An air pump cover 24A for covering an air pump gear 52 of an air pump 50 described later is formed below the cover 24, and the air pump cover 24A is protruded forward. A cylinder fixing portion 24B for fixing a cylinder 51 of an air pump 50 described later is integrally formed above the air pump cover portion 24A, and the cylinder fixing portion 24B extends upward from the air pump cover portion 24A. Has been issued. The cylinder fixing portion 24B is formed in a substantially cylindrical shape, and the axis of the cylinder fixing portion 24B is inclined leftward as it goes upward in a front view.

  In addition, a cleaning liquid pump case portion 24C that constitutes a part of a cleaning liquid pump 60 described later is integrally formed on the upper portion of the cover 24. The cleaning liquid pump case portion 24C is formed in a substantially stepped cylindrical shape whose axial direction is the front-rear direction, and protrudes forward from the cover 24. Specifically, the diameter of the proximal end (rear end) of the cleaning liquid pump case 24C is set to be larger than the diameter of the distal end (front end) of the cleaning liquid pump case 24C. The tip of the cleaning liquid pump case 24C is configured as an inflow portion 24D. A tube (not shown) is connected to the inflow portion 24D so that the cleaning liquid is supplied into the cleaning liquid pump case 24C.

  Further, at the base end of the cleaning liquid pump case section 24C, a cleaning liquid discharge section 24E constituting a part of a cleaning liquid pump 60 described later is integrally formed, and the cleaning liquid discharge section 24E has an axial direction in the vertical direction. It is formed in a cylindrical shape and extends upward from the base end of the cleaning liquid pump case 24C. Thus, the inside and outside of the cleaning liquid pump case 24C are communicated with each other by the cleaning liquid discharge unit 24E.

  As shown in FIG. 3C, the inside of the cleaning liquid discharge section 24E is configured as a cleaning liquid discharge channel 24E1. A counterbore portion 24F for a valve for accommodating a cleaning liquid valve 67 to be described later is formed at a distal end portion of the cleaning liquid discharge channel 24E1, and the valve counterbore portion 24F has a larger diameter than the cleaning liquid discharge channel 24E1. Is formed. The bottom surface of the valve counterbore portion 24F is formed in a hemispherical shape that is open to the tip side of the cleaning liquid discharge portion 24E.

(About the drive mechanism 30)
As shown in FIGS. 2, 3A, and 5A, the drive mechanism 30 includes a motor 31 and a sun gear 35 as a “drive member”.
The motor 31 is arranged so that the vertical direction is the axial direction, and the output shaft 31A of the motor 31 extends downward from the motor main body 31B of the motor 31. The motor 31 is accommodated in the motor accommodating portion 22 </ b> J of the housing body 22 and is fixed to the housing 20. A control board 32 is electrically connected to the motor 31. The control board 32 is formed in a substantially rectangular shape with the front-rear direction being a plate thickness direction, housed in the board housing portion 22 </ b> K of the housing body 22, and is fixed to the housing body 22. Further, a control unit 33 (ECU) of the vehicle is electrically connected to the control board 32, and the motor 31 is driven by the control of the control unit 33. Further, a worm gear 34 is provided on the output shaft 31A of the motor 31 so as to be integrally rotatable. In the present embodiment, the worm gear 34 is formed separately from the output shaft 31A. However, the worm gear 34 may be formed integrally with the output shaft 31A.

  The sun gear 35 is configured as a two-stage gear whose vertical direction is the axial direction, and is arranged coaxially with the support hole 22 </ b> C of the housing body 22. The sun gear 35 includes a shaft portion 35A constituting a shaft core of the sun gear 35, a large-diameter gear portion 35B, and a small-diameter gear portion 35C disposed adjacent to the rear side of the large-diameter gear portion 35B. It is configured. The front end of the shaft portion 35A projects forward from the large-diameter gear portion 35B, and is rotatably supported by a bearing portion 24G formed on the cover 24. On the other hand, a rear end portion of the shaft portion 35A protrudes rearward from the small-diameter gear portion 35C, and is rotatably supported by a carrier 71 of a wiper 70 described later.

  Further, a plurality of external teeth are formed on the outer peripheral portion of the large-diameter gear portion 35B and the small-diameter gear portion 35C of the sun gear 35, and each external tooth is formed in the circumferential direction of the large-diameter gear portion 35B and the small-diameter gear portion 35C. It is formed over the entire circumference. The large-diameter gear portion 35 </ b> B is disposed adjacent to the left side of the worm gear 34 and meshes with the worm gear 34. Thus, when the motor 31 (the output shaft 31A) rotates forward or backward, the sun gear 35 rotates around the shaft 35A.

(About the switching mechanism 40)
As shown in FIGS. 3A, 5A, and 6A, the switching mechanism 40 includes a planetary gear 41 as a “moving member” and an internal gear 42. Have been.

<About planetary gear 41>
The planetary gear 41 is formed in a substantially disk shape with the vertical direction as the axial direction and a larger diameter than the small diameter gear portion 35 </ b> C of the sun gear 35. A plurality of external teeth are formed on the outer peripheral portion of the planet gear 41, and these external teeth are formed over the entire circumference of the planet gear 41 in the circumferential direction. The planet gear 41 is accommodated in the gear accommodating portion 22A of the housing body 22 on the left side of the sun gear 35, and the external teeth of the planet gear 41 are meshed with the external teeth of the small-diameter gear portion 35C of the sun gear 35. A connection hole 41A is formed through the center of the planet gear 41. The planetary gear 41 is rotatably supported by a carrier 71 of a wiper 70 described later at a portion of the connection hole 41A, and is configured to be able to revolve (movable) in the circumferential direction (around the axis) of the sun gear 35. I have.

  Specifically, when the sun gear 35 rotates counterclockwise in front view by driving the motor 31, the planetary gear 41 rotates in one of the revolving directions (moving directions) (arrows in FIGS. 7B and 7C). (D2 direction side) and is arranged at the first connection position shown in FIG. 6 (A). On the other hand, when the sun gear 35 rotates clockwise in front view by driving of the motor 31, the planetary gear 41 revolves in the other revolving direction (moving direction) in the other side (the direction of the arrow D1 in FIG. 8B). , At the second connection position shown in FIG. Although details will be described later, in the first connection position, the planetary gear 41 is connected to an air pump gear 52 to be described later, and the rotation of the planetary gear 41 to one side in the revolving direction is restricted by the air pump gear 52. It has become. On the other hand, at the second connection position, the planetary gear 41 is connected to the cleaning liquid pump gear 62 described later, and the rotation of the planetary gear 41 to the other side in the revolving direction is restricted by the cleaning liquid pump gear 62.

<About the internal gear 42>
The internal gear 42 includes a gear case 43, a switching moderation mechanism 44, a gear body 47, and a pair of buffer springs 48.
The gear case 43 is formed in a substantially rectangular block shape whose longitudinal direction is the vertical direction, and is curved in an arc shape along the internal gear housing portion 22F in a front view. The gear case 43 is configured to include a rear case portion 43A that forms a rear portion of the gear case 43, and a front case portion 43B that forms a front portion of the gear case 43. The rear case 43A is accommodated in the internal gear housing 22F so as to be movable in the circumferential direction of the sun gear 35 (the longitudinal direction of the internal gear housing 22F).

  As shown in FIGS. 7 and 8, a concave portion 43C for accommodating a later-described switching moderation mechanism 44 is formed in a longitudinally intermediate portion of the rear case portion 43A, and the concave portion 43C is opened to the right. It is formed in a concave shape. That is, in the radial direction of the second arc surface 22G of the housing body 22, the opening of the concave portion 43C is arranged so as to face the second arc surface 22G.

  The front case portion 43B protrudes forward from the internal gear housing portion 22F and is disposed on the left side of the planetary gear 41. The front case portion 43B is formed in a frame shape along the outer peripheral portion of the gear case 43 in a front view, and is formed in a substantially C-shape opened to the right. That is, a pair of holding walls 43D extending in the direction approaching each other from both ends in the longitudinal direction of the front case portion 43B are integrally formed in the opening of the front case portion 43B.

  The switching moderation mechanism 44 includes a spherical moderation ball 45 and a moderation spring 46 configured as a compression coil spring. The moderation ball 45 and the moderation spring 46 are arranged in the recess 43 </ b> C of the gear case 43. Specifically, the moderation ball 45 is arranged at the opening of the recess 43C, and the moderation spring 46 is arranged between the moderation ball 45 and the bottom surface of the recess 43C in a compressed and deformed state. Thereby, the moderation ball 45 is urged to the right (the second arc surface 22G side) by the urging force of the moderation spring 46, and is in contact with the second arc surface 22G. When the internal gear 42 is disposed at the longitudinally intermediate portion of the internal gear housing portion 22F, the moderation ball 45 and the second moderation groove 22H engage to form the gear case 43 (that is, the internal gear 42). Are held by the housing body 22 (the position shown in FIG. 7C, and this position in the internal gear 42 is hereinafter referred to as a “holding position”). On the other hand, when a load equal to or more than the predetermined value acts on the internal gear 42 in the longitudinal direction of the internal gear 42, the switching moderation mechanism 44 is operated, and the engagement state between the switching moderation mechanism 44 and the second moderation groove 22H is changed. It is configured to be released. That is, the moderation spring 46 is compressed and deformed, the moderation ball 45 escapes from the second moderation groove 22H, and the internal gear 42 moves to one side (the other side) in the longitudinal direction of the internal gear housing 22F. ing. Then, one end (the other side) in the longitudinal direction of the internal gear 42 abuts on the one end (the other side) in the longitudinal direction of the internal gear housing portion 22F, whereby the longitudinal direction of the internal gear 42 is made. The movement on one side (the other side) is restricted (the position shown in FIGS. 5 (A) and 6 (A). Hereinafter, this position in the internal gear 42 is referred to as "non-meshing". Position ").

  The gear body 47 is formed in a substantially elongated plate shape extending in the longitudinal direction of the gear case 43, and is housed in the front case portion 43 </ b> B of the gear case 43. The longitudinal dimension of the gear body 47 is set slightly smaller than the longitudinal dimension inside the front case 43B. Thus, the gear main body 47 is configured to be integrally movable with the gear case 43 in the longitudinal direction of the internal gear housing 22F.

  A pair of cutouts 47A are formed at both ends in the longitudinal direction of the gear main body 47, and the cutouts 47A are opened to the outside in the longitudinal direction of the gear main body 47 and to the left. A buffer spring 48 configured as a compression coil spring is disposed between the notch 47A and the left wall of the front case 43B in a compressed and deformed state. As a result, both ends in the longitudinal direction of the gear body 47 abut against the holding wall 43D of the gear case 43 due to the urging force of the buffer spring 48, and the relative movement of the gear body 47 to the right side with respect to the gear case 43 is restricted.

  The left side surface of the gear body 47 is curved in an arc shape along the left wall of the front case portion 43B, and is arranged to be separated rightward from the left wall of the front case portion 43B. Thus, the gear body 47 is configured to move to the left with respect to the gear case 43 by compressing and deforming the buffer spring 48.

  On the other hand, a plurality of internal teeth 47B are formed on the right side surface of the gear body 47. The internal teeth 47B are arranged side by side in the longitudinal direction of the gear body 47, protrude rightward from the opening of the front case portion 43B, and are configured to be able to mesh with the external teeth of the planetary gear 41. In addition, the tooth height of a pair of internal teeth 47B arranged on the outer side in the longitudinal direction of the gear body 47 among the plurality of internal teeth 47B is set lower than the tooth heights of the other internal teeth 47B.

Here, in a state where the planetary gear 41 is disposed at the first connection position (second connection position), the internal gear 42 is disposed at the upper (lower) non-meshing position, and the internal gear of the internal gear 42 is formed. 47B and the external teeth of the planetary gear 41 are set so as not to mesh with each other.
When the planetary gear 41 revolves from the first connection position (second connection position) to the other side (one side) in the revolving direction, the internal teeth 47B of the internal gear 42 mesh with the external teeth of the planetary gear 41, The internal gear 42 is configured to be displaced from the upper (lower) non-meshing position to the holding position side.

(About air pump 50)
As shown in FIG. 3B, the air pump 50 includes a cylinder 51, an air pump gear 52, a piston 53, a rod 55, and an air valve 56.

  The cylinder 51 is formed in a substantially bottomed cylindrical shape. The cylinder 51 is arranged coaxially with the cylinder fixing portion 24B of the cover 24, and the opening of the cylinder 51 is fitted into the cylinder fixing portion 24B from the upper left side. Thus, the cylinder 51 is fixed to the cover 24 in a state in which the cylinder 51 is inclined leftward as it goes upward in a front view (see FIG. 1A).

  On the bottom wall of the cylinder 51, an air discharge portion 51A is formed substantially at the center. The air discharge portion 51A is formed in a cylindrical shape, is arranged coaxially with the cylinder 51, and protrudes outward from the bottom wall of the cylinder 51. Thereby, the inside and the outside of the cylinder 51 are communicated by the air discharge portion 51A. The inside of the air discharge section 51A is configured as an air discharge flow path 51A1. A counterbore portion 51B for a valve for accommodating an air valve 56 to be described later is formed at the tip of the air discharge channel 51A1, and the valve counterbore portion 51B has a larger diameter than the air discharge channel 51A1. Is formed. The bottom surface of the valve counterbore portion 51B is formed in a hemispherical shape that is open to the tip end of the air discharge portion 51A.

  As shown in FIGS. 5A and 6A, the air pump gear 52 is arranged on one side of the planetary gear 41 in the revolving direction of the planetary gear 41. The air pump gear 52 includes a shaft portion 52A forming a shaft portion of the air pump gear 52, a gear portion 52B forming a rear portion of the air pump gear 52, and a rotating body 52C forming a front portion of the air pump gear 52. It is composed of

The shaft portion 52A is formed in a columnar shape with the front-back direction as the axial direction, and the rear end of the shaft portion 52A is rotatably supported by a bearing portion 22M formed on the bottom wall of the housing body 22. .
The gear portion 52B is formed in a disk shape with the front-rear direction being the plate thickness direction, is arranged coaxially with the shaft portion 52A, and is configured to be integrally rotatable with the shaft portion 52A. Further, the position of the gear portion 52B in the front-back direction matches the position of the planetary gear 41 in the front-back direction. Further, on the outer peripheral portion of the gear portion 52B, a plurality of external teeth are formed over the entire circumference of the gear portion 52B in the circumferential direction. When the planetary gear 41 revolves to the first connection position, the external teeth of the planetary gear 41 mesh with the external teeth of the gear portion 52B, and the planetary gear 41 and the air pump gear 52 are connected. (See FIG. 6A).

  The rotating body 52C is formed in a substantially columnar shape with the front-rear direction as the axial direction, is arranged coaxially with the shaft portion 52A, and is configured to be integrally rotatable with the shaft portion 52A. A connecting pin 52D is provided on the front surface of the rotating body 52C at a position radially outward with respect to the shaft portion 52A. The connecting pin 52D is formed in a cylindrical shape with the front-rear direction as the axial direction, and is rotated. It protrudes forward from the body 52C.

  As shown in FIG. 3B, the piston 53 is formed in a substantially columnar shape, is arranged coaxially with the cylinder 51, and is movably accommodated inside the cylinder 51. The outer diameter of the piston 53 is set substantially equal to the inner diameter of the cylinder 51. A groove 53A is formed on the outer periphery of the piston 53, and the groove 53A is formed over the entire circumference of the piston 53 in the circumferential direction. A ring-shaped seal member 54 is accommodated in the groove 53A, and the space between the cylinder 51 and the piston 53 is sealed by the seal member 54.

  Note that an intake hole (not shown) is formed through the piston 53 in the thickness direction of the piston 53, and the intake hole is closed by an intake valve (not shown). Then, when the piston 53 is displaced toward the opening side of the cylinder 51, the suction valve is opened and air is sucked into the cylinder 51. On the other hand, when the piston 53 is displaced to the bottom wall side of the cylinder 51, the closed state of the intake hole by the intake valve is maintained, the air in the cylinder 51 is compressed, and the compressed air is pumped from the air discharge portion 51A. Configuration.

  The rod 55 extends between the piston 53 and the air pump gear 52. Specifically, one end of the rod 55 is rotatably connected to a connection pin 52D of the air pump gear 52. On the other hand, the other end of the rod 55 is disposed inside the opening side of the cylinder 51 and is rotatably connected to the piston 53 with the front-rear direction being the axial direction. Thus, the piston 53 and the air pump gear 52 are connected by a crank mechanism constituted by the rod 55 and the rotating body 52C. Therefore, when the air pump 50 operates, the air pump gear 52 rotates, so that the piston 53 reciprocates in the cylinder 51 in the axial direction.

  The air valve 56 is configured to include a ball valve 57 and a valve opening / closing spring 58, and is configured as a so-called one-way valve. The ball valve 57 is formed in a spherical shape having a smaller diameter than the counterbore portion 51B for the valve of the air discharge portion 51A and having a larger diameter than the inner diameter of the air discharge passage 51A1. Further, the ball valve 57 is disposed in the counterbore portion 51B for the valve, and closes the air discharge passage 51A1. The valve opening / closing spring 58 is configured as a compression coil spring, and is disposed at the tip of the valve counterbore portion 51B. Specifically, the base end of the valve opening / closing spring 58 is locked to the ball valve 57, and the distal end of the valve opening / closing spring 58 is locked by a tube 80 described later. As a result, the ball valve 57 is urged toward the air discharge passage 51A1 by the urging force of the valve opening / closing spring 58. When the piston 53 moves to the bottom wall side of the cylinder 51, the air valve 56 is operated by the internal pressure of the cylinder 51 (the valve opening / closing spring 58 is compressed and deformed), and the air discharge passage 51A1 is opened. The compressed air is sent from the air discharge section 51A to a wiper 70 described later.

(About the cleaning liquid pump 60)
As shown in FIG. 2B, the cleaning liquid pump 60 includes a stopper member 61, a cleaning liquid pump gear 62, a pump screw 63, a rotation restricting mechanism 64, and a cleaning liquid valve 67. .

  The stopper member 61 is formed in a substantially disk shape with the front-rear direction being the plate thickness direction, and is fitted into the base end of the cleaning liquid pump case portion 24 </ b> C of the cover 24. As a result, the base end of the cleaning liquid pump case 24C is closed by the stopper member 61. The cleaning liquid is stored in the cleaning liquid pump case section 24C by flowing the cleaning liquid from the inflow section 24D of the cleaning liquid pump case section 24C.

  At the center of the stopper member 61, an insertion hole 61A through which a shaft portion 62A of a cleaning liquid pump gear 62 described later is inserted is formed. A support column 61B is formed integrally with the upper portion of the stopper member 61. The support column 61B extends rearward from the stopper member 61 and is provided in the upper end of the gear housing portion 22A of the housing body 22. Are located. A key 61C is integrally formed on the lower surface of the support column 61B, and the key 61C is formed in a rectangular column shape extending in the front-rear direction.

  As shown in FIGS. 5A and 6B, the cleaning liquid pump gear 62 is disposed on the other side of the planetary gear 41 in the revolving direction of the planetary gear 41, and the gear housing portion in the housing body 22. It is housed in the upper end of 22A. The cleaning liquid pump gear 62 has a shaft portion 62A that forms a shaft core of the cleaning liquid pump gear 62. The shaft portion 62A is formed in a columnar shape with the front-rear direction as the axial direction, and is arranged coaxially with the insertion hole 61A of the stopper member 61. The rear end of the shaft 62A is rotatably supported by a bearing 22P formed on the housing body 22. On the other hand, a portion on the front end side of the shaft portion 62A of the cleaning liquid pump gear 62 is inserted through the insertion hole 61A of the stopper member 61 and is rotatably supported by the stopper member 61. The front end of the shaft 62A is arranged inside the cleaning liquid pump case 24C. Although not shown, a seal member is provided between the insertion hole 61A and the shaft portion 62A, and the space between the shaft portion 62A and the stopper member 61 is sealed by the seal member.

  Further, a gear portion 62B is formed integrally with the rear end side portion of the shaft portion 62A, and the gear portion 62B is formed in a disk shape with the front-rear direction being the plate thickness direction. The position of the gear portion 62B in the front-rear direction coincides with the position of the planetary gear 41 in the front-rear direction. Further, a plurality of external teeth are formed on the outer circumference of the gear portion 62B over the entire circumference of the gear portion 62B in the circumferential direction. Then, at the second connection position of the planetary gear 41, the external teeth of the planetary gear 41 mesh with the external teeth of the gear portion 62B, so that the planetary gear 41 and the cleaning liquid pump gear 62 are connected (FIG. 5). (A)).

  As shown in FIG. 2B, the pump screw 63 is formed in a substantially stepped cylindrical shape with the front-rear direction being the axial direction, and is arranged coaxially with the cleaning liquid pump gear 62 inside the cleaning liquid pump case portion 24C. Have been. The base end of the pump screw 63 is connected to the front end of the shaft 62A of the cleaning liquid pump gear 62 so as to be integrally rotatable. Further, a plurality of (three in this embodiment) wing portions 63A are formed integrally with the pump screw 63, and the wing portions 63A are arranged at equal intervals in the circumferential direction of the pump screw 63. . Then, the planetary gear 41 rotates at the second connection position, and the pump screw 63 rotates clockwise in a front view, so that the cleaning liquid in the cleaning liquid pump case section 24C causes a tube 80 to be described later from the cleaning liquid discharge section 24E to pass through. The wiper 70 is pressure-fed to the wiper 70.

  The rotation restricting mechanism 64 is configured to include a male screw portion 65 formed on the outer peripheral portion of the shaft portion 62A of the cleaning liquid pump gear 62, and a collar 66 configured to be screwable with the male screw portion 65.

  The male screw portion 65 is formed at a longitudinally intermediate portion of the shaft portion 62A, and is disposed adjacent to the rear side of the stopper member 61. Further, the male screw portion 65 is disposed at a position separated from the front side of the gear portion 62B of the cleaning liquid pump gear 62 by a predetermined distance.

  The collar 66 is formed in a cylindrical shape whose axial direction is the front-back direction. Further, a female screw portion 66 </ b> A configured to be screwable with the male screw portion 65 is formed on the inner peripheral portion of the collar 66. Then, the shaft portion 62A is inserted into the collar 66, and the collar 66 is disposed between the gear portion 62B and the male screw portion 65 (the position shown by a solid line in FIG. , This position in the collar 66 is referred to as a “non-regulated position”). In this non-regulated position, the threaded engagement between the female thread 66A of the collar 66 and the male thread 65 of the cleaning liquid pump gear 62 is in the initial state. That is, when the cleaning liquid pump gear 62 rotates clockwise in the front view at the non-restricted position, the initial state of the screwing of the cleaning liquid pump gear 62 with the collar 66 is maintained, and the collar 66 is maintained at the non-restricted position. Has become.

  On the other hand, when the cleaning liquid pump gear 62 rotates counterclockwise in front view at the non-regulated position, the female screw portion 66A of the collar 66 is screwed into the male screw portion 65, and the collar 66 is moved in the axial direction of the shaft portion 62A. Along the front side (stopper member 61 side). When the collar 66 comes into contact with the stopper member 61, the displacement of the collar 66 to the front side is restricted, and the rotation of the cleaning liquid pump gear 62 is stopped (in FIG. This position in the collar 66 is hereinafter referred to as a “regulation position”.)

  A key groove 66B that is open upward is formed in an upper part of the outer periphery of the collar 66, and the key groove 66B is penetrated in the front-rear direction (the axial direction of the collar 66). The key 61C of the stopper member 61 is disposed so as to be relatively movable in the key groove 66B. Thus, when the collar 66 is displaced between the non-restricted position and the restricted position, the rotation of the collar 66 around the shaft portion 62A is restricted by the key 61C.

  As shown in FIG. 3C, the cleaning liquid valve 67 includes a ball valve 68 and a valve opening / closing spring 69, and is configured as a so-called one-way valve. The ball valve 68 is formed in a spherical shape having a smaller diameter than the counterbore portion 24F for the valve of the cleaning liquid discharge portion 24E of the cover 24 and a diameter larger than the inner diameter of the cleaning liquid discharge passage 24E1. Then, the ball valve 68 is disposed in the valve counterbore portion 24F, and closes the cleaning liquid discharge flow path 24E1. The valve opening / closing spring 69 is configured as a compression coil spring, and is disposed at the distal end of the valve counterbore 24F. Specifically, the base end of the valve opening / closing spring 69 is locked to the ball valve 68, and the distal end of the valve opening / closing spring 69 is locked to a tube 80 described later. Thus, the ball valve 68 is urged toward the cleaning liquid discharge channel 24E1 by the urging force of the valve opening / closing spring 69. When the cleaning liquid pump 60 is operated, the cleaning liquid valve 67 is actuated by the cleaning liquid that is sent under pressure (the valve opening / closing spring 69 is compressed and deformed), and the cleaning liquid discharge flow path 24E1 is opened. To a wiper 70 described later.

(About the wiper 70)
As shown in FIG. 2, FIG. 3 (A), FIG. 5 (B), and FIG. 6 (B), the wiper 70 includes a carrier 71 as a “connecting member”, a wiper arm 72 as an “arm”, It is configured to include a wiper moderation mechanism 73 (in a broad sense, an element grasped as a “moderation mechanism”), a nozzle valve 76, and a wiping unit 79.
As shown in FIGS. 5A and 6A, the carrier 71 is formed in a substantially elongated plate shape with the front-rear direction being the plate thickness direction. A portion on one end side of the carrier 71 is configured as a first carrier portion 71 </ b> A, and the first carrier portion 71 </ b> A is formed in a substantially disk shape, and the first carrier accommodation portion of the carrier accommodation portion 22 </ b> B in the housing body 22. 22B1. At the center of the first carrier portion 71A, a columnar rotating shaft 71A1 protruding downward is integrally formed. The rotation shaft 71A1 is inserted into the support hole 22C of the housing main body 22, and is rotatably supported by the housing main body 22. Further, a support concave portion 71A2 opened to the front side is formed at the center of the first carrier portion 71A. A portion of the sun gear 35 on the rear end side of the shaft portion 35A is rotatably inserted into the support recess 71A2. As a result, the sun gear 35 is rotatably supported by the carrier 71, and the rotation axes of the sun gear 35 and the carrier 71 match.

  The other end portion of the carrier 71 is configured as a second carrier portion 71B. The second carrier portion 71B is formed in a substantially rectangular plate shape, and extends leftward (radially outward) from the first carrier portion 71A. The second carrier portion 71B is accommodated in the second carrier accommodating portion 22B2 of the carrier accommodating portion 22B of the housing main body 22, and is disposed adjacent to the rear side of the planetary gear 41. A connecting shaft 71B1 is integrally formed on the front surface of the distal end portion of the second carrier portion 71B, and the connecting shaft 71B1 is formed in a cylindrical shape with the front-rear direction being the axial direction. The connection shaft 71B1 is inserted into the connection hole 41A of the planetary gear 41, and rotatably supports the planetary gear 41. Thereby, the carrier 71 and the planet gear 41 are connected, and when the planet gear 41 revolves, the carrier 71 rotates (moves) around the rotation shaft 71A1 (that is, the circumferential direction of the sun gear 35) together with the planet gear 41. , The first connection position or the second connection position.

  Further, a concave portion 71B2 for accommodating a wiper moderation mechanism 73 described later is formed at a distal end portion of the second carrier portion 71B, and the concave portion 71B2 is located on the distal end side of the second carrier portion 71B (the first carrier portion 71A). Is formed in a concave shape that is open to the outside in the radial direction. That is, the opening of the recess 71B2 is disposed so as to face the first circular surface 22D of the second carrier accommodating portion 22B2.

  The wiper arm 72 is formed in a substantially elongated plate shape with the front-rear direction being a plate thickness direction, and is disposed between the housing main body 22 and the camera 90. A circular fitting hole 72 </ b> A is formed in the base end portion of the wiper 70 so as to penetrate in the front-rear direction. The rotating shaft 71A1 of the carrier 71 is fitted into the fitting hole 72A, and the wiper arm 72 is fixed to the carrier 71. Thus, when the carrier 71 rotates between the first connection position and the second connection position, the wiper arm 72 rotates (moves) integrally with the carrier 71 around the rotation shaft 71A1. Specifically, at the second connection position of the carrier 71, the wiper arm 72 extends in the left-right direction, and the tip end of the wiper arm 72 is disposed at a position separated from the lens 90A of the camera 90 to the upper left side. (This is the position shown in FIG. 5B, and this position on the wiper 70 is hereinafter referred to as a “standby position”). On the other hand, when the carrier 71 rotates from the second connection position to the first connection position, the wiper arm 72 rotates clockwise as viewed from the rear side so that the tip of the wiper arm 72 approaches the lens 90A of the camera 90. Has become. More specifically, when viewed from the rear side, the wiper arm 72 wraps with the camera 90 and extends along the axial direction of the camera 90 (the position shown in FIG. , This position on the wiper 70 is referred to as the “ejection position”).

  At the tip of the wiper arm 72, a nozzle portion 72B extending rearward is formed. An injection hole 72 </ b> C that opens to the base end side of the wiper arm 72 is formed at the distal end (rear end) of the nozzle 72 </ b> B. Then, at the ejection position of the wiper 70, the ejection hole 72 </ b> C is arranged to face the lens 90 </ b> A of the camera 90 in the axial direction of the camera 90. On the other hand, an inlet 72D is formed at the base end of the wiper arm 72. The inlet 72D is formed in a cylindrical shape, and is bent downward in a substantially inverted L-shape when viewed from the rear side. I have. A tube 80, which will be described later, is connected to the inlet 72 </ b> D. The compressed air fed by the air pump 50 and the cleaning liquid pumped by the cleaning liquid pump 60 are supplied to the wiper arm 72.

  Further, inside the wiper arm 72, a flow path 72E for communicating the inlet 72D and the injection hole 72C is formed. At a position adjacent to the injection hole 72C, a valve housing portion 72F for housing a nozzle valve 76 to be described later is formed at a distal end portion of the flow passage 72E, and the valve housing portion 72F is connected to the adjacent flow passage 72E. It is formed with a larger diameter than that. Then, the bottom surface of the valve housing portion 72F is formed in a hemispherical shape opened downward.

  The wiper moderation mechanism 73 includes a spherical moderation ball 74 and a moderation spring 75 configured as a compression coil spring. The moderation ball 74 and the moderation spring 75 are arranged in the concave portion 71B2 of the carrier 71. Specifically, the moderation ball 74 is arranged at the opening of the recess 71B2, and the moderation spring 75 is arranged between the moderation ball 74 and the bottom surface of the recess 71B2 in a compressed and deformed state. As a result, the moderating ball 74 is urged to the left (on the side of the first circular surface 22D) by the urging force of the moderating spring 75 and is in contact with the first circular surface 22D. When the carrier 71 is located at the first connection position, the moderation ball 74 and the lower first moderation groove 22EL are engaged, and the wiper 70 is held at the injection position. On the other hand, when the carrier 71 is located at the second connection position, the moderation ball 74 and the upper first moderation groove 22EU are engaged, and the wiper 70 is held at the standby position.

  On the other hand, when a load equal to or more than the predetermined value acts on the carrier 71 in the rotation direction of the carrier 71, the wiper moderation mechanism 73 is operated, and the engagement state between the wiper moderation mechanism 73 and the first moderation grooves 22EU and 22EL is released. Configuration. That is, the moderation spring 75 is compressed and deformed, the moderation ball 74 escapes from the first moderation grooves 22EU and 22EL, and the carrier 71 rotates together with the planetary gear 41.

  The nozzle valve 76 includes a ball valve 77 and a valve opening / closing spring 78, and is configured as a so-called one-way valve. The ball valve 77 is formed in a spherical shape having a smaller diameter than the valve housing portion 72F of the wiper arm 72 and a larger diameter than the inner diameter of the flow path 72E. And the ball valve 77 is arrange | positioned in the valve accommodation part 72F, and has closed the flow path 72E. The valve opening / closing spring 78 is configured as a compression coil spring, and is disposed at a distal end of the valve housing 72F. Specifically, the base end of the valve opening / closing spring 78 is locked by the ball valve 77, and the tip of the valve opening / closing spring 78 is locked by the wiper arm 72. Thus, the ball valve 77 is urged toward the flow path 72E by the urging force of the valve opening / closing spring 78.

Here, in the present embodiment, the cleaning liquid pump 60 and the air pump 50 are configured such that a pressure difference between the pumps during operation occurs. The valve opening / closing spring 78 does not operate with the load generated on the nozzle valve 76 when the cleaning liquid is pumped, and the valve opening / closing spring 78 operates with the load generated on the nozzle valve 76 when compressed air is pumped. Thus, the load of the valve opening / closing spring 78 is set.
For this reason, when the cleaning liquid pump 60 is operated, the cleaning liquid pumped by the cleaning liquid pump 60 is pressure-fed into the flow path 72E of the wiper arm 72 via a tube 80 described later. At this time, the nozzle valve 76 is operated. Instead, the cleaning liquid is stored in the tube 80 and the flow path 72E.
On the other hand, when the air pump 50 operates, the nozzle valve 76 operates by the compressed air pumped by the air pump 50, and the ball valve 77 opens the flow path 72E. Thus, the compressed air sent to the wiper arm 72 is injected from the injection hole 72C. Further, when the air pump 50 is operated in a state where the cleaning liquid is stored in the tube 80 and the flow path 72E, the cleaning liquid is injected from the injection hole 72C by the compressed air.

  The wiping portion 79 is provided on the right side surface of the tip portion of the nozzle portion 72B (the surface facing the lens 90A of the camera 90 at the ejection position). More specifically, the wiping unit 79 is disposed on one side in the rotation direction (moving direction) of the wiper 70 with respect to the injection hole 72C of the nozzle unit 72B. The wiping portion 79 is made of a flexible member such as rubber, and protrudes from the right side surface of the nozzle portion 72B toward the base end of the wiper arm 72. When the wiper 70 rotates from the standby position to the ejection position, the wiping unit 79 is configured to contact the lens 90A of the camera 90 and wipe the surface of the lens 90A.

(About tube 80)
As shown in FIG. 1, the tube 80 is formed of a flexible member such as rubber, and connects the air pump 50 and the cleaning liquid pump 60 to the wiper 70. A branch portion 80A is formed at the base end portion of the tube 80, and the base end of the tube 80 is formed in a forked shape. One of the proximal ends of the tube 80 is configured as an air pump connection portion 80B connected to the air pump 50. The air discharge portion 51A of the air pump 50 is fitted into the air pump connection portion 80B, and the air pump connection portion 80B is fixed to the air discharge portion 51A. The other end of the base end of the tube 80 is configured as a cleaning liquid pump connection portion 80C connected to the cleaning liquid pump 60. The cleaning liquid discharge section 24E of the cleaning liquid pump 60 is fitted into the cleaning liquid pump connection section 80C, and the cleaning liquid pump connection section 80C is fixed to the cleaning liquid discharge section 24E.

  The distal end portion of the tube 80 is configured as a nozzle connection portion 80D connected to the wiper 70. Then, the inlet portion 72D of the wiper 70 is fitted into the nozzle connection portion 80D, and the nozzle connection portion 80D is fixed to the inlet portion 72D. Thus, the compressed air pumped by the air pump 50 and the cleaning liquid pumped by the cleaning liquid pump 60 are fed through the tube 80 into the flow path 72E of the wiper 70 (wiper arm 72).

(Effects)
Next, with reference to FIGS. 7A to 7C, FIGS. 8A and 8B, the operation and effect of the present embodiment will be described while explaining the operation of the attached matter removing apparatus 10. FIG. 7 (A) to 7 (C), 8 (A) and 8 (B), the left side diagram schematically shows the positional relationship between the wiper 70 and the camera 90 in a front view, In the center figure, the state of the internal gear 42 and the carrier 71 of the wiper 70 in a front view is schematically shown, and in the right figure, the states of the drive mechanism 30 and the switching mechanism 40 in a front view are schematically shown. ing.

  First, the state shown in FIG. 7A is set as the initial state of the extraneous matter removing device 10. In this initial state, the planet gear 41 and the carrier 71 are arranged at the second connection position, and the planet gear 41 is connected to the cleaning liquid pump gear 62 of the cleaning liquid pump 60. As a result, the cleaning liquid pump 60 is in an operable state. At this time, the moderation ball 74 of the wiper moderation mechanism 73 of the wiper 70 is engaged with the upper first moderation groove 22EU of the housing body 22, and the wiper 70 is held at the standby position. Specifically, the nozzle portion 72B of the wiper 70 is disposed at a position separated from the lens 90A of the camera 90 diagonally upward and to the left. Further, at this time, the internal gear 42 is disposed at the lower non-meshing position, and the meshing state between the internal teeth 47B of the internal gear 42 (gear body 47) and the external teeth of the planetary gear 41 is released. ing.

  In this state, when the motor 31 is rotated forward under the control of the control unit 33, the sun gear 35 rotates clockwise (see the arrow A1 in FIG. 7A). In this state, since the meshing state between the planetary gear 41 and the internal gear 42 (gear body 47) has been released, the planetary gear 41 is allowed to rotate. Therefore, the planetary gear 41 rotates counterclockwise (see the arrow B1 in FIG. 7A). Thus, the cleaning liquid pump gear 62 rotates clockwise (see the arrow C1 in FIG. 7A), and the cleaning liquid pump 60 operates.

  When the cleaning liquid pump 60 is operated, the pump screw 63 of the cleaning liquid pump 60 rotates, and the cleaning liquid in the cleaning liquid pump case 24C is pumped to the cleaning liquid discharge unit 24E. At this time, the cleaning liquid fed under pressure pushes the ball valve 68 of the cleaning liquid valve 67 to operate the cleaning liquid valve 67. Thus, the cleaning liquid is pressure-fed from the cleaning liquid discharge flow path 24E1 of the cleaning liquid discharge unit 24E into the flow path 72E of the wiper 70 via the tube 80. In addition, when the cleaning liquid pump 60 is operated, the force for pumping the cleaning liquid pump 60 is set to be weak, and the nozzle valve 76 does not operate. Therefore, the cleaning liquid is stored in the tube 80 and the flow path 72E of the wiper 70. . In the operation of the cleaning liquid pump 60, the cleaning liquid is also pressure-fed to the air pump connection portion 80B side of the tube 80. However, since the air discharge portion 51A of the air pump 50 is provided with the air valve 56, the cleaning liquid is supplied. Inflow into the cylinder 51 is suppressed.

  When the motor 31 is rotated under the control of the control unit 33 after the operation of the cleaning liquid pump 60, the sun gear 35 rotates counterclockwise as shown in FIG. 7B (see the arrow A2 in FIG. 7B). To rotate. Further, at this time, since the meshing state between the planetary gear 41 and the internal gear 42 (gear body 47) has been released, the planetary gear 41 once rotates clockwise (see the arrow B2 in FIG. 7B). . Accordingly, the cleaning liquid pump gear 62 rotates counterclockwise (see the arrow C2 in FIG. 7B). Further, at this time, the engagement state between the wiper moderation mechanism 73 of the wiper 70 and the upper first moderation groove 22EU is maintained, and the state where the wiper 70 is disposed at the standby position is maintained.

  When the cleaning liquid pump gear 62 rotates counterclockwise, the rotation restricting mechanism 64 of the cleaning liquid pump 60 operates. That is, the collar 66 arranged at the non-restricted position is screwed into the male screw portion 65 of the shaft portion 62A of the cleaning liquid pump gear 62, and the collar 66 is displaced forward along the shaft portion 62A. When the collar 66 reaches the regulation position, the collar 66 contacts the stopper member 61 of the cleaning liquid pump 60. As a result, the displacement of the collar 66 to the front side is restricted, and the rotation of the cleaning liquid pump gear 62 stops.

  When the rotation of the cleaning liquid pump gear 62 stops, the rotation of the planetary gear 41 at the second connection position stops. On the other hand, since the motor 31 is rotating in the reverse direction, a rotational force in the circumferential direction of the sun gear 35 acts on the planetary gear 41 at a portion of the external gear meshed with the sun gear 35. Therefore, the orbital movement of the planetary gear 41 from the second connection position to one side in the orbital direction (see the arrow D2 in FIG. 7B) starts.

  When the planet gear 41 starts revolving in one direction in the revolving direction, the external teeth of the planet gear 41 mesh with the internal teeth 47B of the internal gear 42 (gear body 47), and the planet gear 41 and the cleaning liquid pump gear 62 The meshing state is released. Therefore, the clockwise rotation of the planetary gear 41 is restarted. At this time, since the external teeth of the planetary gear 41 are meshed with the internal teeth 47B of the internal gear 42 (gear body 47), the rotation of the planetary gear 41 causes the internal gear 42 to move to the lower non-meshing position. From the inner gear housing 22F in the longitudinal direction of the internal gear housing 22F (see the arrow E2 in FIG. 7C). Then, as shown in FIG. 7C, when the internal gear 42 reaches the longitudinally intermediate portion of the internal gear housing portion 22F, the moderation ball 45 of the switching moderation mechanism 44 in the internal gear 42 is moved to the housing 20. , The internal gear 42 is held at the holding position.

  When the planetary gear 41 starts revolving in one of the revolving directions, the wiper moderation mechanism 73 is operated by the rotational force acting on the planetary gear 41 from the sun gear 35. That is, the moderation spring 75 of the wiper moderation mechanism 73 is compressed and deformed, and the moderation ball 74 escapes from the first moderation groove 22EU. Thereby, the carrier 71 rotates together with the planetary gear 41 from the second connection position to one side in the revolving direction. As a result, the wiper 70 rotates from the standby position to one side around the rotation shaft 71A1 (the ejection position side), and the nozzle portion 72B of the wiper 70 approaches the lens 90A of the camera 90.

  As shown in FIG. 8 (A), when the planetary gear 41 further revolves to one side in the revolving direction from the state shown in FIG. 7 (C) and reaches the first connection position, the external teeth of the planetary gear 41 Meshes with the external teeth of the air pump gear 52 (gear portion 52B), and the planetary gear 41 and the air pump gear 52 are connected. As a result, the planet gear 41 stops revolving to one side in the revolving direction, and the planet gear 41 rotates clockwise at the first connection position.

  At this time, the carrier 71 that rotates together with the planetary gear 41 is disposed at the first connection position. Thereby, the wiper 70 is arranged at the injection position. That is, in the axial direction of the camera 90, the injection hole 72 </ b> C of the wiper 70 is arranged at a position facing the lens 90 </ b> A of the camera 90. When the wiper 70 is located at the ejection position, the wiping unit 79 of the wiper 70 contacts the lens 90A of the camera 90 to wipe the lens 90A. Further, when the carrier 71 reaches the first connection position, the moderation ball 74 of the wiper moderation mechanism 73 is engaged with the lower first moderation groove 22EL, and the carrier 71 (that is, the wiper 70) is at the injection position. Will be retained.

  On the other hand, the internal gear 42 is located at the holding position, and the internal teeth 47 </ b> B of the internal gear 42 (gear body 47) mesh with the external teeth of the planetary gear 41. Then, as described above, at the first connection position, the planetary gear 41 rotates clockwise. As a result, a rotational force in the circumferential direction of the planetary gear 41 acts on the internal gear 42 (gear body 47) from the planetary gear 41, and the switching moderation mechanism 44 is operated by the rotational force. That is, the moderation spring 46 of the switching moderation mechanism 44 is compressed and deformed, and the moderation ball 45 escapes from the second moderation groove 22H. This allows the internal gear 42 to be displaced upward from the holding position, and the internal gear 42 is displaced upward from the holding position (see the arrow E2 in FIG. 8A).

  Then, as shown in FIG. 8B, when the internal gear 42 reaches the upper non-meshing position, the internal teeth 47B of the internal gear 42 (gear body 47) mesh with the external teeth of the planetary gear 41. The state is released. Therefore, the continuation of the clockwise rotation of the planetary gear 41 is allowed.

  Further, at the first connection position, since the planetary gear 41 rotates clockwise, the air pump gear 52 rotates by the rotation of the planetary gear 41, and the air pump 50 operates. Specifically, when the air pump gear 52 rotates, the piston 53 moves to the opening side of the cylinder 51, and air is sucked into the cylinder 51. When the air pump gear 52 further rotates, the piston 53 reverses and moves to the bottom wall side of the cylinder 51, and the compressed air in the cylinder 51 is sent to the air discharge portion 51A by pressure. At this time, the ball valve 57 of the air valve 56 is pressed by the compressed air that has been fed, and the air valve 56 is operated. As a result, the compressed air is pressure-fed from the air discharge channel 51A1 of the air discharge portion 51A into the channel 72E of the wiper 70 via the tube 80. In the operation of the air pump 50, the compressed air is also pressure-fed to the cleaning liquid pump connection portion 80C side of the tube 80. However, since the cleaning liquid discharge portion 24E of the cleaning liquid pump 60 is provided with the cleaning liquid valve 67, The flow of the compressed air into the air pump cover 24A is suppressed.

  Further, when the air pump 50 is operated, unlike the case where the cleaning liquid pump 60 is driven, the nozzle valve 76 is operated by the compressed air fed into the flow path 72E of the wiper 70. The cleaning liquid is stored inside the flow path 72E of the tube 80 and the wiper 70. For this reason, when the nozzle valve 76 is operated, the cleaning liquid is jetted toward the camera 90 (lens 90A) from the jetting hole 72C of the wiper 70 by the compressed air that has been fed under pressure, and the lens 90A is cleaned.

  Further, in this state, if the adhered substance remains on the lens 90A, the motor 31 is rotated reversely by the control of the control unit 33, and the air pump 50 is further operated. Therefore, the compressed air is ejected from the ejection hole 72C of the wiper 70 and is blown to the camera 90 (the lens 90A). Thus, the lens 90A is cleaned by the compressed air.

  Then, after removing the deposits on the camera 90 (lens 90A), the motor 31 is rotated forward under the control of the control unit 33. Therefore, the sun gear 35 rotates clockwise (see the arrow A1 in FIG. 8B). At this time, a rotational force in the circumferential direction of the sun gear 35 acts on the planetary gear 41 on the external teeth of the planetary gear 41 meshed with the sun gear 35. Therefore, the planet gear 41 revolves from the first connection position to the other side in the revolving direction (see the arrow D1 in FIG. 8B), and the planet gear 41 and the internal gear 42 mesh with each other.

  Then, by continuing the normal rotation of the motor 31, the extraneous matter removing device 10 performs an operation reverse to the above-described operation and returns to the initial state. That is, the planet gear 41 revolves from the first connection position to the other side in the revolving direction (see the arrow D1 in FIG. 8B) and is disposed at the second connection position. At this time, the carrier 71 of the wiper 70 moves from the first connection position to the second connection position together with the planetary gear 41. Thereby, the wiper 70 is arranged from the injection position to the standby position. At this time, the wiping unit 79 of the wiper 70 comes into contact with the lens 90A of the camera 90 to wipe the lens 90A. Further, the internal gear 42 is displaced from the upper non-meshing position to the lower side (see the arrow E1 in FIG. 8B) and is disposed at the holding position, and then is displaced downward again to lower the lower It is arranged at the meshing position. Then, when the attached matter removing device 10 is returned to the initial state, the driving of the control unit 33 with respect to the motor 31 is stopped.

  Next, the operation of blowing only the compressed air to the camera 90 (the lens 90A) by the attached matter removing device 10 will be described. In this case, in the initial state of the extraneous matter removing device 10, the motor 31 is reversed to revolve the planetary gear 41 from the second connection position to the first connection position. Thereby, the planet gear 41 is connected to the air pump gear 52. Therefore, by continuing the reverse rotation of the motor 31 in this state, only the compressed air can be blown to the camera 90 (the lens 90A).

  As described above, in the extraneous matter removing device 10, the planet gear 41 is connected to the sun gear 35, and the planet gear 41 revolves in the circumferential direction of the sun gear 35 by the rotation of the sun gear 35. After the planet gear 41 revolves from the second connection position to the first connection position, the planet gear 41 is connected to the air pump gear 52 of the air pump 50, and the driving force of the motor 31 is transmitted via the planet gear 41 to the air pump gear. 52. Thereby, the compressed air pumped by the air pump 50 is ejected from the ejection hole 72C of the nozzle portion 72B of the wiper 70 toward the lens 90A of the camera 90, and the attached matter attached to the lens 90A can be removed.

Here, a wiper 70 is connected to the planetary gear 41, and the wiper 70 has a wiping unit 79 for wiping the lens 90A of the camera 90. Then, when the planet gear 41 revolves from the second connection position to the first connection position, the wiper 70 moves to the injection position side together with the planet gear 41, and the wiping unit 79 wipes the lens 90A of the camera 90. Therefore, in addition to the removal of the attached matter by the compressed air jetted from the nozzle portion 72B, the attached matter can be removed by the wiping unit 79. In addition, as described above, when the planetary gear 41 revolves, the wiper 70 moves together with the planetary gear 41, so that a single drive source for driving the air pump 50 and a single drive source for driving the wiper 70 are provided. Of the motor 31 can be realized.
Accordingly, it is possible to improve the performance of removing the attached matter while suppressing an increase in the size and cost of the attached matter removing device 10.

  Further, a nozzle portion 72B having an injection hole 72C is formed integrally with the wiper arm 72 of the wiper 70, and a wiping portion 79 is provided on the nozzle portion 72B. Therefore, when the planetary gear 41 revolves, the nozzle portion 72B and the wiping portion 79 move together with the planetary gear 41. Accordingly, when the wiper 70 is not operated (initial state), the nozzle portion 72B and the wiping portion 79 can be arranged at the standby position separated from the camera 90. Therefore, the influence of the nozzle unit 72B and the wiping unit 79 at the time of imaging by the camera 90 can be suppressed. On the other hand, when the wiper 70 is operated, the nozzle 72 </ b> B can be disposed at an ejection position close to the camera 90, and the compressed air or the cleaning liquid can be ejected toward the camera 90. Therefore, the compressed air and the cleaning liquid can be effectively jetted to the camera 90.

  Further, the wiping portion 79 of the wiper 70 is arranged on one side (ejection position side) in the rotation (movement) direction of the wiper 70 with respect to the ejection hole 72C. For this reason, the driving range of the wiper 70 is minimized, and the lens 90A can be wiped twice by one drive of the wiper arm 72. In other words, the wiping unit 79 wipes the camera 90 both when the wiper 70 moves forward (when moving from the standby position to the ejection position side) and when it moves backward (when moving from the injection position to the standby position side). The camera 90 can be wiped by the wiping unit 79 before and after the injection of the cleaning liquid or the compressed air. Accordingly, the lens 90A can be wiped once by the wiping unit 79 before the compressed air is jetted toward the lens 90A of the camera 90 by the air pump 50. When the cleaning liquid is jetted toward the camera 90, the cleaning liquid remaining in the camera 90 can be wiped by the wiping unit 79. Therefore, the performance of removing adhering substances can be further improved.

  Further, the wiper 70 is configured to include a carrier 71 connected to the planetary gear 41 and a wiper arm 72 disposed outside the housing 20 and having a nozzle portion 72B. The carrier 71 is rotatably (movably) supported by the housing 20 (housing body 22), and the wiper arm 72 is connected to the carrier 71 so as to be integrally rotatable. Thereby, the planet gear 41 arranged inside the housing 20 and the wiper arm 72 arranged outside the housing 20 are connected by the carrier 71, and when the planet gear 41 revolves, the wiper arm 72 is moved together with the planet gear 41. Can be rotated (moved).

  An air pump 50 (air pump gear 52) is provided on one side in the revolving direction of the planetary gear 41, and a cleaning liquid pump 60 (cleaning liquid pump gear 62) is provided on the other side in the revolving direction of the planetary gear 41. . When the planetary gear 41 revolves to one side in the revolving direction by the driving of the motor 31, the planetary gear 41 and the air pump 50 (the air pump gear 52) are connected. On the other hand, the planetary gear 41 revolves to the other side in the revolving direction by the driving of the motor 31, whereby the planetary gear 41 and the cleaning liquid pump 60 (the cleaning liquid pump gear 62) are connected. Thus, the two pumps (the air pump 50 and the cleaning liquid pump 60) and the wiper 70 can be driven by the single motor 31.

  Further, at the second connection position of the planetary gear 41, the planetary gear 41 is connected to the cleaning liquid pump 60 (the cleaning liquid pump gear 62), and the wiper 70 is arranged at the standby position. When the cleaning liquid pump 60 operates, the nozzle valve 76 does not operate, and the injection of the cleaning liquid from the injection holes 72C is prohibited. On the other hand, when the planet gear 41 revolves from the second connection position to reach the first connection position, the planet gear 41 is connected to the air pump 50 (the air pump gear 52), and the wiper 70 moves from the standby position to the injection position. . When the air pump 50 is operated, the nozzle valve 76 is operated, and the injection of the compressed air or the cleaning liquid from the injection hole 72C is permitted. Therefore, the nozzle portion 72B for injecting the pressure-feeding object (compressed air or cleaning liquid) pumped by the two pumps can be configured as one nozzle portion, and when the wiper 70 is disposed at the ejection position. Only the compressed air or the cleaning liquid can be jetted to the camera 90.

  Further, in the attached matter removing device 10 of the present embodiment, as described above, the planetary gear 41 is revolved from the second connection position to one side in the revolving direction without operating the cleaning liquid pump 60, so that only compressed air is used. To the camera 90. Thereby, the cleaning liquid or the compressed air can be selected, and the selected cleaning liquid or the compressed air can be injected from the injection hole 72C of the wiper 70. Therefore, the convenience for the user can be improved.

  Further, in the present embodiment, as described above, after the cleaning liquid is injected from the injection hole 72C, the compressed air can be continuously injected from the injection hole 72C. Thus, if the attached matter remains on the camera 90 (the lens 90A) after the cleaning liquid is sprayed, the attached matter can be removed by blowing the compressed air onto the camera 90 (the lens 90A). Therefore, the effect of removing adhering substances can be effectively improved.

  In the present embodiment, the attached matter removing device 10 includes the air pump 50 and the cleaning liquid pump 60. However, in the attached matter removing device 10, the air pump 50 or the cleaning liquid pump 60 may be omitted. In the case where the air pump 50 is omitted in the attached matter removing device 10, the cleaning liquid pump 60 (the cleaning liquid pump gear 62) is arranged on one side in the revolving direction of the planetary gear 41, and when the cleaning liquid pump 60 is operated, the nozzle valve is operated. 76 may be configured to operate.

  Further, in the present embodiment, the rotation restricting mechanism 64 is provided in the cleaning liquid pump 60. However, the air pump 50 may be provided with a rotation restricting mechanism configured similarly to the rotation restricting mechanism 64. In this case, a male screw portion may be formed on the shaft portion 52A of the air pump gear 52, and a collar configured to be screwable with the male screw portion may be provided on the shaft portion 52A. Then, when the motor 31 rotates forward, the rotation of the air pump gear 52 may be regulated by the rotation regulating mechanism.

  Further, in the present embodiment, the rotation restricting mechanism 64 of the cleaning liquid pump 60 is configured by the male screw portion 65 formed on the shaft portion 62A of the cleaning liquid pump gear 62 and the collar 66, and the rotation of the motor 31 during the reverse rotation is performed. Although the rotation of the cleaning liquid pump gear 62 is restricted, the configuration for restricting the rotation of the cleaning liquid pump gear 62 is not limited to this. For example, a ratchet mechanism may be provided in the cleaning liquid pump gear 62 to restrict the rotation of the cleaning liquid pump gear 62 when the motor 31 rotates in the reverse direction. That is, for example, a disk having ratchet teeth may be integrally formed on the shaft portion 62A of the cleaning liquid pump gear 62, and a ratchet that can be engaged with the ratchet teeth may be provided outside the disk.

10 Adhered matter removing device 20 Housing 31 Motor 35 Sun gear (drive member)
41 planetary gear (moving member)
50 Air pump (pump)
60 Cleaning liquid pump (pump)
67 Cleaning liquid valve 70 Wiper 71 Carrier (connecting member)
72 Wiper arm (arm)
72B Nozzle part 72C Injection hole 76 Nozzle valve 79 Wiping part 90 Camera (optical sensor)

Claims (6)

An adhering matter removing device for removing adhering matter attached to an optical sensor,
Motor and
A driving member driven by the motor,
A moving member connected to the driving member and moved by a driving force of the motor;
A pump that is connected to the moving member after the movement and that operates by the driving force of the motor to pump the pressure-feeding body;
A nozzle unit having an injection hole for injecting the pressure-feeding object toward the optical sensor,
A wiper connected to the moving member and having a wiping unit for wiping the optical sensor, and moving with the moving member when the moving member moves to wipe the optical sensor with the wiping unit;
An adhering matter removing device equipped with a. The nozzle portion is formed integrally with the wiper,
The attached matter removing device according to claim 1, wherein the wiping unit is provided in the nozzle unit.   3. The attached matter removing device according to claim 2, wherein the wiping unit is disposed on one side in a moving direction of the wiper with respect to the injection hole. 4. The motor, the driving member, and a housing for housing the moving member,
The wiper is
A connecting member connected to the moving member and movably supported by the housing;
An arm provided outside the housing and having the nozzle portion, and an arm connected to be integrally movable with the connecting member,
The attached matter removing device according to claim 2 or 3, wherein the attached matter removing device is configured to include: The wiper moves from a standby position separated from the optical sensor to a jetting position approaching the optical sensor when the moving member moves to one side in the moving direction,
The pump is
An air pump that is provided on one side in the moving direction of the moving member and that operates to feed compressed air to the nozzle portion by pressure,
A cleaning liquid pump that is provided on the other side in the moving direction of the moving member and that operates to pump the cleaning liquid to the nozzle unit;
Has,
When the cleaning liquid pump is operated, the nozzle portion is prohibited from ejecting the pumped cleaning liquid to the outside, and when the air pump is operated, the nozzle portion is permitted to eject the pumped cleaning solution or the compressed air to the outside. The attached matter removing device according to any one of claims 2 to 4. A nozzle valve is provided at the tip of the nozzle portion,
When the cleaning liquid pump is operated, the nozzle valve prohibits the jetting of the cleaning liquid pumped to the outside, and when the air pump is operated, the nozzle valve jets the cleaning liquid or the compressed air sent to the outside. The adhering matter removing device according to claim 5, which permits the following.

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