JPH0866645A - Speed sprayer - Google Patents

Abstract

PURPOSE: To adjust the direction of a nozzle with no need for the driver on a driving seat to look back at an ejection head. CONSTITUTION: A conduit 50 is extended at an ejection head 28 in the horizontal direction of the speed sprayer, and an untwisted pipe on the tip side is made freely rotatable around the axis of a base pipe. The untwisted pipe is integrally furnished with a nozzle 26 at the tip in the rotating direction and rotated by a motor. The dial of a potentiometer is set in front of the driver on a driving seat, provided with a protrusion showing the direction of the nozzle 26 and turned by the driver. A voltage corresponding to the direction of the nozzle 26 and that of the protrusion is outputted from the potentiometer, and the nozzle 26 is driven by the motor so that the output voltage of the potentiometer is equal to the output voltage of the potentiometer.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a speed sprayer, and more particularly to a speed sprayer with improved control of the nozzle direction of the nozzle.

[0002]

2. Description of the Related Art Japanese Utility Model Publication No. 63-30516 and Japanese Utility Model Publication No. 63-30517 disclose that a nozzle of a jet head and a direction of a baffle plate are controlled by a motor in a speed sprayer.

[0003]

[Problems to be Solved by the Invention] Jitsuko Sho 63-3051
In the speed sprayer disclosed in Japanese Patent Publication No. 6 and Japanese Utility Model Publication No. 63-30517, it is necessary for the driver to operate the motor and adjust the directions of the nozzle and the baffle plate while watching the actual spray direction of the chemical liquid. In adjusting the direction, it is necessary to turn around while the speed sprayer is running, which is inefficient.

It is an object of the invention of claim 1 to provide a speed sprayer in which a driver can adjust the direction of a nozzle without turning around. It is an object of the invention of claim 2 to provide a speed sprayer in which the accuracy of control of the nozzle direction is improved. It is an object of the invention of claim 3 to provide a speed sprayer in which the driver can adjust the direction of the baffle plate without turning around. It is an object of the invention of claim 4 to provide a speed sprayer capable of simplifying the drive structure in the direction of the nozzle and the baffle plate (60).

[0005]

The present invention will be described using reference numerals in the drawings corresponding to the embodiments. The speed sprayer (10) of claim 1 has the following components (a) to (c). (A) A nozzle (26) that is arranged in the spray head (28) so that its direction can be freely changed, and sprays spray liquid outward from the spray head (28) in the radial direction. (B) Operation panel of the driver's seat (20) An indicator member (104) disposed in front of the driver within the driver (102) for instructing the direction of the nozzle (26) (c) to the nozzle (2) in the direction instructed by the indicator member (104).
6) Control means for controlling (64a-d, 80a-d, 106a-d, 110)

In the speed sprayer (10) of claim 2,
The speed sprayer (10) according to claim 1, further comprising:
The control means (64a-d, 80a-d, 106a-d, 110) has the following (a)-
It has the component (d). (A) A motor (64a-d) for changing the rotational position of the nozzle (26) that changes its direction by rotating around the straight line in the front-rear direction of the speed sprayer (10) (b) A rotation of the nozzle (26) Nozzle side potentiometer (80a-d) that outputs voltage related to the moving position (c) Driver side potentiometer (106a-d) (d) nozzle side that outputs voltage related to the rotational position of the indicator member (104) Motor control means (110) for controlling the motor (64a-d) so that the output of the potentiometer (80a-d) becomes a value corresponding to the output of the driver side potentiometer (106a-d).

In the speed sprayer (10) of claim 3,
The speed sprayer (10) according to claim 1 or 2, further comprising a baffle plate (60) disposed in the spray head (28) such that the direction thereof is adjustable, and the control means (64a-d, 80a-d, 106a-d, 110) control the baffle plate (60) in the direction indicated by the indicating member (104).

In the speed sprayer (10) of claim 4,
The speed sprayer (10) according to claim 3, further comprising:
The baffle plate (60) is rotated around a straight line in the front-rear direction of the speed sprayer (10) to change its direction, and link means for interlocking is provided.
(96) is provided so that the rotation of the nozzle (26) and the rotation of the baffle plate (60) are interlocked.

[0009]

In the speed sprayer (10) of the first aspect, the driver operates the indicating member (104) located at the front of the driver's seat (20) to indicate the direction of the nozzle (26). Control means (64a
-d, 80a-d, 106a-d, 110) aligns the nozzle (26) with the direction indicated by the indicating member (104).

In the speed sprayer (10) of claim 2,
The driver in the driver's seat (20) rotates the indicating member (104) to a rotation position corresponding to the requested orientation of the nozzle (26). Control means
(64a-d, 80a-d, 106a-d, 110) driver side potentiometer
(106a-d) outputs a voltage related to the rotation position of the indicating member (104), and the nozzle side potentiometer (80a-d) is the nozzle.
The voltage corresponding to the rotational position of (26), that is, the direction is output. The motor control means (110) is a driver side potentiometer (106a-d) and a nozzle side potentiometer (80a-d).
The motors (64a-d) are operated and the nozzles (26) are rotated until the outputs correspond to each other, and as a result, the direction of the nozzles (26) is the direction indicated by the indicating member (104). Is adapted to.

In the speed sprayer (10) of claim 3,
Control means (64a-d, 80a-d, 106a-d, 110) is an indicating member (104)
Orient the baffle plate (60) to the direction indicated by.
As a result, both the spraying direction of the sprayed liquid from the nozzle (26) and the discharge direction of the wind from the spraying head (28) are adjusted to the direction of the indicating member (104).

In the speed sprayer (10) of claim 4,
The nozzles (26) and the baffle plate (60) have their rotational positions changed by the common motors (64a-d) due to the interlocking relationship by the interlocking link means (96).

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the accompanying drawings. FIG. 8 is a schematic side view of the speed sprayer 10. The frame 12 is self-propelled while being supported by the front wheels 14 and the rear wheels 16. In the upper part of the frame 12, in order from the front side, a driver's seat 20 provided with a handle 18, a spray liquid tank 22 for storing spray liquid such as a chemical liquid, a machine room 24 in which a machine such as an engine or a pump is housed, radiation A plurality of nozzles arranged outward along the peripheral direction
A jet head 28 including 26 and a blower 30 that discharges air sucked from the rear to the jet head 28 are provided.

FIG. 1 is a perspective view of the jet nozzle device 32. The spouting device 32 is manufactured as a unit and placed on the frame 12. The spout plate 34 and the vortex preventive plate 36 are respectively arranged at the front and rear to define the front and rear of the spout head 28. Left left nozzle pipe 38, left middle nozzle pipe 40, right middle nozzle pipe 42,
The right and right nozzle pipes 44 are attached to the swirl preventive plate 36 on the rear surface side of the swirl preventive plate 36, that is, on the blower 30 side, and the left left nozzle pipe 38 extends along the left side portion of the swirl preventive plate 36, and the left middle nozzle. The pipe 40 extends along the left half of the upper side of the vortex shield 36,
The right middle nozzle pipe 42 extends along the right half of the upper side of the vortex shield 36, and the right right nozzle pipe 44 extends along the right side of the vortex shield 36. The partition plate 46 partitions the jet head 28 into front and rear parts, and draws the peripheral edges radially inward from the peripheral edges of the spray head plate 34 and the anti-vortex plate 36.

FIG. 2 is a structural view of the injection nozzle device 32 as viewed from the side. Although shown in FIG. 2 for the right-right nozzle pipe 44, the left-left nozzle pipe 38, the left-middle nozzle pipe 40,
The structure of the right middle nozzle pipe 42 is also the same. The holder 48 includes a left left nozzle pipe 38, a left middle nozzle pipe 40,
Nozzle pipes 38, 4 are arranged at appropriate intervals along each of the right middle nozzle pipe 42 and the right right nozzle pipe 44.
The 0, 42 and 44 are gripped and fixed to the vortex plate 36. In FIG. 1 and FIG. 2, the left left nozzle pipe 38, the left middle nozzle pipe 4
0, the right middle nozzle pipe 42, and the right right nozzle pipe 44 are each connected with a plurality of conduit bodies 50, which extend horizontally forward and backward of the speed sprayer 10 and penetrate the swirl preventive plate 36. And reaches the vicinity of the partition plate 46 in the spray head 28. Each conduit body 50 includes a fixed base pipe 54 on the base side and a base pipe.
54 and the untwisting tube 52 which is aligned with the center line and is rotatably coupled around the axis on the tip end side of the base tube 54. nozzle
26 is fixed to the tip end portion of the untwisting tube 52 via a nut 27 and is integrated with the untwisting tube 52 in the rotation direction. Support tube 56
Extends horizontally in the front-rear direction of the speed sprayer 10, penetrates the partition plate 46 at an intermediate portion, and has both ends rotatably supported by the jet nozzle plate 34 and the vortex preventive plate 36, and at a predetermined position in the axial direction. It has a pin insertion hole 58 for attaching the baffle plate 60. The support pipes 56 constitute a plurality of groups corresponding to the left-left nozzle pipe 38, the left-middle nozzle pipe 40, the right-middle nozzle pipe 42, and the right-right nozzle pipe 44, and in each group,
The total number of support tubes 56 is set to be equal to or less than the total number of nozzles 26. A blower plate 60 is attached to each of the support pipes 56 on the side of the spout plate 34 and the side of the swirl preventive plate 36 with respect to the partition plate 46.
With respect to the flow direction of the wind from 30, the downstream side edge of each baffle plate 60 is arranged so as not to protrude beyond the peripheral edge of the partition plate 46 to the downstream side at an arbitrary rotational position of the baffle plate 60.

4 and 5 show the baffle plate 60 at different rotational positions.
The attached state of is shown. The pair of pin insertion holes 58 are formed in the support tube 56 in a 90 ° cross relationship with each other. The baffle plate 60 is rotatably fitted to the support tube 56, and the clevis pin
The relative rotation position is restrained by 62, and the pin insertion hole 58 through which the clevis pin 62 is inserted is changed, so that the rotation position of the baffle plate 60 with respect to the support tube 56 can be switched by 90 °.

FIG. 3 is a partial view of the nozzle head device 32 viewed from the nozzle head plate 34 side. 1 to 3, the motor can be rotated forward and backward freely.
64a-d (only a part shown) are left and right nozzle pipes 3
8, the left middle nozzle pipe 40, the right middle nozzle pipe 42, and the right right nozzle pipe 44 are provided correspondingly, and are fixed to the surface of the jet head plate 34 on the machine chamber 24 side. Pinion 66 is a motor 64a-
The sector gear 68 is attached to the output shaft of d, is arranged on the machine room 24 side of the jet head plate 34, is rotatably supported by the jet head plate 34, and engages with the pinion 66. Potentiometer 80
ad is arranged corresponding to the motors 64a-d on the machine room 24 side of the jet head plate 34, changes the resistance in relation to the rotation of the spindle of the sector gear 68, and the voltage related to the resistance, that is, the nozzle 26
And a voltage having a functional relationship with the rotating position of the baffle plate 60. The baffle plate drive link lever 82 is integrally attached to the central support tube 56 of the support tubes 56 of each group in the rotation direction, and the baffle plate driven link arm 84 is rotated to the other support tube 56. It is attached integrally to the direction. In the group belonging to the left and right nozzle pipes 38 and the right and right nozzle pipes 44, the link rods 86 are adjacent to each other at both ends thereof.
Alternatively, the left middle nozzle pipe 40 and the right middle nozzle pipe 42 are rotatably connected to the baffle plate driven link arm 84.
In the group belonging to, the common link rod 86 has a wind guide plate drive link lever 82 and all the wind guide plate driven link arms 84.
Rotatably connected to the
56 rotates together. The operation rod 88 is rotatably connected to the sector gear 68 and the air guide plate drive link lever 82 at both ends, and rotates the air guide plate drive link lever 82 as the sector gear 68 rotates. The nozzle drive link lever 90 is disposed in the spray head 28, is integrally attached in the rotational direction to the untwisting tube 52 of the central conduit body 50 of the conduit bodies 50 of each group, and is driven by the nozzle. Link arm 92 is another conduit
It is integrally attached to the untwisting pipe 52 of 50 in the direction of rotation. In the group to which the left-left nozzle pipe 38 and the right-right nozzle pipe 44 belong, the link rod 94 is rotatably connected to the adjacent baffle plate drive link levers 82, and the left middle nozzle pipe 40
In the group to which the right middle nozzle pipe 42 belongs, the common link rod 94 is rotatably connected to the nozzle driving link lever 90 and all the nozzle driven link arms 92, whereby the nozzles 26 of each group are Rotate in conjunction. Swing plate 98
(FIG. 1) is disposed at the left and right lowermost end portions of the jet head 28 while avoiding the radial outward projection from the peripheral edge of the jet head 28, and is provided on the left-left nozzle pipe 38 and the right-right nozzle pipe 44. The baffle plate 60 to which it belongs is connected to the baffle plate 60 via a link rod 86 so that the baffle plate 60 swings in conjunction with the rotation thereof.
Specifies the direction of the wind emitted from the bottom end of the to the surroundings.
The stay 100 is fixed to the baffle plate 60 on the side of the swirl preventive plate 36 of the support tube 56 to which the baffle plate drive link lever 82 is attached,
The interlocking rod 96 rotatably connects both ends to the stay 100 and the nozzle drive link lever 90, whereby the nozzle 26 rotates in conjunction with the rotation of the baffle plate 60.

FIG. 6 is a front view of the operation panel 102. The operation panel 102 is provided in the driver's seat 20 in front of the driver so as to face the driver, like other instruments such as a speedometer. The potentiometers 106a-d include the left left nozzle pipe 38, the left middle nozzle pipe 40, and the right middle nozzle pipe 4, respectively.
2 and the right and right nozzle pipes 44 are provided corresponding to the dials 104 of the potentiometers 106a-d are arranged on the operation panel 102, and the potentiometer 1 is rotated by rotating each dial 104.
The resistance value of 06a-d, and hence the output voltage, changes. Each dial 104 has a protrusion 105 that can be orientated in the direction of the nozzle 26 desired by the driver, and a plurality of nozzle orientation marks 108 around each dial 104.
ad is shown. The orientation of the projection 105 and the orientation of each nozzle orientation mark 108a-d are set equal to the actual orientation of the nozzle 26, which is controlled as a result of the operation of the dial 104, ie the spraying direction. The driver manually turns the dial 104 to align the protrusion 105 with a desired orientation while referring to the nozzle orientation marks 108a-d.

FIG. 7 is a block diagram of a control device for controlling the rotational positions of the nozzle 26 and the baffle plate 60. When the engine switch 114 of the driver's seat 20 is turned on, the controller 110 receives electric power from, for example, a battery 112 having a voltage of 12V at both ends, and becomes in an operating state. A predetermined voltage is applied to both ends of the potentiometers 80a-d and 106a-d in advance, and the controller 110 receives a voltage related to the resistance value of the potentiometers 80a-d and 106a-d,
The motors 64a-d are driven so that the input voltage from each potentiometer 80a-d becomes equal to the input voltage from each potentiometer 106a-d. The controller 110 converts the input voltage 12V from the battery 112 and outputs the potentiometer output 116.
The output of the potentiometer output 116 of 5 V is applied to both terminals of the potentiometers 80a-d and 106a-d.

The operation of the embodiment will be described. A pump (not shown) in the machine room 24 of the speed sprayer 10 sucks in and discharges the spray liquid in the spray liquid tank 22, and the discharged spray liquid is the left left nozzle pipe 38 and the left middle nozzle pipe. Four
After passing through 0, the right middle nozzle pipe 42, and the right right nozzle pipe 44, each nozzle passes through each conduit 50, reaches the nozzle 26, and is ejected from the nozzle 26 outward in the radial direction of the jet head 28. Further, the blower 30 discharges the air sucked from the rear to the jet head 28,
The wind is diverted from the front-rear direction of the speed sprayer 10 to the radial direction of the jet head 28 by the jet head plate 34 and the vortex plate 36 of the jet head 28, and is emitted from the jet head 28 outward in the radial direction.

In order to adjust the orientations of the nozzles 26 and the baffle plate 60, the driver reaches the front operation panel 102 in the driver's seat 20 and rotates the dial 104 to project the protrusion.
Align 105 with the desired orientation of nozzle 26 and baffle plate 60. The controller 110 sends a current to the motors 64a-d so that the input voltage from each potentiometer 80a-d is equal to the input voltage from each potentiometer 106a-d to drive the motors 6a-d.
Reverse 4a-d. The rotational power of the motors 64a-d is transmitted to the baffle plate drive link lever 82 via the sector gear 68 and the operation rod 88 to rotate the support tubes 56 of each group,
The direction of the baffle plate 60 is aligned with the direction of the protrusion 105 on the operation panel 102. Further, the swinging of the baffle plate drive link lever 82 causes the nozzle drive link lever 82 to move through the interlocking rod 96.
90, the untwisting tube 52 of the conduit body 50 of each group is rotated, and the direction of the nozzle 26 is changed to the projection 105 on the operation panel 102.
To match the orientation of. The direction and on / off of the power supply current to the motors 64a-d are automatically performed by the controller 110, so that the operator only needs to align the projection 105 of the operation panel 102 with a desired direction and look back. , While confirming the direction of the spray discharged from the spray head 28, the motor 64a-
The trouble of switching the power supply current of d and turning on and off is omitted.

The nozzle 26 and the baffle plate 60 are each a conduit body.
Since the nozzles 26 and the support tubes 56 are attached, the number of the nozzles 26 and the number of the baffle plates 60 can be set to appropriate numbers without depending on each other. Further, the intervals between the nozzles 26 and the intervals between the baffle plates 60 in the circumferential direction of the spray head 28 can be set to appropriate values individually without depending on each other.
The 60 can be a large one that is long enough to improve the performance of wind direction control. The support tube 56 does not require a twist-back portion such as the twist-back tube 52 of the conduit body 50.
Is not a cantilever type, and both ends thereof are rotatably supported by the spout plate 34 and the vortex plate 36 to stabilize the support. Further, since the heavy air guide plate 60 cannot be attached to the conduit body 50, the strength can be reduced while ensuring the required durability.

Left left nozzle pipe 38, left middle nozzle pipe 4
An opening / closing cock (not shown) is provided for each of 0, the right middle nozzle pipe 42, and the right right nozzle pipe 44, and the left left nozzle pipe 38 and the left middle nozzle pipe 4 are operated by operating the respective opening and closing cocks.
It is possible to switch spraying and suspension of spraying for each of 0, the right middle nozzle pipe 42, and the right right nozzle pipe 44. Thereby, when spraying on the left side, only the valve opening cocks for the left left nozzle pipe 38 and the left middle nozzle pipe 40 are opened, and the spray liquid is sprayed only from the nozzles 26 belonging to the left left nozzle pipe 38 and the left middle nozzle pipe 40. To do. Similarly, when spraying upward, open only the open / close cock for the left middle nozzle pipe 40 and right middle nozzle pipe 42, and for the right spray, open / close cock for the right middle nozzle pipe 42 and right right nozzle pipe 44. Open only.

When stopping the upward spraying, the opening / closing cocks for the left middle nozzle pipe 40 and the right middle nozzle pipe 42 are closed, and the supply of the spray liquid to the left middle nozzle pipe 40 and the right middle nozzle pipe 42 is stopped. Not only does the left middle nozzle pipe 40
Each of the baffle plates 60 belonging to the group of the right middle nozzle pipes 42 is rotated until it becomes horizontal. As a result of all the baffle plates 60 belonging to the group of the left middle nozzle pipe 40 and the right middle nozzle pipe 42 being oriented horizontally, a plurality of baffle plates 60 are formed along the upper side of the jet head 28 at the upper side. , Adjacent ones are arranged continuously without leaving a gap therebetween, and block the upper side of the spray head 28, that is, act as a wind shield plate, and stop the discharge of wind upward. As a result, the left and left nozzle pipes 38 and / or
Alternatively, the spray liquid ejected from the nozzles 26 belonging to the right and right nozzle pipes 44 is prevented from flowing upward and being conveyed upward by the discharge air. In order for the baffle plate 60 to function as a baffle plate, the lengths of the baffle plate 60 are mutually different when the baffle plate 60 is in a rotating position at a right angle to the radial direction of the jet head 28. It is set so that there is almost no gap between the edges of the adjacent baffle plates 60.

Similarly, in the case of one-sided spraying, the baffle plates 60 belonging to the group on the side where the spraying is stopped are rotated to a rotating position perpendicular to the radial direction of the jet head 28, A plurality of baffle plates 60 are continuously arranged in the circumferential direction of the jet head 28 and shut off the peripheral portion on the side where the spraying is stopped, that is, act as a windshield and discharge the wind in the non-spraying direction. Stop so that the jetted spray liquid sneaking in from the spray side is not discharged in the non-spray direction.

As described above, the air guide plate 60 functions as a wind shield. The baffle plate 60 is disposed radially inward of the nozzle 26 in the spray head 28, and is completely immersed in the spray head 28 regardless of the rotating position. The plate protrudes outward in the radial direction from the jet head 28 and is prevented from catching branches and leaves to be sprayed while the speed sprayer 10 is running.

When individually adjusting the direction of the nozzle 26,
This is performed by loosening the nut 27 and changing the rotational position of the nozzle 26 with respect to the untwisting pipe 52 of the pipe body 50. Also, baffle plate
When individually adjusting the orientation of 60, it is performed by removing the clevis pin 62 from the pin insertion hole 58 of the support tube 56 and inserting it into another pin insertion hole 58, and it is possible to switch the orientation by approximately 90 °. No tools are required for this switching.

Stay 100 and nozzle drive link lever 90
The link rod 86 connecting the and is exchangeable, and by changing the link rod 86 to a link rod 86 having a different length, the baffle plate drive link lever 82 and the nozzle drive for the displacement amount of the operating rod 88. The ratio of the change amount of the swing amount of the link lever 90 changes, and as a result, the ratio of the rotation amount of the baffle plate 60 to the rotation amount of the nozzle 26 can be appropriately changed.

If the rotation range of the dial 104 for changing the output voltage of the potentiometers 106a-d is increased / decreased and the angular range to which the protrusion 105 of the dial 104 is directed is increased / decreased, the rotation of the nozzle 26 and the baffle plate 60 can be increased. The controllable angular range of the moving position can also be changed arbitrarily.

The spout device 32 spouts a line system from the left-left nozzle pipe 38, the left-middle nozzle pipe 40, the right-middle nozzle pipe 42, and the right-right nozzle pipe 44 to the nozzle 26, which guides the spray liquid to each nozzle 26. It is directly or indirectly attached to the plate 34 and the anti-vortex plate 36. Further, the support tube 56 as a mechanical movement part for controlling the directions of the nozzle 26 and the baffle plate 60, the motor 64a-
d, the sector gear 68, the link rod 86, the operating rod 88, the link rod 94, and the interlocking rod 96 are also the nozzle 26 and the baffle plate 60, and the nozzle plate and the duct system for the nozzle 26.
It is directly or indirectly attached to 34 and the baffle plate 36. Therefore, the spray head device 32 is manufactured as a unit and placed on the frame 12 without the restriction of assembling it on the frame 12 or manufacturing it together with the blower 30. Further, since the spray head device 32 is not restricted to be assembled on the frame 12 or assembled with the blower 30, the same spray head device 32 can be assembled to various types of speed sprayers 10.

[0031]

According to the invention of claim 1, the driver can arbitrarily adjust the direction of the nozzle by operating the front indicating member in the driver's seat. Therefore, it is possible to omit the trouble of operating the direction of the nozzle while turning backward and confirming the spraying direction of the spray liquid from the spray head.

According to the second aspect of the present invention, the output of the driver side potentiometer which outputs the voltage corresponding to the direction instructed by the indicating member and the output of the nozzle side potentiometer which outputs the voltage corresponding to the direction of the nozzle correspond to each other. Moreover, since the motor for changing the direction of the nozzle is driven, the direction of the nozzle can be accurately controlled to the direction instructed by the driver on the operation panel.

According to the third aspect of the present invention, since the direction of the baffle plate can be controlled by operating the indicating member, the driver can adjust the direction of the baffle plate without turning around the rear like the direction of the nozzle. .

In the invention of claim 4, since the nozzle and the air guide plate are interlocked by the interlocking link means, the nozzle and the air guide plate can share the drive means, and the structure of the drive unit can be simplified.

[Brief description of drawings]

FIG. 1 is a perspective view of a spray head device.

FIG. 2 is a structural view of the jet nozzle seen from the side.

FIG. 3 is a partial view of the spouting device viewed from the spouting plate side.

FIG. 4 is a view showing an attached state of a baffle plate at a predetermined rotation position.

FIG. 5 is a view showing an attached state of the baffle plate at a rotation position different from that of FIG.

FIG. 6 is a front view of an operation panel.

FIG. 7 is a configuration diagram of a control device that controls rotational positions of a nozzle and a baffle plate.

FIG. 8 is a schematic side view of a speed sprayer.

[Explanation of symbols]

 10 speed sprayer 20 driver's seat 26 nozzle 28 jet head 60 baffle plate 64a-d motor (control means) 80a-d potentiometer (control means) 96 interlocking rod (interlocking link means) 104 dial (indicating member) 106a-d potentiometer (Control Means) 110 Controller (Control Means, Motor Control Means)

[Procedure amendment]

[Submission date] September 29, 1994

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] 0014

[Correction method] Change

[Correction content]

FIG. 1 is a perspective view of the nozzle unit 32. The spouting device 32 is manufactured as a unit and is mounted on the frame 12. The spray head plate 34 and the vortex shelter plate 36 are respectively arranged at the front and rear to define the front and rear of the spray head 28. The left-left nozzle pipe 38, the left-middle nozzle pipe 40, the right-middle nozzle pipe 42, and the right-right nozzle pipe 44 are attached to the swirl-proof plate 36 on the rear surface side of the swirl-proof plate 36, that is, on the blower 30 side. Pipe 38 is a vortex plate 3
6, the left middle nozzle pipe 40 extends along the left half of the upper side of the swirl preventive plate 36, and the right middle nozzle pipe 42 extends along the right half of the upper side of the swirl preventive plate 36. The right-right nozzle pipe 44 extends along the right side portion of the vortex shelter plate 36. The partition plate 46 partitions the jet head 28 into front and rear,
The peripheral edges are pulled inward in the radial direction from the peripheral edges of the spout plate 34 and the anti-vortex plate 36.

[Procedure Amendment 2]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 6

[Correction method] Change

[Correction content]

[Figure 6]

Claims (4)

[Claims] 1. (a) Nozzle (26), (b) operation which is disposed in the jet head (28) so that its direction can be freely changed and ejects spray liquid from the jet head (28) outward in the radial direction. Seat (20) operation panel (1
02) an indicator member (104) disposed in front of the driver for indicating the direction of the nozzle (26), and (c) the direction indicated by the indicator member (104). Control means (64a-d, 80a-d, 106a-d, 11 for controlling the nozzle (26)
0), having a speed sprayer. 2. The control means (64a-d, 80a-d, 106a-d, 110)
(A) a motor (64a-d) for changing the turning position of the nozzle (26) which turns around the straight line in the front-rear direction of the speed sprayer (10) to change the direction; Nozzle (2
6) Nozzle side potentiometer (80a-d) that outputs a voltage related to the rotational position, (c) Potentiometer for the driver side that outputs a voltage related to the rotational position of the indicating member (104)
(106a-d), and (d) the nozzle side potentiometer (8
0a-d) output is the driver side potentiometer (106a-d)
2. The speed sprayer according to claim 1, further comprising motor control means (110) for controlling the motors (64a-d) so as to obtain a value corresponding to the output of the motor. 3. A baffle plate (60) is disposed in the spray head (28) so that its direction can be adjusted, and the control means (64a-d, 80a-d, 106).
The ad (110) controls the baffle plate (60) in the direction indicated by the indicating member (104).
Or the speed sprayer described in 2. 4. The baffle plate (60) rotates around a straight line in the front-rear direction of the speed sprayer (10) to change its direction, and the interlocking link means (96) causes the nozzle (26) to move. 4. The speed sprayer according to claim 3, wherein the speed sprayer is provided so as to interlock with the rotation of the baffle plate (60).