JP2004067328A - Hose winding-up device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hose winding-up device capable of automatically stopping driving the rotation of a hose reel near completion of hose winding with a simple structure, and returning from an automatic stop condition to an initial condition by pulling out the hose. <P>SOLUTION: This hose winding-up device has a hose reel for winding up the hose 22 by rotating and driving from a rotation driving means through a clutch, an swollen part 161 of the hose, a press roller shaft 166 which can be moved to the hose, an energization means 28 which energizes the press roller shaft to a side approximating to the hose, a press roller 27 supported at the press roller shaft so as to rotate freely, a guide part 165 which guides the press roller shaft, and a switch 168 which is operated by the press roller shaft to switch the clutch into an OFF condition when the press roller shaft is moved to positions on the side approximating to the hose of the guide part and on the hose reel side in a moving direction of the hose. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a hose winding device used for a power sprayer or the like.
[0002]
[Prior art]
As a hose winding device of a power sprayer, for example, power from an engine is transmitted to a hose reel via a power transmission mechanism by a pulley and a belt, and a clutch such as an electromagnetic clutch is interposed in the power transmission mechanism, There has been known an apparatus which performs on / off operation of the electromagnetic clutch by a signal from a radio control transmitter to disconnect and connect power transmission to a hose reel. In such a hose winding device, when the electromagnetic clutch is engaged, power from the engine is transmitted to the hose reel, the hose reel is driven to rotate, and the hose is wound around the hose reel.
[0003]
If the electromagnetic clutch is turned on just before the end of the winding of the hose in the power sprayer, the worker holding the hose or the nozzle attached to the end of the hose is caught in the winding machine. That has an automatic stop device (safety device) that turns off the electromagnetic switch and stops the rotation drive of the hose reel before the occurrence of such a possibility that the winder may be damaged. It has been known.
[0004]
As such a hose winder of the power sprayer, for example, a hose winder described in Japanese Utility Model Publication No. 6-15943 can be mentioned. In this method, a swelling member (swelling portion) is fixed to a hose, and a first driven member and a second driven member having a passage portion through which the hose passes are angled with respect to a rotation axis in a rotation direction. And are provided so as to be integrally rotatable.
When the electromagnetic clutch (clutch) is engaged and the hose reel is driven to rotate, the hose is wound around the hose reel, and the swelling member of the hose comes into contact with the first driven member. The driven member is entrained, whereby the rotating shaft is rotated, the cam fixed to the rotating shaft is rotated, the limit switch is operated, the electromagnetic clutch is turned off, and the rotation of the hose reel is stopped. Let it.
Also, when the hose is pulled out of this state in which the rotation of the hose reel is automatically stopped, the bulging member of the hose comes into contact with the second driven member, and the second driven member is brought into contact with the first driven member. It is entrained in the direction that rotates in the opposite direction to the case, thereby rotating the rotating shaft in the reverse direction, rotating the cam fixed to this rotating shaft in the reverse direction, operating the limit switch, returning the electromagnetic clutch to the engaged state, The hole reel can be driven to rotate by rotation from the engine.
[0005]
[Problems to be solved by the invention]
However, in such a power take-up hose winding device, the structure of the automatic stop device for stopping the rotation drive of the hose reel is complicated, and the hose of the power spray device having the simple structure of the automatic stop device is used. There is a need for a winding device.
[0006]
The present invention has been made in view of the above circumstances, and with a simple structure, it is possible to automatically stop the rotation drive of the hose reel near the end of the hose winding, and to automatically stop the hose reel by pulling out the hose. It is an object of the present invention to provide a hose winding machine capable of returning to an initial state from the above.
[0007]
[Means for Solving the Problems]
To achieve the above object, a hose winding device according to claim 1, wherein the hose reel (20) is rotatably driven from a rotation driving means (15) via a clutch (78) to wind the hose (22). When,
A bulging portion (161) provided on the hose (22);
A pressure roller shaft (166) movably provided with respect to the hose (22); and a biasing means (28) for biasing the pressure roller shaft (166) toward the hose (22).
A pressure roller (27) rotatably supported by the pressure roller shaft (166) and capable of pressing the hose (22);
A guide portion (165) provided on a side portion of the passage portion of the hose (22) for guiding the pressing roller shaft (166);
When the pressure roller shaft (166) moves to a position on the hose reel (20) side in the moving direction of the hose (22) on the side of the guide portion (165) approaching the hose (22), A switch (168) operated by the pressing roller shaft (166) to disengage the clutch (78);
It is characterized by having.
[0008]
In the invention of claim 1, when the hose reel is driven to rotate and the hose is wound on the hose reel, the hose passes while being pressed by the pressing roller. At this time, the pressing roller shaft is located on the side of the guide portion closer to the hose and on the hose tip side in the moving direction of the hose.
Thereafter, as the winding of the hose approaches the end, the bulging portion of the hose pushes the pressing roller toward the hose reel against the urging force of the urging means. The pushed-out roller moves the guide portion toward the hose reel along with the movement of the bulging portion. The pressing roller shaft supporting the pressing roller moves together with the pressing roller, and the pressing roller shaft comes into contact with the end of the guide portion on the hose reel side, thereby preventing further movement.
Thereafter, the bulging portion further moves while pressing the pressing roller in a direction away from the hose against the urging force of the urging means. When the bulging portion has passed through the pressing roller, the pressing roller is pulled toward the hose by the urging force of the urging means, and the pressing roller shaft is closer to the hose of the guide portion and the hose reel in the moving direction of the hose. Move to the side position. Then, the switch is operated by the pressing roller shaft to disengage the clutch, whereby the hose reel is not driven to rotate. In this way, the hose winding is automatically stopped.
[0009]
To return to the initial state from this state in which the rotation of the hose reel has stopped automatically, the hose is manually pulled out. Then, the bulging portion of the hose pushes the pressing roller from the hose reel side toward the tip end of the hose in the moving direction of the hose (opposite to the hose reel) against the urging force of the urging means. The pushed pressure roller moves the guide portion toward the tip of the hose with the movement of the bulging portion. The pressing roller shaft supporting the pressing roller moves together with the pressing roller, and the pressing roller shaft abuts on the end of the guide portion on the hose tip side, so that further movement is prevented.
Thereafter, the bulging portion further moves while pressing the pressing roller in a direction away from the hose against the urging force of the urging means. When the bulging portion has passed through the pressing roller, the pressing roller is pulled toward the hose by the urging force of the urging means, and the pressing roller shaft is on the side closer to the hose of the guide portion in the initial state and the moving direction of the hose. Move to the position on the hose tip side in. When the pressing roller shaft moves from a position on the hose reel side in the moving direction of the hose on the side closer to the hose of the guide portion, the switch is no longer pressed by the pressing roller shaft and returns to the initial state.
[0010]
According to a second aspect of the present invention, in the first aspect of the present invention, the surface of the guide portion (165) on the hose (22) side is formed in a substantially "C" shape. And
[0011]
According to the second aspect of the present invention, the surface of the guide portion on the hose side is formed in a substantially "U" shape, so that when the pressing roller is pushed away by the bulging portion of the hose, the guide roller moves obliquely away from the hose. Since the pressing roller moves, the bulging portion can pass smoothly without being caught by the pressing roller.
[0012]
According to a third aspect of the present invention, in the hose winding device according to the first or second aspect, the bulging portion (161) is formed in a substantially spindle shape.
[0013]
According to the third aspect of the present invention, since the bulging portion of the hose is formed in a substantially spindle shape, when the bulging portion pushes the pressing roller, the bulging portion is pressed against the pressing roller like a wedge. In addition, the swelling portion can pass smoothly without being caught by the pressing portion.
[0014]
According to a fourth aspect of the present invention, in the hose winding device according to any one of the first to third aspects, the pressing roller shaft (166) is manually moved to the pressing roller shaft (166). For providing a grip.
[0015]
In the invention of claim 4, since the pressing roller shaft is provided with a grip for manually moving the pressing roller shaft, if a problem occurs in the movement of the pressing roller shaft, this grip is used. The pressing roller shaft can be easily moved to a desired position.
[0016]
According to a fifth aspect of the present invention, in the hose winding device according to the first to fourth aspects, the hose (22) of the hose reel (20) is sent out by being rotationally driven by a rotation driving means (15). A possible delivery roller (26) is provided, and the hose (22) is adapted to pass between the delivery roller (26) and the pressing roller (27).
[0017]
According to the fifth aspect of the invention, the hose can be sent out by power, and the work can be performed more efficiently.
[0018]
In addition, the code | symbol in a parenthesis in the above is what expressed the corresponding element in drawing for convenience, Therefore, this invention is not limited to description on drawing. The same applies to the description in the column of “Claims”.
[0019]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 and 2 are a side view and a front view, respectively, showing a power sprayer provided with a hose winding / unwinding device (hose winding device) according to an embodiment of the present invention.
In the power sprayer 10, a drive wheel 12 as a front wheel and a caster 13 as a rear wheel are attached to a body frame 11, and the vehicle can travel independently by driving rotation of the drive wheel 12. A handle 14 is formed on the rear end side upper portion of the body frame 11, and the operator can steer the power sprayer 10 by holding the handle 14 and changing the steering angle of the casters 13. ing. An engine (rotation drive means) 15 and a pump 16 are installed in the front half of the body frame 11 in the front-rear direction.
[0020]
At the rear half of the body frame 11 in the front-rear direction, a hose reel 20 is installed rotatably around a cylindrical rotating shaft 21 fixed to both ends of the hose reel 20. A hose 22 is wound. A distributor 23 is provided substantially below the center of the body frame 11 in the front-rear direction. A transmission 24 is provided at a lower front part of the body frame 11 and is directly connected to the drive wheels 12.
[0021]
As shown in FIGS. 1 and 3, a hose guide 25 is provided on the upper part of the body frame 12 at a position in front of the hose reel 20 in the front-rear direction. The body frame 11 is reciprocated in the left-right direction by a helical shaft described later so as to be aligned and wound. Here, FIG. 3 is illustrated as viewed from the opposite side of FIG. 1 (the opposite side in the left-right direction of the body frame 11).
As shown in FIG. 3, the hose guide 25 is provided with a delivery roller 26 that reciprocates and moves laterally with the hose guide 25 and a pressing roller 27 that can approach and separate from the delivery roller 26. The hose 22 is driven to rotate, and the pressing roller 27 is urged toward the sending roller 26 by a tension coil spring 28 so that the hose 22 is sandwiched between the sending roller 26 and the pressing roller 27, and the hose 22 is passed through the hose guide 25. It is sent out from the hole 29.
[0022]
A guide arm 30 is provided on the upper part of the hose guide 25 so as to be rotatable around a vertical axis of a through hole 29 of the hose guide 25, and the hose 22 wound around the hose reel 20 is moved from the hose guide 25 to the machine body. It is guided outside the frame 11. A large-diameter guide roller 31 is provided below the guide arm 30, and guides the hose 22 sent upward from the through hole 29 of the hose guide 25 obliquely upward. A small-diameter guide roller 32 is provided above the guide arm 30, and guides the hose 22 sent obliquely upward to the outside of the guide arm 30. A plurality of hose stoppers 33 are provided between the guide rollers 31 and 32 at appropriate intervals to prevent the hose 22 from coming off the guide rollers 31 and 32.
[0023]
A mounting bracket 151 for mounting a nozzle (not shown) is attached to the distal end of the hose 22, and a substantially spindle-shaped bulging member (bulging portion) 161 is provided at a predetermined distance from the distal end of the hose. Has been fixed. The swelling member 161 constitutes an automatic stop device for automatically stopping the rotation drive of the hose reel near the end of the later-described hose winding.
[0024]
As shown in FIGS. 1 and 4 (power transmission system diagram), a pulley 36A of a two-stage pulley mounted on the output shaft 35 of the engine 15 and a pulley 38 mounted on the drive shaft 37 of the pump 16 are provided. The belt 39 is wound, and transmits rotational power from the output shaft 35 of the engine 15 to the drive shaft 37 of the pump 16. The belt 39 is provided with a tension clutch (not shown) for switching between a tension state and a relaxed state of the belt 39, and turns on and off transmission of rotational power from the engine 15 to the pump 16.
A belt 43 is wound between a pulley 36 </ b> B of the two-stage pulley of the engine 15 and a pulley 42 attached to the input shaft 41 of the distributor 23, from the output shaft 35 of the engine 15 to the input shaft 41 of the distributor 23. Transmit rotational power.
The distributor 23 functions not only as a distributor but also as a clutch and a speed reducer (transmission). The distributor 23 converts the rotational power input to the input shaft 41 into an appropriate rotational speed and converts one of the output shafts ( Power to the other output shaft (first output shaft) 45 at the same rotational speed, and the power transmission to these output shafts 44 and 45. And cutting is performed.
[0025]
A belt 48 is wound between a pulley 46 attached to the output shaft 44 and a pulley 47 attached to the rotating shaft 21 of the hose reel 20, and the rotational power of the output shaft 44 of the distributor 23 is a hose reel. The rotation is transmitted to a rotation shaft 21 of the motor 20. A chain 54 is hung around a sprocket 50 mounted on the rotating shaft 21 and a sprocket 53 mounted on the end of a napier helical shaft (helical shaft) 52, and interlocks with the rotation of the rotating shaft 21 of the hose reel 20. The napier helical shaft 52 rotates, and the hose guide 25 engaged with the napia helical shaft 52 reciprocates along the napier helical shaft 52 extending in the left-right direction of the body frame 11. 22 are wound on the hose reel 20 in an aligned manner.
[0026]
A chain 58 is hung between a sprocket 55 attached to the end of the output shaft 45 and a sprocket 57 attached to the end of the delivery shaft 56, and the delivery shaft is linked with the rotation of the output shaft 45. 56 rotates. As shown in FIGS. 3 and 4, the delivery roller 26 is fitted outside the delivery shaft 56 with a one-way clutch 60 interposed. The one-way clutch 60 allows only one-way rotation transmission from the delivery shaft 56 to the delivery roller 26, so that the delivery roller 26 is driven to rotate in the direction in which the hose is delivered by the delivery shaft 56. Is rotated only through the one-way clutch 60 and is rotated in the opposite direction (the direction in which the hose is wound up) (however, in this embodiment, the rotation is not performed in this direction). Or, when it is not driven to rotate by the feed shaft 56, it freely rotates.
[0027]
The delivery roller 26 and the one-way clutch 60 are movable in the axial direction of the delivery shaft 56, and reciprocate laterally along the delivery shaft 56 with the reciprocating lateral movement of the hose guide 25. . As shown in FIG. 8, the feed shaft 56 and the napier spiral shaft (lateral feed shaft) 52 are rotatably supported at their both ends by support members 11A, 11A fixed to the frame 11 and parallel to each other.
[0028]
As shown in FIGS. 1 and 3, a pulley 61 is mounted on an input shaft (intermediate shaft) 41 of the distributor 23, and the pulley 63 is mounted on the input shaft 62 of the transmission 24. A belt 64 is wound therebetween, and transmits rotational power from the output shaft 35 of the engine 15 to the input shaft 62 of the transmission 24 via the input shaft 41 of the distributor 23. The belt 64 is provided with a tension clutch (not shown) that switches the tension state and the relaxed state of the belt 64, and turns on and off transmission of rotational power from the distributor 23 to the transmission 24.
The drive wheels 12 are directly connected to the output shaft 65 of the transmission 24.
[0029]
The distributor 23 is configured as follows.
That is, as shown in FIG. 5, one end of the input shaft 41 is inserted into the case 70 with the bearing 131 interposed. The inserted end of the input shaft 41 is aligned with the end of the portion of the output shaft 45 inserted into the case 70 with the bearing 132 interposed between the input shaft 41 and the output shaft 45. Thus, it is inserted with the bearing 133 interposed. Therefore, the input shaft 41 and the output shaft 45 are rotatably supported and inserted into the case 70 by the bearings 131, 132, and 133, and the input shaft 41 and the output shaft 45 can be relatively rotated by the bearing 133. It has become. A sprocket 55 is fixed to an end of the output shaft 45 protruding from the case 70 to the outside.
[0030]
A claw clutch (clutch) 71 is provided between the output shaft 45 and the input shaft 41. That is, a pawl clutch piece (first pawl clutch piece) 71A is attached to an end of the output shaft 45 facing the input shaft 41 so as to be movable along the axis of the output shaft 45 by spline coupling. On the other hand, a pawl clutch piece (third pawl clutch piece) 71 </ b> B is attached to an end of the input shaft 41 facing the output shaft 45 so as to be movable along the axis of the input shaft 41 by spline coupling. I have. When the pawl clutch piece 71A is moved to the pawl clutch piece 71B side by a fork lever (lever) 72 that rotates in the groove of the pawl clutch piece 71A, when the pawl clutch pieces 71A and 71B are engaged. The pawl clutch 71 is engaged, and rotational power is transmitted from the input shaft 41 to the output shaft 45. On the other hand, the pawl clutch piece 71A is moved by the fork lever 72 so as to move away from the pawl clutch piece 71B. When the clutch pieces 71A, 71B are no longer engaged, the pawl clutch 71 is in the disengaged state, and the rotational power is not transmitted from the input shaft 41 to the output shaft 45. Power is transmitted from the input shaft 41 to the output shaft 45 at the same rotation speed without being decelerated or increased.
[0031]
A gear 73 is fitted on the input shaft 41 via a bearing 134, so that the gear 73 and the input shaft 41 can rotate relative to each other. A gear 75 fixed to a counter shaft 74 rotatably provided on the case 70 meshes with the gear 73. A small gear 76 is also formed on the counter shaft 74, and a gear 77 fixed to the output shaft 44 meshes with the small gear 76. The pulley 46 is fixed to an end of the output shaft 44 protruding from the case 70 to the outside.
[0032]
A claw clutch (clutch) 78 is provided between the gear 73 and the input shaft 41. That is, on the input shaft 41, a pawl clutch piece (fourth pawl clutch piece) 78A is integrally movable with the pawl clutch piece (second pawl clutch piece) 71B along the axis of the input shaft 41 by spline coupling. On the other hand, a claw clutch piece 78B is formed on a side surface of the gear 73 opposite to the claw clutch piece 78A. Then, the pawl clutch piece 78A is moved to the pawl clutch piece 78B side by the fork lever (lever) 79, and when the pawl clutch pieces 78A, 78B are engaged, the pawl clutch 78 is in the engaged state. The rotational power is transmitted to the gear 73, and the rotational power is further reduced (shifted) and transmitted to the output shaft 44 via the gear 75, the small gear 76, and the gear 77. The pawl clutch 78 is moved away from the clutch piece 79B so that the pawl clutch 78 is disengaged when the pawl clutch pieces 78A and 78B no longer engage, so that the rotational power is not transmitted from the input shaft 41 to the output shaft 44. Has become.
[0033]
As described above, the pawl clutch piece connecting member 80 in which the pawl clutch piece 71B and the pawl clutch piece 78A are integrally formed, the input shaft is driven by the fork lever 79 that rotates in the groove of the pawl clutch piece connecting member 80. It reciprocates along the axis 41. When the pawl clutch piece coupling member 80 is moved to the pawl clutch piece 78B side and the pawl clutch piece 78A and the pawl clutch piece 78B are engaged with each other and the pawl clutch 78 is engaged, the fork lever 72 is engaged. The claw clutch piece 78B, the claw clutch piece coupling member 80, and the claw clutch piece so that the claw clutch piece 71A and the claw clutch piece 71B do not mesh even if the claw clutch piece 71A is moved to the claw clutch piece 71B side. The positional relationship between 71A is set. Therefore, when the pawl clutch 78 is engaged and the rotational power is transmitted from the input shaft 41 to the output shaft 44, the rotational power is not transmitted from the input shaft 41 to the output shaft 45.
[0034]
The fork lever 79 moves the pawl clutch piece coupling member 80 toward the pawl clutch piece 71A, and the fork lever 72 moves the pawl clutch piece 71A toward the pawl clutch piece 71B. When the pawl clutch 71 is engaged and the pawl clutch 71 is engaged, the pawl clutch piece 78B and the pawl clutch piece are connected so that the pawl clutch piece 78A does not separate from the pawl clutch piece 78B. The positional relationship between the member 80 and the pawl clutch piece 71A is set. Therefore, when the pawl clutch 71 is engaged and the rotational power is transmitted from the input shaft 41 to the output shaft 45, the rotational power is not transmitted from the input shaft 41 to the output shaft 44.
The fork lever 79 is operated by rotating the motor 81 as a driving means in the forward or reverse direction and moving the rod 82 to the left or right in FIG. On the other hand, the fork lever 72 is operated by a clutch lever 127 described later, and the clutch lever 127 is operated using human power as a driving source without using a driving means such as a motor. Therefore, the number of motors (drive means) for operating the clutch of the distributor 23 is one, and the manufacturing cost is reduced.
[0035]
As shown in FIG. 3, the guide arm portion 30 is provided on the hose guide 25 so as to be tiltable about a shaft 85 so that the guide arm portion 30 is erected by a compression coil spring (biasing means) 87. Being energized. An elevating member 86 is provided between the guide arm 30 and the hose guide 25 so as to be able to move up and down. The elevating member 86 is a compression coil spring provided between the elevating member 86 and the hose guide 25. 87 urged upward. When the guide arm 30 is tilted (falls), the elevating member 86 is pushed downward by a roller 88 provided below the guide arm 39 against the urging force of the compression coil spring 87, and descends. It is supposed to.
[0036]
As shown in FIGS. 6 and 7, a bar 90 is attached to the hose guide 25 so as to be rotatable about a shaft portion 91, and the tip of the bar 90 is inserted into a groove of the elevating member 86. I have. One end of a lever 92 is fixed to the base end of the bar 90. An L-shaped plate 93 is rotatably connected to the other end of the lever 92. One end of a rod (brake operating member) 94 is screwed to 93. A connecting plate 95 is fixed to the other end of the rod 94, and a bent portion is fixed to the distributor 23 so as to be rotatable in a long hole 96 formed in the connecting plate 95 and extending in the direction of the rod 94. A pin 98 provided at one end of the "H" -shaped brake arm 97 is inserted, and the connection plate 95 and the brake arm 97 are connected. The bent portion of the brake arm 97 is rotatably fixed to the distributor 23. Further, a brake material 99 is fixed to the other end of the brake arm 97, and the brake material 99 can freely contact and separate from the outer peripheral edge of the side plate of the hose reel 20. The brake material 99 is pressed against the outer peripheral edge of the side plate of the hose reel 20 by a tension coil spring (biasing means) 100 stretched between the pin 98 and the distributor 23.
[0037]
As shown in FIGS. 6, 7, and 8, a gear (conduction element) 110 is provided at an end of the napier spiral shaft 52 via a one-way clutch 111. The one-way clutch 111 allows only one-way rotation transmission from the napier spiral shaft 52 to the gear 110, whereby the gear 110 rotates in the direction in which the hose reel 20 sends out the hose by the napier spiral shaft 52. Only when it is driven, it is rotationally driven via the one-way clutch 111, and when it is rotationally driven in the opposite direction (the direction in which the hose reel 20 winds up the hose), or when it is not rotationally driven by the napier spiral shaft 52. , Free rotation.
The gear 110 is meshed with a gear 112 rotatably fixed to a support member 11A fixed to an upper portion of the frame 11. The ratio of the number of teeth between the gear 110 and the gear 112 is set to 1: 2, so that while the gear 100 makes two rotations (therefore, while the napier spiral shaft 52 makes two rotations), the gear 112 becomes one. It is designed to rotate. A cam 113 is fixed to the gear 112. The cam 113 is formed by forming a circular cam groove 115 on the peripheral surface of a cylindrical member 114.
[0038]
On the shaft 120 fixed to the frame 11, a lever 121 having an "H" shape is fixed so that its bent portion can be rotated. A roller 122 is rotatably provided at an intermediate portion of the long side of the lever 121, and a tension coil spring (biasing means) 123 is provided on the long side of the lever 121 so as to press the roller 122 against the cam 113. Is provided between the front end portion and the support member 11A. An L-shaped plate 124 is rotatably connected to the distal end of the short side of the lever 121, and one end of a rod 125 is screwed to the L-shaped plate 124. A connecting plate 126 is fixed to the other end of the rod 125. One end of an L-shaped clutch lever 127 is rotatably connected to the connecting plate 126. The bent portion of the clutch lever 127 is rotatably fixed to the distributor 23, and the other end of the clutch lever 127 is connected to the fork lever 72 of the distributor 23.
[0039]
Next, an automatic stop device (safety device) for automatically stopping the rotation drive of the hose reel 20 near the end of the winding of the hose will be described.
As shown in FIGS. 3 and 9, the swelling member 161 is formed by halving a pair of synthetic resin halves 161A, 161A with the hose 22 interposed therebetween. It is fixed to the hose 22 by being joined to each other by a screw (fixing tool) 163 inserted into the hole 162. The screw 163 does not project from the surface of the bulging member 161. The bulging member 161 has a central portion formed in a cylindrical shape, and both end portions formed in a cylindrical frustoconical shape, and is formed in a substantially spindle-shaped cylindrical shape as a whole. By the time the rotation of the hose reel 20 is stopped by the automatic stop device, the worker holding the tip of the nozzle or the hose 22 is not caught in the guide arm unit 30 (power sprayer 10), and The bulging member 161 is mounted at a position where the automatic stop device operates so that the hose 22 is wound around the hose reel 20 as much as possible. That is, the swelling member 161 is usually attached at a position about 3 m away from the tip of the hose 22. However, the mounting position of the bulging member 161 can be appropriately set according to the needs of the operator.
[0040]
On the other hand, as shown in FIGS. 10 and 11, the hose guide 25 is provided with two plate-shaped bracket portions 164 vertically so as to face each other at an interval. In each case, a substantially “U” -shaped guide hole (guide portion) 165 is formed. The shape of the guide hole 165 will be described in more detail. The guide hole 165 is linearly extended slightly obliquely so as to be positioned gradually upward as the distance from the hose 22 increases. A lower guide 165b extending below the upper guide 165a in parallel with the upper guide 165a, and an intermediate guide 165c connecting the ends of the upper guide 165a and the lower guide 165b on the hose 22 side are provided. ing. The upper guide part 165a and the lower guide part 165b are each formed in a long hole shape, and each end is in an arc shape. The surface of the intermediate guide portion 165c on the hose 22 side is formed in a substantially “C” shape.
[0041]
In each of the guide holes 165, both ends of a pressing roller shaft 166 formed of a round bar that rotatably supports the pressing roller 27 are inserted so as to be able to move in the guide holes 165. Further, between each end portion of the pressing roller shaft 166 protruding outward from each bracket portion 164 and each bracket, the pressing roller shaft 166 is attached to the delivery roller 26 side (the side approaching the hose 22). An urging tension coil spring (urging means) 28 is provided so that the pressing roller 27 is pressed against the hose 22. Each end of the pressing roller shaft 166 functions as a grip portion, and the operator can move the pressing roller shaft inside the guide hole 165 by holding both ends. In addition, in order to make it easy for the operator to grip, both ends of the pressing roller shaft 166 may be provided with grip members, or both ends may be covered with rubber, synthetic resin, or the like. . A guide roller 167 is rotatably provided on the bracket 164 below the pressing roller 27.
[0042]
As shown in FIG. 11, a limit switch (switch) 168 is attached to the outer surface of the one bracket portion 164. The limit switch 168 is arranged such that the pressing roller shaft 166 is positioned at a position below the hose 22 side. It is pressed when it moves to the position (on the side approaching the hose 22 and on the hose reel 20 side in the moving direction of the hose 22). When the limit switch 168 is depressed, the motor 81 is operated to disengage the claw clutch (clutch) 78 in the distributor 23, whereby the input shaft 41 rotates from the input shaft 41 to the output shaft 44. Power is not transmitted, and the hose reel 20 is not driven to rotate. When the limit switch 168 is no longer pressed by the pressing roller shaft 166, it returns to the initial state. The harness 169 of the limit switch 168 is fixed to the bracket part 164, and is not fixed to the hose guide part 30. Thereby, even if the hose guide part 30 rotates 360 degrees, there is no trouble such as the harness 169 being twisted.
10 and 11 are illustrated as viewed from the opposite side of FIG. 3 (the opposite side in the left-right direction of the body frame 11).
[0043]
In the automatic stop device configured as described above, when the hose reel 20 is driven to rotate and the hose 22 is wound around the hose reel 20 as shown in FIG. And the pressing roller 27, while passing the feed roller 26 and the pressing roller 27 while rotating. At this time, as shown in FIG. 12, the pressing roller shaft 166 is at the point A of the guide hole 165 (the position above the substantially U-shaped guide hole 165 on the hose 22 side). That is, the pressing roller shaft 166 is located on the side of the guide hole 165 approaching the hose 22 and at the tip end side of the hose 22 in the moving direction of the hose 22.
[0044]
Then, when the winding of the hose 22 approaches the end, the swelling member 161 fixed to the hose 22 enters like a wedge between the delivery roller 26 and the pressing roller 27, and the pressing roller 27 is tapered by the tapered surface. It is pushed downward against the urging force of the tension coil spring 28. As shown in FIG. 10B, the pressing roller 27 that has been pushed downward moves the guide hole 165 downward along with the movement of the bulging member 161. Then, the pressing roller shaft 166 comes into contact with the lower end edge of the guide hole 165, and further downward movement is prevented. Then, as the bulging member 161 moves further downward, the pressing roller 27 is pushed by the outer peripheral surface of the cylindrical portion having a large outer diameter in a direction away from the hose 22 against the urging force of the tension coil spring 28, As shown in FIG. 12, the pressing roller shaft 166 moves to a point B of the guide hole 165 (a position below the guide hole 165 on the opposite side to the hose 22). That is, the pressing roller shaft 166 moves to a position away from the hose 22 of the guide hole 165 and to a position on the hose reel 20 side in the moving direction of the hose 22.
[0045]
Thereafter, when the swelling member 161 moves further downward, as shown in FIG. 10C, the urging force of the tension coil spring 28 pulls the pressing roller shaft 166 toward the hose 22, and as shown in FIG. The pressing roller shaft 166 moves to a point C of the guide hole 165 (a position below the guide hole 165 on the hose 22 side). That is, the pressing roller shaft 166 moves to a position closer to the hose 22 of the guide hole 165 and closer to the hose reel 20 in the moving direction of the hose 22. Then, the limit switch 168 is pressed by the pressing roller shaft 166, whereby the motor 81 is operated, the claw clutch 78 in the distributor 23 is disengaged, and the rotational power is transmitted from the input shaft 41 to the output shaft 44. And the hose reel 20 is no longer driven to rotate. In this way, the hose winding is automatically stopped.
[0046]
To return the automatic stopping device to the initial state from the state where the rotation of the hose reel 22 is automatically stopped, the hose is manually pulled out. Then, the swelling member 161 fixed to the hose 22 enters between the delivery roller 26 and the pressing roller 27 like a wedge from below, and pulls the pressing roller 27 by the tapered surface to apply the urging force of the coil spring 28. Push upward in opposition. As shown in FIG. 12, the pressing roller 27 pushed upward moves the guide hole 165 upward along with the movement of the bulging member 161. Then, the pressing roller shaft 166 comes into contact with the upper end edge of the guide hole 165, and further upward movement is prevented. Then, as the bulging member 161 moves further upward, the pressing roller 27 is pushed in a direction away from the hose 22 against the biasing force of the tension coil spring 28 by the outer peripheral surface of the cylindrical portion having a large outer diameter, The pressing roller shaft 166 moves to a point D of the guide hole 165 (a position above the guide hole 165 on the side opposite to the hose 22). That is, the pressing roller shaft 166 moves to a position away from the hose 22 of the guide hole 165 and to a position on the distal end side of the hose 22 in the moving direction of the hose 22.
[0047]
Thereafter, when the bulging member 161 moves further upward, the pressing roller shaft 166 is pulled toward the hose 22 by the urging force of the tension coil spring 28, and moves to the point A in the initial state. When the pressing roller shaft 166 moves from the point C, the limit switch 168 is no longer pressed by the pressing roller shaft 166, and returns to the initial state.
[0048]
In the power sprayer configured as described above, the hose 22 is pulled out from the hose reel 20 as follows.
First, in FIG. 5, the fork lever 79 is operated by the motor 81 to move the pawl clutch piece coupling member 80 to the pawl clutch piece 71A side so that the pawl clutch 78 is disengaged. With this configuration, the rotational power is not transmitted to the hose reel 20.
[0049]
In this state, when the operator holds the distal end of the hose 22 and pulls the hose 22, in FIGS. 3, 6, and 7, the guide arm 30 moves the shaft 85 against the urging force of the compression coil spring 87. Tilt to center (fall). Then, the elevating member 86 is pushed downward by the roller 88 provided below the guide arm portion 39 and descends. When the elevating member 86 is lowered, as shown in FIGS. 6 and 7, the bar 90 inserted into the groove of the elevating member 86 rotates counterclockwise about the shaft 91 in these figures. Then, the brake arm 97 is rotated via the lever 92, the L-shaped plate 93, the rod 94, and the connecting plate 95 against the urging force of the tension coil spring 100, and the brake material 99 is moved to the side plate of the hose reel 20. The hose reel 22 is separated from the outer peripheral edge, whereby the brake of the hose reel 22 is released.
[0050]
Further, when the operator pulls out the hose 22, the hose reel 20 rotates clockwise (the direction in which the hose 22 is pulled out) in FIGS. Then, the napier spiral shaft 52 rotates in the same direction as the rotation direction of the hose reel 20 via the sprocket 50, the chain 54, and the sprocket 53. The rotation of the napier spiral shaft 52 is transmitted to the gear 110 by the one-way clutch 111, and the gear 112 makes one rotation while the gear 110 makes two rotations. With the rotation of the gear 112, the cam 113 similarly rotates counterclockwise in these figures. Then, the roller 122 that has been in the cam groove 115 comes off the cam groove 115, and the roller 122 comes into contact with the peripheral surface of the rotating cylindrical member 114. When the roller 122 comes into contact with the peripheral surface of the cylindrical member 114 of the cam 113, the lever 121 to which the roller 122 is fixed is moved around the shaft 120 against the urging force of the tension coil spring 123. Rotate clockwise. Then, the clutch lever 127 rotates clockwise via the L-shaped plate 124, the rod 125, and the connecting plate 126, and in FIG. 5, the fork lever 72 is moved to move the pawl clutch piece 71A to the pawl clutch piece 71B side. , Thereby bringing the claw clutch 71 into the engaged state. When the pawl clutch 71 is engaged, the rotational power of the engine 15 is transmitted from the input shaft 41 to the output shaft 45 while maintaining the same rotational speed, and as shown in FIG. 4 via the sprocket 55, the chain 58, and the sprocket 57. The delivery shaft 56 rotates. When the delivery shaft 56 is driven to rotate, the delivery roller 26 is driven to rotate in the delivery direction of the hose 22 by the one-way clutch 60. The hose 22 is delivered by the delivery roller 26 while being sandwiched between the delivery roller 26 and the pressing roller 27.
[0051]
Then, in FIGS. 6 and 7, the hose 22 is pulled out by a certain length, the hose reel 20 rotates by a certain amount, and when the gear 110 makes two rotations, the gear 112 makes one rotation. Accordingly, when the cylindrical member 114 of the cam 113 makes one rotation, and the roller 122 enters the cam groove 115, the lever 121 rotates clockwise about the shaft 120 by the urging force of the tension coil spring 123. Then, the clutch lever 127 rotates counterclockwise via the L-shaped plate 124, the rod 125, and the connecting plate 126, and in FIG. 5, the fork lever 72 is moved to move the pawl clutch piece 71A to the pawl clutch piece 71B. , Thereby causing the claw clutch 71 to be in the disengaged state. When the claw clutch 71 is disengaged, the rotational power of the engine 15 is not transmitted from the input shaft 41 to the output shaft 45, and the delivery shaft 56 is not driven to rotate. If the delivery shaft 56 does not rotate, the delivery roller 26 is not driven to rotate, and the delivery of the hose 22 by the delivery roller 26 is stopped.
[0052]
Thereafter, when the worker pulls out the hose 22, as described above, the feeding of the hose 22 by the feed roller 26 is started, and when the hose 22 is drawn by a certain length, the feeding of the hose 22 by the feed roller 26 is stopped. .
[0053]
In FIGS. 6 and 7, if the tension of the pulled out hose 22 decreases while the hose 22 is being fed by the feed roller 26, the pulling force of the hose 22 does not act on the guide arm portion 30, so that the guide arm The portion 30 is brought upright by the urging force of the compression coil spring 87, so that the lifting member 86 is not pushed downward by the roller 88, and the brake arm 97 is pulled by the urging force of the coil spring 100, so that the brake material 99 is released by the hose reel. Attempt to rotate so as to be pressed against the outer peripheral edge of the side plate 20. However, in this power atomizer, although not shown, when the clutch lever 127 is rotated in a direction to bring the claw clutch 71 into the engaged state, the brake arm 97 is released in the direction in which the brake is released. Since a release member that pushes in the clockwise direction in FIG. 6 is provided, the brake is released at the same time when the hose 22 is being delivered by the delivery roller 26. Therefore, even if the tension of the drawn-out hose 22 becomes small, the feeding of the hose 22 is not hindered.
[0054]
Here, while the brake arm 97 is rotated clockwise in FIG. 6 by the release member of the clutch lever 127, the rod 94 connected to the brake arm 97 via the connection plate 95 approaches the brake arm 97. However, since the connecting plate 95 has a long hole 96 extending in the direction of the rod 94, the pin 98 provided on the brake arm 97 moves through the long hole 96 toward the rod 94. Since it can move, the rod 94 does not prevent the release member of the clutch lever 127 from rotating the brake arm 97 in the direction in which the brake is released.
[0055]
When the worker stops pulling the hose 22, the pulling force of the hose 22 does not act on the guide arm 30, so that the guide arm 30 is set up by the urging force of the compression coil spring 87, so that the roller The lifting member 86 is no longer pushed downward by 88, the brake arm 97 is rotated by the urging force of the tension coil spring 100, and the brake material 99 is pressed against the outer peripheral edge of the side plate of the hose reel 20, whereby the brake is applied. State.
[0056]
Further, even when there is a trouble such as the rotation of the delivery shaft 56, since the one-way clutch 60 is interposed between the delivery shaft 56 and the delivery roller 26, the one-way clutch 60 is in the disconnected state. That is, since the delivery roller 26 rotates freely, the hose 22 can be pulled out manually.
When the rotation speed of the hose reel 20 based on the pulling force of the hose 22 by the operator becomes faster than the rotation speed of the delivery shaft 56, the one-way clutch 60 is disengaged, and the delivery roller 26 rotates freely. Therefore, the hose reel 20 is rotated in the delivery direction by the pulling force of the hose 22 by the operator.
[0057]
On the other hand, the winding of the hose 22 around the hose reel 20 is performed as follows.
In FIG. 5, the fork lever 79 is operated by the motor 81 to move the pawl clutch piece coupling member 80 to the pawl clutch piece 78B side, thereby bringing the pawl clutch 78 into the engaged state. When the claw clutch 78 is engaged, the rotational power of the engine 15 is transmitted from the input shaft 41 to the output shaft 44, and the hose reel 20 is moved through the pulley 46, the belt 48 and the pulley 47 as shown in FIG. Rotate. Since the rotation direction of the output shaft 44 is opposite to the rotation direction of the output shaft 45, the hose reel 20 rotates in the direction opposite to the feed shaft 56, and the hose 22 is wound around the hose reel 20.
[0058]
At this time, with the rotation of the hose reel 20, the napier spiral shaft 52 also rotates in the same direction as the hose reel 20, but since the rotation direction of the napier spiral shaft 52 is opposite to the rotation direction at the time of hose delivery, The rotation of the napier spiral shaft 52 is not transmitted to the gear 110 by the one-way clutch 111, so that the pawl clutch 71 is not engaged, and the delivery shaft 56 and the delivery roller 26 are not driven to rotate.
In this case, even if the delivery shaft 56 does not rotate, the one-way clutch 60 is interposed between the delivery shaft 56 and the delivery roller 26, so that the delivery roller 26 rotates freely, so that the winding of the hose 22 is prevented. There is no problem in taking.
[0059]
At the time of winding the hose, since the pulling force of the hose 22 acts on the guide arm 30, the guide arm 30 tilts about the shaft 85, whereby the brake arm 97 resists the urging force of the tension coil spring 100. The brake material 99 is separated from the outer peripheral edge of the side plate of the hose reel 20, and the brake of the hose reel 22 is released.
[0060]
In the above-described embodiment, the guide hole 165 is used as the guide portion. Alternatively, the guide portion may be formed by being surrounded by a guide groove or a member in a substantially “U” shape.
Further, the guide hole (guide portion) 165 may not be formed in a U-shape, and may be formed to extend linearly in the moving direction of the hose 22, for example. The guide portion is, in short, a side portion of the passage portion of the hose 22 so that the pressing roller shaft 166 can move in the moving direction of the hose 22 and can approach and leave the hose 22. What is necessary is just to be provided so that it may extend along the moving direction of the hose 22. Even in such a guide portion, if the surface on the hose side is formed in a substantially `` C '' shape, when the pressing roller is pushed away by the bulging portion of the hose, the pressing roller is obliquely away from the hose. Since it moves, the bulging portion can pass smoothly without being caught by the pressing roller. This guide is normally provided on the side of the passage of the hose 22 near the hose reel 20.
In the above embodiment, the bulging member 161 of the hose 22 has a substantially spindle shape. However, a sphere or other shape may be used instead. The bulging member (bulging portion) may be formed so as to be able to push the pressing roller 27 and pass therethrough.
[0061]
In the above-described embodiment, the hose winding / unwinding device has been described. However, the present invention can be applied to a case in which a hose unwinding mechanism using power is not provided and only the hose winding is performed by power.
Furthermore, the case where the hose winding device according to the present invention is used for a power sprayer has been described. However, the present invention is not limited to this, and the present invention relates to a hose winding device such as a carpet sprayer, and a flexible oil supply device. The present invention can also be applied to other devices for winding pipes and wires.
[0062]
【The invention's effect】
As described above, according to the hose winding of the present invention, with a simple structure, the rotation driving of the hose reel can be automatically stopped near the end of the hose winding, and the hose is automatically stopped by pulling out the hose. The state can be returned to the initial state.
[Brief description of the drawings]
FIG. 1 is a side view showing a power sprayer provided with a hose winding and feeding device according to an embodiment of the present invention.
FIG. 2 is a front view of the same.
FIG. 3 is a side view illustrating a part of the hose winding / delivery device, which is partially omitted.
FIG. 4 is a power transmission system diagram.
FIG. 5 is a diagram for explaining a distributor.
FIG. 6 is a view for explaining a portion of the hose winding / delivery device, and is a side view partially omitted.
FIG. 7 is a partially enlarged view of FIG. 6;
FIG. 8 is a diagram for explaining a portion of a delivery shaft and a napier helical shaft, and is a plan view with a part thereof omitted.
FIGS. 9A and 9B are diagrams showing a mounting state of a bulging member of a hose, wherein FIG. 9A is a front view, and FIG.
FIG. 10 is a view for explaining the automatic stop device, and is a cross-sectional view of a hose guide portion.
FIG. 11 is a view for explaining the automatic stop device, as viewed from the side of the hose guide.
FIG. 12 is a diagram illustrating a movement locus of a pressing roller shaft.
[Explanation of symbols]
10 Power sprayer 15 Engine (rotary drive means)
Reference Signs List 20 hose reel 22 hose 26 delivery roller 27 pressing roller 28 tension coil spring (biasing means)
78 Claw clutch (clutch)
161 bulging member (bulging portion)
165 Guide hole (guide part)
166 Press roller shaft 168 Limit switch (switch)

Claims (5)

A hose reel (20) that is rotatably driven from a rotation driving means (15) via a clutch (78) and winds a hose (22);
A bulging portion (161) provided on the hose (22);
A pressure roller shaft (166) movably provided with respect to the hose (22); and a biasing means (28) for biasing the pressure roller shaft (166) toward the hose (22).
A pressure roller (27) rotatably supported by the pressure roller shaft (166) and capable of pressing the hose (22);
A guide portion (165) provided on a side portion of the passage portion of the hose (22) for guiding the pressing roller shaft (166);
When the pressure roller shaft (166) moves to a position on the hose reel (20) side in the moving direction of the hose (22) on the side of the guide portion (165) approaching the hose (22), A switch (168) operated by the pressing roller shaft (166) to disengage the clutch (78);
A hose winding device comprising: The hose winding device according to claim 1, wherein a surface of the guide portion (165) on a hose (22) side is formed in a substantially “C” shape. The hose winding device according to claim 1, wherein the bulging portion is formed in a substantially spindle shape. The hose winding according to any one of claims 1 to 3, wherein the pressing roller shaft (166) is provided with a grip for manually moving the pressing roller shaft (166). Taking device. A delivery roller (26), which is rotatably driven by a rotation drive means (15) and is capable of delivering the hose (22) of the hose reel (20), is provided. The hose (22) is provided with the delivery roller (26). The hose winding device according to any one of claims 1 to 4, wherein the hose winding device passes between the pressure roller and the pressing roller (27).

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