JP2021195082A - Work vehicle - Google Patents

Abstract

To secure an installation space of a tank for storing water without fail in a work vehicle which includes a driver protection frame and may jet mist-like water to a driver.SOLUTION: A work vehicle 1 includes: a vehicle body 2; a driver seat 3 mounted on the vehicle body; a protection frame 9 for protecting a driver which is erected so as to extend to an area above the driver seat; a tank 40 for storing water; a spray nozzle 50 which jets water in a mist-like manner; and a supply device 60 which supplies the water in the tank to the spray nozzle. An internal space of the protection frame forms a water storage space of the tank.SELECTED DRAWING: Figure 14

Description

The present invention relates to a work vehicle such as a tractor.

Conventionally, a work vehicle disclosed in Patent Document 1 is known.
The work vehicle disclosed in Patent Document 1 includes a driver's seat, a frame for protecting the driver rising upward from the driver's seat, a tank for storing water, and a fine mist injection for injecting water in the tank into a fine mist. It has the means.

Japanese Unexamined Patent Publication No. 2011-89257

In the work vehicle disclosed in Patent Document 1, the tank is configured separately from the frame for protecting the driver and is arranged on the vehicle body. Therefore, a space for installing the tank is required in the vicinity of the frame for protecting the driver, and there is a problem that it is difficult to secure the installation space when installing a tank having a large capacity.
In view of the prior art, the present invention makes it possible to reliably secure an installation space for a tank for storing water in a work vehicle provided with a frame for protecting the driver and capable of injecting atomized water to the driver. That is the solution issue.

The work vehicle according to one aspect of the present invention includes a vehicle body, a driver's seat mounted on the vehicle body, a protective frame for protecting a driver standing upright so as to extend above the driver's seat, and a tank for storing water. And an injection nozzle for injecting water in the form of a mist, and a supply device for supplying the water in the tank to the injection nozzle, and the internal space of the protection frame constitutes the water storage space of the tank.

Preferably, the protective frame has an upright portion that stands behind the driver's seat and a leg portion that extends downward from the upright portion and is arranged behind the vehicle body, and the internal space of the leg portion is formed. It constitutes the water storage space of the tank.
Preferably, the legs include a left leg and a right leg spaced apart from each other in the width direction of the vehicle body, the tank includes a first tank and a second tank, and the first tank is. The internal space of the protective frame is configured as a water storage space, and the second tank connects the left leg portion and the right leg portion.

Preferably, the injection nozzle includes a first injection nozzle provided in the upright portion and capable of injecting water from the rear of the driver's seat toward the driver's seat side.
Preferably, the injection nozzle includes a second injection nozzle arranged in front of the driver's seat, and the second injection nozzle can inject water from the front of the driver's seat toward the driver's seat side. ..

Preferably, the work vehicle is provided with a rear mounting portion on which the work device can be mounted behind the vehicle body, and the first injection nozzle is rearward of the vehicle body toward the work device side mounted on the rear mounting portion. It is possible to spray water up to.
Preferably, the work vehicle is provided with a front mounting portion on which the work device can be mounted in front of the vehicle body, and the second injection nozzle is in front of the vehicle body toward the work device side mounted on the front mounting portion. It is possible to spray water up to.

Preferably, the work vehicle is provided with a changing mechanism that allows the direction of the injection nozzle to be changed, and the injection nozzle has a left nozzle arranged to the left of the driver's seat in the vehicle body width direction and the driver's seat. The change mechanism includes a right nozzle arranged to the right of the driver's seat, and the change mechanism is such that the direction of the injection nozzle is such that the water ejected from the left nozzle and the water ejected from the right nozzle are above the driver's seat. It is possible to change between the first direction of merging at and the second direction of not merging above the driver's seat.

Preferably, the protective frame is removable with respect to the vehicle body together with the tank, the injection nozzle, and the supply device.
Preferably, the work vehicle includes an air conditioner unit that generates cold air that cools the driver seated in the driver's seat, a cold air passage that is provided inside the protective frame and through which the cold air generated by the air conditioner unit passes, and the above. It is provided with a cold air sending unit that sends cold air that has passed through the cold air passage toward the driver's seat.

Preferably, a first space constituting the cold air passage and a second space constituting the water storage space of the tank are formed inside the protective frame.
Preferably, the supply device has a water pipe that guides the water in the tank to the injection nozzle, the water pipe is inserted inside the protective frame, and the cold air passage is the protective frame. It is formed between the inner surface of the water pipe and the outer surface of the water pipe.

Preferably, the injection nozzle is arranged in the vicinity of the cold air delivery portion.
Preferably, the work vehicle has a first water guiding section that guides the drain water generated from the air conditioner unit to the tank, and a filter that removes impurities contained in the water that is guided to the tank through the first water guiding section. And have.
Preferably, the work vehicle removes impurities contained in the second headrace portion that guides the dew condensation water adhering to the surface of the protective frame to the tank and the water that is guided to the tank through the second headrace portion. It has a filter and a filter.

According to the above-mentioned work vehicle, in a work vehicle provided with a frame for protecting the driver and capable of injecting mist-like water to the driver, it is possible to reliably secure an installation space for a tank for storing water.

It is a side view which shows one Embodiment of a work vehicle. It is a rear view which shows one Embodiment of a work vehicle. It is a perspective view which shows the 1st Embodiment of a protection frame. It is a side view which shows the 1st Embodiment of a protection frame. It is a front view which shows the 1st Embodiment of a protection frame. It is a partially enlarged view of the protection frame, and is the figure which shows the 1st tank, the 1st injection nozzle, the 1st delivery part, the air conditioner unit and the like. It is a perspective view which shows the 2nd Embodiment of a protection frame. It is a side view which shows the 2nd Embodiment of a protection frame. It is a figure which shows the state which the air-conditioning wind is sent out from the 1st delivery part and the 2nd delivery part to the driver who was seated in the driver's seat. It is a perspective view which shows the 3rd Embodiment of a protection frame. It is a front view which shows the 3rd Embodiment of a protection frame. It is a side view which shows the 3rd Embodiment of a protection frame. It is a figure which shows the usage mode (air conditioner wind mode) which blows an air conditioner wind to a driver. It is explanatory drawing which shows the flow of the air-conditioning wind supplied from an air-conditioning unit, and the flow of water supplied from a 1st tank. It is a top view which shows the state which made the 2nd injection nozzle a 1st direction. It is a figure which shows an example of the change mechanism. It is a top view which shows the state which made the 1st injection nozzle a 1st direction. It is a top view which shows the state which made the 1st injection nozzle a 2nd direction. It is a top view which shows the state which made the 2nd injection nozzle a 2nd direction. It is a figure which shows the state which the 1st injection nozzle is injecting mist toward the work apparatus side attached to the rear mounting part to the rear from the vehicle body. It is a figure which shows the state which the 2nd injection nozzle injects mist toward the work apparatus side attached to the front mounting part, to the front of the vehicle body. It is a figure which shows the state which the mist is injected from the 1st injection nozzle to the driver, and the mist is injected from the 2nd injection nozzle toward the generation source of the dust generated on the work apparatus side. It is a figure which shows the state which the mist is injected from the 2nd injection nozzle to the driver, and the mist is injected from the 1st injection nozzle toward the generation source of the dust generated on the work apparatus side. It is a figure which shows the usage mode (mist mode) which cools a driver by a mist. It is a side view which shows the other embodiment of the work vehicle.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a side view showing an embodiment of the work vehicle 1. In the case of this embodiment, the work vehicle 1 is a tractor. However, the work vehicle 1 according to the present invention is not limited to the tractor, and may be another work vehicle. Examples of other work vehicles include, but are not limited to, construction machines such as backhoes and wheel loaders, agricultural machines such as rice transplanters and combine harvesters, and passenger lawnmowers and management machines. The present invention is widely applied to a work vehicle in which the driver's seat is not surrounded by a cabin, in other words, a work vehicle in which the driver's seat is open to the outside air (not isolated from the outside air). be able to.

Hereinafter, a case where the work vehicle 1 is a tractor will be described as an example.
As shown in FIG. 1, the work vehicle (tractor) 1 includes a vehicle body 2, a driver's seat 3 mounted on the vehicle body 2, and a traveling device 4 that supports the vehicle body 2 so as to be able to travel.
The vehicle body 2 has a vehicle body frame 5, a clutch housing 6, and a mission case 7. The vehicle body frame 5 extends in the front-rear direction of the vehicle body 2. The prime mover 8 is mounted on the vehicle body frame 5. The prime mover 8 is an engine in the case of the present embodiment, but may be a motor. The upper part and the side surface of the prime mover 8 are covered with the bonnet 10. The clutch housing 6 is connected to the rear of the prime mover 8 and houses the clutch. The transmission case 7 is connected to the rear portion of the clutch housing 6 and houses a transmission, a rear wheel differential device, and the like. A PTO shaft 23 projects behind the mission case 7.

The traveling device 4 has a front wheel 4F provided at the front portion of the vehicle body 2 and a rear wheel 4R provided at the rear portion of the vehicle body 2. The front wheel 4F is supported by the vehicle body frame 5. The rear wheel 4R is supported by the output shaft of the rear wheel differential device. The upper part of the rear wheel 4R is covered with the fender 11. A steering wheel 24 is provided in front of the driver's seat 3. The steering wheel 24 is supported on the upper part of the steering column 29 arranged in front of the driver's seat 3.

The vehicle body 2 is provided with a mounting portion 12 to which a working device can be mounted.
As shown in FIGS. 1 and 2, the mounting portion 12 can include a rear mounting portion 12A. The rear mounting portion 12A is provided at the rear portion of the vehicle body 2. The rear mounting portion 12A is a portion for mounting the work device W1 (see FIG. 20) that performs work behind the vehicle body 2 on the rear portion of the work vehicle 1. The working device W1 is driven by, for example, a driving force transmitted from the PTO shaft 23. The working device W1 is, for example, a cultivator, a sprayer, a seeder, and the like, but is not limited thereto. The rear mounting portion 12A can be driven by an actuator such as a hydraulic cylinder to raise or lower the working device W1. The rear mounting portion 12A is, for example, a three-point link mechanism, but is not limited thereto.

The mounting portion 12 may include a front mounting portion 12B (see FIG. 21) in addition to or in place of the rear mounting portion 12A. The front mounting portion 12B is a portion for mounting the work device W2 that performs work in front of the vehicle body 2 on the front portion of the work vehicle 1. The working device W2 is driven by, for example, the operation of a hydraulic cylinder. In FIG. 21, a front loader is shown as the working device W2. The front mounting portion 12B is a mounting frame 14 connected to the vehicle body frame 5. The mounting frame 14 is connected to the left portion and the right portion of the vehicle body frame 5, respectively. However, the working device W2 is not limited to the front loader, and may be another type of working device. Further, the configuration of the front mounting portion 12B can be changed according to the type of the working device W2.

As shown in FIGS. 1 and 2, the work vehicle 1 includes a protective frame 9 for protecting the driver. The protection frame 9 is a frame for protecting the driver OP seated in the driver's seat 3 when the work vehicle 1 rolls over, and is also called ROPS (Roll-Over Protective Structures). The protective frame 9 stands up so as to extend above the driver's seat 3. The protective frame 9 is attached to the vehicle body 2. The protective frame 9 may not be removable from the vehicle body 2, but is preferably removable from the vehicle body 2. Further, the protective frame 9 may be attached to the work vehicle 1 in advance, but it is preferable that the protective frame 9 can be retrofitted to the existing work vehicle 1.

In the following description, the directions (front, rear, left, right, top, bottom) with respect to the protection frame 9 are directions in which the protection frame 9 is attached to the vehicle body 2. That is, the arrow F direction in FIG. 1 is referred to as forward, the arrow B direction is referred to as backward, the arrow U direction is referred to as upward, the arrow D direction is referred to as downward, the arrow L direction in FIG. 2 is referred to as left, and the arrow R direction is referred to as right. Further, the arrow W direction in FIG. 2 is referred to as a vehicle body width direction.
3, FIG. 4, and FIG. 5 show one embodiment (first embodiment) of the protection frame 9.

The protective frame 9 has an upright portion 15. The upright portion 15 stands upright (upright) behind the driver's seat 3 (see FIG. 1). The standing portion 15 includes a left standing portion 15L and a right standing portion 15R. The left standing portion 15L and the right standing portion 15R stand at intervals in the vehicle body width direction W (see FIG. 2). The left standing portion 15L stands behind the left rear of the driver's seat 3. The right standing portion 15R stands on the right rear side of the driver's seat 3.

The protective frame 9 has a connecting portion 16 that connects the left standing portion 15L and the right standing portion 15R. The connecting portion 16 includes an upper connecting portion 17 and a lower connecting portion 18. The upper connecting portion 17 connects the upper end of the left standing portion 15L and the upper end of the right standing portion 15R. The lower connecting portion 18 connects the lower end of the left standing portion 15L and the lower end of the right standing portion 15R. As a result, the left standing portion 15L, the right standing portion 15R, the upper connecting portion 17, and the lower connecting portion 18 are connected and integrated in an annular shape. Hereinafter, the structure in which the left standing portion 15L, the right standing portion 15R, the upper connecting portion 17, and the lower connecting portion 18 are integrated is referred to as “upper structure 19”.

The protective frame 9 has a lower structure 20 connected to the lower part of the upper structure 19. The lower structure 20 has a leg portion 21 and a mounting portion 22.
The leg portion 21 includes a left leg portion 21L and a right leg portion 21R. The left leg portion 21L and the right leg portion 21R are arranged at intervals in the vehicle body width direction. The left leg portion 21L is connected to the lower portion of the left standing portion 15L, and extends forward and downward from the lower portion. The right leg portion 21R is connected to the lower portion of the right standing portion 15R, and extends forward and downward from the lower portion. The legs 21 are arranged behind the vehicle body 2 (see FIG. 1). Further, the leg portion 21 is arranged between the rear wheel 4R on the left side and the rear wheel 4R on the right side (see FIG. 2).

The mounting portion 22 is a portion for mounting the protective frame 9 on the vehicle body 2. The mounting portion 22 includes a left mounting portion 22L and a right mounting portion 22R. The left mounting portion 22L is mounted on the left side of the vehicle body 2. The right mounting portion 22R is mounted on the right side of the vehicle body 2. The mounting portion 22 is mounted on the vehicle body 2 by a mounting tool such as a bolt. The mounting portion 22 is mounted on the rear portion of the vehicle body 2. The mounting portion 22 is mounted directly on the rear portion of the vehicle body 2 (for example, the rear portion of the mission case 7 or the like) or indirectly via a mounting member such as a rudder hitch.

The configuration of the mounting portion 22 is not particularly limited as long as the protective frame 9 can be mounted on the vehicle body 2. For example, the mounting portion 22 may have a configuration that can be mounted on a portion other than the mission case 7, for example, a fender 11 or a driver's seat 3. The configuration (shape, etc.) of the leg portion 21 can be appropriately changed according to the configuration (mounting position, etc.) of the mounting portion 22.

The protective frame 9 is composed of a hollow pipe (cylinder body). The internal spaces of the left standing portion 15L, the right standing portion 15R, the upper connecting portion 17, and the lower connecting portion 18 communicate with each other. This internal space functions as a space through which the air-conditioning wind described later flows. That is, the air-conditioning wind can flow through the internal space of the superstructure 19 of the protective frame 9.
On the other hand, the passage of air-conditioning wind is blocked at the boundary between the internal space of the left leg portion 21L and the internal space of the left standing portion 15L, and the boundary between the internal space of the right leg portion 21R and the internal space of the right standing portion 15R. There is a wall 28 (see FIG. 6). Therefore, the air-conditioning air flowing through the internal space of the upper structure 19 does not flow into the internal space of the lower structure 20.

The protective frame 9 has a structure capable of supplying air-conditioned air to the driver's seat 3 side (hereinafter referred to as "air-conditioned air supply structure") and a structure capable of supplying mist-like water (mist) to the driver's seat 3 side (hereinafter referred to as "mist"). It has both or one of (referred to as "mist supply structure"). "Air-conditioned air" is air generated by a flow of air adjusted to a suitable temperature, which is higher or lower than the ambient temperature, and includes cold air for cooling and / or hot air for heating. That is, the air-conditioning air supply structure can supply cold air for cooling and / or hot air for heating.

In the following description, the form having only the air conditioner air supply structure is the "air conditioner form", the form having only the mist supply structure is the "mist form", and the form having both the air conditioner air supply structure and the mist supply structure is "combined with the air conditioner mist". It is called "form".
In the drawing, the protective frame 9 of the "air conditioner mist combined use form" is mainly shown. The protective frame 9 of the "air conditioner form" is obtained by omitting the mist supply structure of the "air conditioner mist combined form". The protective frame 9 in the "mist form" is obtained by omitting the air conditioner air supply structure in the "air conditioner mist combined form".

Hereinafter, the air-conditioning air supply structure of the protective frame 9 will be described first.
As shown in FIGS. 3 to 5, the air conditioner unit 30 is attached to the protective frame 9. The air conditioner unit 30 generates an air conditioner air that cools or heats the driver seated in the driver's seat 3. The air conditioning unit 30 is composed of an HVAC (Heating Ventilation and Air-Conditioning) unit.

As shown in FIG. 1, the air conditioner unit (HVAC unit) 30 is connected to the air conditioner operating device 45, which is configured separately from the air conditioner unit 30, via a cooling passage 46. The cooling passage 46 is a passage through which the refrigerant flows (circulates). The air conditioner unit (HVAC unit) 30, the air conditioner operating device 45, and the refrigerant passage 46 constitute an air conditioner that generates and generates air conditioning air.

The air conditioning actuating device 45 is arranged in the bonnet 10 of the vehicle body 2, and includes a compressor and a condenser. The compressor is driven by the prime mover (engine) 8. The air conditioner unit (HVAC unit) 30 includes a housing 31, an evaporator, a heater core, a blower fan, an air mix door, and an inlet / outlet switching door. The compressor, the fan motor that drives the blower fan, and the actuator of each door are driven based on a command signal from an ECU (Engine Control Unit).

The air conditioner unit 30 may be driven by electric power supplied from a power source of a battery or a generator (alternator or the like). The power supply may be mounted on the vehicle body 2 or may be mounted on the protective frame 9.
The air conditioner unit 30 is attached to the lower connecting portion 18 of the protective frame 9. As shown in FIGS. 1 and 2, the air conditioner unit 30 is arranged behind the driver's seat 3. Specifically, the air conditioner unit 30 is arranged at a position behind the backrest portion 3a of the driver's seat 3 and overlapping the backrest portion 3a when viewed from the rear.

The conditioned air generated by the air conditioner unit 30 is supplied to the conditioned air passage 32. The air-conditioned air passage 32 becomes a cold air passage 32 when the air-conditioned air is cold air, and becomes a hot air passage 32 when the air-conditioned air is warm air. As shown in FIG. 6, the air-conditioning air passage 32 is provided inside the protective frame 9, and the air-conditioning air generated by the air-conditioning unit 30 passes through the air-conditioning air passage 32. In the case of the present embodiment, the internal space of the protective frame 9 constitutes the air-conditioning air passage 32. That is, the protective frame 9 functions as a duct constituting the air conditioning air passage 32.

In the case of the present embodiment, a part of the internal space of the protective frame 9 constitutes an air conditioner air passage 32 through which the air conditioner air generated by the air conditioner unit 30 passes. Specifically, the internal space of the upper structure 19 (left standing portion 15L, right standing portion 15R, upper connecting portion 17, lower connecting portion 18) constitutes the air-conditioning air passage 32. The conditioned air generated by the air conditioner unit 30 flows through the conditioned air passage 32. In FIGS. 5 and 6, the flow of air conditioning air is indicated by white arrows. The air conditioning air generated by the air conditioner unit 30 is supplied to the internal space of the lower connecting portion 18 and flows to the upper connecting portion 17 through the left standing portion 15L and the right standing portion 15R.

The protective frame 9 is provided with an air-conditioning air sending unit 33. The air-conditioning air sending unit 33 sends out the air-conditioning air that has passed through the air-conditioning air passage 32 toward the driver's seat 3. The air-conditioning air sending unit 33 becomes a cold air sending unit 33 when the air-conditioning air is cold air, and becomes a hot air sending unit 33 when the air-conditioning air is hot air. The air-conditioned air sending unit 33 has an outlet 34 (see FIGS. 5 and 6) for blowing out air-conditioned air. The air-conditioning air delivery unit 33 has a first transmission unit 35 provided in the upright unit 15. The first delivery unit 35 sends out the air-conditioning air from the rear to the front of the driver's seat 3.

As shown in FIG. 5, the first sending unit 35 is provided in the left standing portion 15L and the right standing portion 15R, respectively. The first delivery unit 35 includes an upper transmission unit 35A and a lower transmission unit 35B. The upper delivery portion 35A is provided on the upper part of the upright portion 15. The lower delivery portion 35B is provided at the lower part of the upright portion 15. As shown in FIG. 1, the upper delivery portion 35A is located higher than the upper end of the backrest portion 3a of the driver's seat 3. The lower delivery portion 35B is located at a position lower than the upper end of the backrest portion 3a of the driver's seat 3. The upper delivery unit 35A can send air-conditioning air toward the driver's neck and head from above after the driver OP seated in the driver's seat 3. The lower delivery unit 35B can send air conditioning air from behind the driver OP seated in the driver's seat 3 toward the driver's arms and back.

The orientation of the outlet 34 of the first delivery unit 35 can be changed as needed. By changing the direction of the outlet 34, the flow direction (sending direction) of the air-conditioning air can be changed. The direction of the air outlet 34 can be changed by, for example, changing the direction of the louver (baffle plate) provided in the air outlet 34.
7 and 8 show another embodiment (second embodiment) of the protection frame 9. Hereinafter, the difference between the protection frame 9 of the second embodiment and the protection frame 9 of the first embodiment described above will be described.

In the protection frame 9 of the second embodiment, a anteversion portion 25 extending forward and upward is formed on the upper portion of the upright portion 15. The forward tilted portion 25 includes a left forward tilted portion 25L formed on the upper portion of the left standing portion 15L and a right forward tilted portion 25R formed on the upper portion of the right standing portion 15R. The upper connecting portion 17 connects the upper end of the left forward tilted portion 25L and the upper end of the right forward tilted portion 25R.
In the case of the present embodiment (second embodiment), the internal spaces of the left standing portion 15L including the left forward tilting portion 25L, the right standing portion 15R including the right forward tilting portion 25R, the upper connecting portion 17, and the lower connecting portion 18 are air-conditioned air. It constitutes the passage 32. The air-conditioning wind generated by the air conditioner unit 30 was supplied to the internal space of the lower connecting portion 18, flowed to the lower part of the left standing portion 15L and the lower part of the right standing portion 15R, and then formed on the upper part of the left standing portion 15L. It flows to the upper connecting portion 17 through the right forward tilted portion 25R formed on the upper part of the left forward tilted portion 25L and the right standing portion 15R.

In the case of the present embodiment, the air-conditioning air delivery unit 33 has a second transmission unit 36 in addition to the first transmission unit 35 described above. The second delivery unit 36 is provided in the upper connecting unit 17. The second delivery unit 36 is provided above and in front of the first transmission unit 35. As shown in FIG. 9, the second delivery unit 36 sends out the air conditioner wind CW from the rear upper side to the front lower side of the driver's seat 3. As a result, the second delivery unit 36 can send the air-conditioning wind CW from above the rear of the driver OP seated in the driver's seat 3 toward the driver's head.

The direction of the outlet of the second delivery unit 36 can be changed as necessary, as in the case of the first transmission unit 35. For example, as shown in FIG. 9, the direction of the outlet of the second delivery unit 36 can be set so that the air conditioning wind CW (see the solid line arrow) hits the head of the driver OP, or the driver OP can be set. It can also be set to send air conditioning air (see the dashed arrow) in front of. When the former orientation is set, the head of the driver OP can be efficiently cooled or warmed. When the latter direction is set, the sent out air-conditioning air functions as an air curtain AC, and it is possible to prevent dust and the like generated during work from hitting the driver's face from the front.

According to the protection frame 9 of the second embodiment, the cool feeling or the warm feeling given to the driver is improved by sending cold air or warm air toward the driver from both the first sending unit 35 and the second sending unit 36. At the same time, it is possible to obtain a dustproof effect. Further, depending on the environment around the driver's seat (temperature, wind direction, type of work, etc.) and the driver's preference, the conditioned air is selectively sent from either the first sending section 35 or the second sending section 36. You can also do it.

10, 11, and 12 show still another embodiment (third embodiment) of the protection frame 9. Hereinafter, the difference between the protection frame 9 of the third embodiment and the protection frame 9 of the first embodiment described above will be described.
The protective frame 9 of the third embodiment has a roof portion 26. The roof portion 26 is attached to the upper part of the upright portion 15 and covers the upper part of the driver's seat 3. The roof portion 26 is attached to the upper part of the upper connecting portion 17. An extension portion 27 extending forward from the upper connecting portion 17 is connected to the upper connecting portion 17. The front extension portion 27 extends forward along the lower surface (back surface) of the roof portion 26. The front end of the front extension portion 27 is located above the driver's seat 3 (see FIG. 20) and opens downward. The front extension portion 27 is composed of a hollow pipe. The internal space of the front extension portion 27 communicates with the internal space of the upper connecting portion 17.

In the case of the present embodiment (third embodiment), the internal space of the front extension portion 27, the left standing portion 15L, the right standing portion 15R, the upper connecting portion 17, and the lower connecting portion 18 constitutes the air conditioning air passage 32. .. The air-conditioning air generated by the air conditioner unit 30 is supplied to the internal space of the lower connecting portion 18 and flows from the left standing portion 15L and the right standing portion 15R to the front extension portion 27 through the upper connecting portion 17.
In the case of the present embodiment, the air-conditioning air delivery unit 33 has a third transmission unit 37 in addition to the first transmission unit 35 described above. The third delivery unit 37 is provided in the front extension unit 27. Specifically, the downward opening at the front end of the front extension portion 27 constitutes the third delivery portion 37. As shown in FIG. 13, the third delivery unit 37 sends out the air-conditioning wind CW from the upper side to the lower side of the driver's seat 3. As a result, the third delivery unit 37 can send the air-conditioning wind CW from above the driver OP seated in the driver's seat 3 toward the driver's head. Therefore, the head of the driver OP can be efficiently cooled or warmed.

The direction of the outlet of the third delivery unit 37 can also be changed as needed. For example, the direction of the outlet of the third delivery unit 37 can be set to send the air conditioner air in front of the driver. In this case, the air-conditioning wind functions as an air curtain, and it is possible to prevent dust and the like generated during work from hitting the driver's face from the front.
According to the protection frame 9 of the third embodiment, as shown in FIG. 13, the conditioned air is sent from both the first delivery unit 35 and the third transmission unit 37 toward the driver OP, so that the driver OP It is possible to generate a concentrated region CR in which cold air or warm air is concentrated around the face, and improve the cool feeling or warm feeling given to the driver OP. It is also possible to obtain a dustproof effect by creating an air curtain by air conditioning wind around the face of the driver OP.

The protection frame 9 according to the present invention may include at least one of the above-mentioned first transmission unit 35, second transmission unit 36, and third transmission unit 37, but may include two or three. It is preferable to have it.
Hereinafter, the mist supply structure of the protection frame 9 will be described. The mist supply structure described below can be applied to the protection frame 9 of all the above-described embodiments (first, second, third embodiment).

As shown in FIG. 14, the mist supply structure includes a tank 40 for storing water, an injection nozzle 50 for injecting water in a mist form, and a supply device 60 for supplying water in the tank 40 to the injection nozzle 50. Have.
In the case of the present embodiment, the tank 40 includes a first tank 41 and a second tank 42. However, the tank 40 may be only one of the first tank 41 and the second tank 42. For example, when the specifications are such that water can be sprayed over a long period of time, the tank 40 preferably includes a first tank 41 and a second tank 42. When the specification is such that water can be injected only for a short time, the tank 40 can be only one of the first tank 41 and the second tank 42 (preferably only the first tank 41).

As shown in FIG. 6, the internal space of the protective frame 9 constitutes the water storage space of the first tank 41. In other words, the internal space of the protective frame 9 is used as the water storage space of the first tank 41. Specifically, the internal space of the lower structure 20 of the protective frame 9 constitutes the water storage space of the first tank 41. Specifically, the internal space of the leg portion 21 (left leg portion 21L and right leg portion 21R) of the lower structure 20 constitutes the water storage space of the first tank 41. The water WT injected from the injection nozzle 50 is stored in the first tank 41.

As shown in FIG. 6, in the case of the protective frame 9 in the form of using the air conditioner mist together, the first space 38 constituting the air conditioner air passage 32 and the water storage space of the tank (first tank 41) are configured inside the protective frame 9. A second space 39 is formed. The first space 38 and the second space 39 are separated by a wall 28.
The first space 38 is formed inside the upper structure 19 of the protective frame 9, and the second space 39 is formed inside the lower structure 20 of the protective frame 9. That is, inside one protective frame 9, a space (first space 38) constituting the air-conditioning air passage 32 and a space (second space 39) constituting the water storage space of the tank (first tank 41) are formed. ing. As a result, the internal space of the protective frame 9 can be effectively used as a space for air-conditioning wind and mist distribution. Further, it is not necessary to separately secure a space for installing a duct constituting an air conditioner air passage and a tank for storing water outside the protective frame 9. Further, since the upper part of the protective frame 9 is the first space 38 and the lower part is the second space 39, water is stored in the lower part of the protective frame 9 and the position of the center of gravity of the protective frame 9 can be lowered. It is possible to prevent the work vehicle 1 from becoming unstable due to the weight.

As shown in FIGS. 3, 7, 10, 10 and the like, the second tank 42 is attached to the protective frame 9. Specifically, the second tank 42 is attached to the lower structure 20. More specifically, the second tank 42 is a container attached to the leg 21. The second tank 42 connects the left leg portion 21L and the right leg portion 21R. In this way, by adopting a structure in which the left leg portion 21L and the right leg portion 21R are connected by the second tank 42, the strength (rigidity) of the leg portion 21 is improved. In addition to the second tank 42, a connecting member for connecting the left leg portion 21L and the right leg portion 21R may be provided, and the second tank 42 may be fixed to the connecting member.

The second tank 42 is preferably provided when the required amount of water cannot be secured only by the first tank 41. For example, the second tank 42 is detachably configured with respect to the protective frame 9, and the form having only the first tank 41 and the form having both the first tank 41 and the second tank 42 can be switched as needed. It can be possible.
In the case of having both the first tank 41 and the second tank 42, the internal space (water storage space) of the first tank 41 and the internal space (water storage space) of the second tank 42 may be independent of each other. However, it is preferable that they communicate with each other. For example, when the amount of water stored in the internal space of the first tank 41 decreases, the water stored in the internal space of the second tank 42 may be configured to flow into the internal space of the first tank 41. can.

The injection nozzle 50 is preferably a nozzle capable of injecting fine powder mist having a particle diameter of 10 to 30 μm. Such fine powder mist is also called dry mist, and since it evaporates in a short time, the object to be sprayed does not get wet. In addition, the object can be cooled by utilizing the heat of vaporization at the time of evaporation. In addition, it has an excellent dustproof effect because it can collide with dust (sand dust, etc.) in the air and be dropped.

As shown in FIG. 1 and the like, the injection nozzle 50 includes a first injection nozzle 51 arranged behind the driver's seat 3. As shown in FIGS. 4, 8, 12, 12 and the like, the first injection nozzle 51 is provided on the upright portion 15 of the protective frame 9. The first injection nozzle 51 can inject water from the rear of the driver's seat 3 toward the driver's seat 3. As shown in FIGS. 5 and 11, the first injection nozzle 51 includes a left nozzle 51L (hereinafter referred to as “first left nozzle 51L”) and a right nozzle 51R (hereinafter referred to as “first right nozzle 51R”). include. The first left nozzle 51L is arranged to the left of the driver's seat 3 in the vehicle body width direction. The first right nozzle 51R is arranged to the right of the driver's seat 3 in the vehicle body width direction. The first left nozzle 51L is provided on the left standing portion 15L. The first right nozzle 51R is provided on the right standing portion 15R. As shown in FIG. 1, the first injection nozzle 51 is arranged at a height below the upper end of the backrest portion 3a of the driver's seat 3 and above the upper surface of the fender 11. However, the first injection nozzle 51 may be arranged at a height above the upper end of the backrest portion 3a of the driver's seat 3.

As shown in FIG. 14, the supply device 60 includes a pump 61 and a water pipe 62. The pump 61 is a high pressure pump capable of supplying water at a high pressure (for example, 4 MPa or more). The pump 61 supplies the water in the tank 40 to the water pipe 62. The pump 61 is attached to the protective frame 9 and is arranged behind the vehicle body 2 (see FIG. 2). However, the pump 61 may be attached to the vehicle body 2.

The water pipe 62 guides the water in the tank 40 supplied by the pump 61 to the first injection nozzle 51. The water pipe 62 is, for example, a flexible hose or tube. The water pipe 62 includes a first water pipe 63 that connects the pump 61 and the tank 40, and a second water pipe 64 that connects the pump 61 and the first injection nozzle 51.
The first water pipe 63 is connected to both or one of the first tank 41 and the second tank 42. FIG. 14 shows an example in which the first water pipe 63 is connected to the first tank 41. The second water pipe 64 is connected to the first injection nozzle 51 via a pipe connecting portion 67 (see FIGS. 3, 7, 10, 10 and the like) provided in the upper structure 19.

In FIG. 14, the flow of air conditioning air supplied from the air conditioner unit 30 is indicated by a white arrow, and the flow of water supplied from the first tank 41 is indicated by a two-dot chain arrow.
By driving the pump 61, the water stored in the tank 40 is sucked out by the first water pipe 63, supplied to the first injection nozzle 51 via the second water pipe 64, and fog is sent from the first injection nozzle 51. It can be sprayed in a shape. FIG. 14 shows a mode in which the water stored in the first tank 41 is supplied to the first injection nozzle 51, but the water stored in the second tank 42 is supplied to the first injection nozzle 51. You may.

The pump 61 can be driven by the driving force of the prime mover 8, but may be driven by the power supply from the power source. The power source is, for example, a battery or an alternator. The power supply may be mounted on the vehicle body 2 or may be mounted on the protective frame 9.
The first injection nozzle 51 is preferably a one-fluid nozzle that discharges only water. When the first injection nozzle 51 is a one-fluid nozzle, the supply device 60 can use a device having a pump 61 and a water pipe 62 as shown in FIG. 14 described above. When a one-fluid nozzle is used as the first injection nozzle 51, the quietness is higher than when a two-fluid nozzle described later is used. Therefore, the driver's comfort is improved by the water discharge sound (mist spray sound). There is no loss.

However, the first injection nozzle 51 may be a two-fluid nozzle that discharges water and air. The two-fluid nozzle is composed of a water nozzle for discharging water and an air nozzle for discharging air, and water can be atomized by mixing air with water using compressed air or the like.
When the first injection nozzle 51 is a two-fluid nozzle, the supply device 60 may include an air compressor (not shown) that produces compressed air instead of the pump 61. An air blower may be used instead of the air compressor. The air compressor and the air blower (hereinafter referred to as "air supply source") can be driven by, for example, the driving force of the prime mover 8. The air supply source is attached to the protective frame 9 and is arranged behind the vehicle body 2. However, the air supply source may be attached to the vehicle body 2.

An air hose 66 (see FIG. 6) for passing air supplied from an air supply source is connected to the air nozzle of the first injection nozzle 51. A water pipe 65 (hereinafter referred to as “third water pipe 65”) (see FIG. 6) that guides the water in the tank 40 to the water nozzle is connected to the water nozzle of the first injection nozzle 51.
In FIG. 6, the flow of air conditioning air supplied from the air conditioner unit 30 is indicated by a white arrow A1, and the flow of water supplied from the tank 40 (first tank 41) is indicated by a broken line arrow B1 from the air supply source. The flow of the supplied air is indicated by the arrow F1 on the alternate long and short dash line.

The air supplied from the air supply source is supplied to the first injection nozzle 51 through the air hose 66, and is discharged from the air nozzle. When air is discharged from the air nozzle, the pressure around the discharge port of the water nozzle becomes low, water is sucked up from the tank 40 through the third water passage pipe 65, and water is discharged from the water nozzle. The water is atomized by the collision of the air discharged from the air nozzle with the discharged water.

For example, when an air compressor is used, the particle size of the mist injected from the first injection nozzle 51 can be set to about 10 μm. When an air blower is used, the particle size of the mist injected from the first injection nozzle 51 can be set to about 13 to 30 μm.
The configuration relating to the first injection nozzle 51 and the supply device 60 described above can also be applied to the second injection nozzle 52 described later. For example, the second injection nozzle 52 may be a one-fluid nozzle or a two-fluid nozzle. Further, the supply device 60 for supplying water to the second injection nozzle 52 can be selected according to the type of the nozzle and the like, and may be provided with any of a pump 61, an air compressor, and an air blower.

As shown in FIG. 6, the third water pipe 65 is inserted inside the protective frame 9. The third water pipe 65 penetrates the wall 28 and extends from the internal space of the lower structure 20 to the internal space of the upper structure 19. A space S1 is formed between the inner surface of the protective frame 9 and the outer surface of the third water pipe 65. When the protective frame 9 is a protective frame in the form of combined use of air conditioner mist, the space S1 formed in the upper structure 19 is used as the air conditioner air passage 32. That is, the air-conditioning air passage 32 is formed between the inner surface of the protective frame 9 (inner surface of the upper structure 19) and the outer surface of the third water pipe 65.

Although not shown, all or part of the second water pipe 64 (see FIG. 14) may be inserted into the protective frame 9. In this case, the space formed between the inner surface of the protective frame 9 and the outer surface of the second water pipe 64 can be used as the air conditioning air passage 32.
When the protection frame 9 is a protection frame in which the air conditioner mist is used in combination, the first injection nozzle 51 is preferably arranged in the vicinity of the air conditioning air delivery unit 33 (first transmission unit 35) (FIGS. 5, FIGS. 6 and 6). 11 etc.). Specifically, as shown in FIG. 6, the mist MT injected from the first injection nozzle 51 is arranged so as to overlap with the outlet 34 of the air conditioner air delivery unit 33 (first transmission unit 35) in front view. It is preferable to do so. With such an arrangement, the mist MT injected from the first injection nozzle 51 can be diffused by the air conditioning air sent from the air conditioning air sending unit 33 (first sending unit 35), and the cooling effect can be enhanced. ..

Further, as shown in FIG. 6, when the protective frame 9 is a protective frame in the form of combined use of an air conditioner mist, it passes through a water guide unit 70 that guides water generated by driving the air conditioner unit 30 to the tank 40 and a water guide unit 70. A filter 71 for removing impurities contained in the water guided to the tank 40 can be provided.
The water guide unit 70 is at least one of a first water guide unit 72 that guides the drain water generated from the air conditioner unit 30 to the tank 40 and a second water guide unit 73 that guides the dew condensation water adhering to the surface of the protective frame 9 to the tank 40. Including one. The first water guide unit 72 is composed of a drain hose 72 that guides the drain water generated from the air conditioner unit 30. One end of the drain hose 72 is connected to the air conditioner unit 30, and the other end of the drain hose 72 is inserted into the water receiving portion 74. The drain water discharged from the air conditioner unit 30 to the drain hose 72 can enter the water receiving portion 74. In FIG. 6, the flow of drain water is indicated by the broken line arrow C1.

The water receiving portion 74 is provided above the first tank 41. The water receiving portion 74 is a cylindrical body that covers the outer periphery of the protective frame 9 (the outer periphery of the leg portion 21). The upper portion of the water receiving portion 74 has a gap G1 between the outer peripheral surface of the protective frame 9 and the lower portion thereof is in close contact with the outer peripheral surface of the protective frame 9. The lower portion of the gap G1 communicates with the internal space of the protective frame 9 via the water inlet hole 9c formed in the protective frame 9. The upper part of the gap G1 is open, and the dew condensation water adhering to the surface of the protective frame 9 flows down along the surface and can enter the water receiving portion 74 from the upper part of the gap G1. That is, the gap G1 between the water receiving portion 74 and the protective frame 9 constitutes the second water guiding portion 73. In FIG. 6, the flow of dew condensation water is indicated by the broken line arrow C2.

The filter 71 is arranged inside the water receiving portion 74. The filter 71 is arranged above the water entry hole 9c. The water introduced into the water receiving portion 74 via the first water guiding portion 72 and / or the second heading portion 73 passes through the filter 71 and then enters the first tank 41 through the water inlet hole 9c. As a result, the drain water and the dew condensation water are stored in the first tank 41 after the impurities are removed by the filter 71, so that they can be used as mist to be injected from the injection nozzle 50.

As shown in FIG. 1, the injection nozzle 50 can include a second injection nozzle 52 arranged in front of the driver's seat 3. The second injection nozzle 52 can inject water from the front of the driver's seat 3 toward the driver's seat 3. The second injection nozzle 52 can be attached to, for example, the front part of the floor step 13 of the work vehicle 1. However, the mounting position of the second injection nozzle 52 is not limited to the front portion of the floor step 13, and may be another position in front of the driver's seat 3 (for example, the bonnet 10 or the steering column 29).

As shown in FIG. 15, the second injection nozzle 52 includes a left nozzle 52L (hereinafter referred to as “second left nozzle 52L”) arranged to the left of the driver's seat 3 in the vehicle body width direction, and the driver's seat 3. The right nozzle 52R (hereinafter referred to as “second right nozzle 52R”) arranged to the right of the right nozzle is included. The second left nozzle 52L is provided on the left front portion of the floor step 13. The second right nozzle 52R is provided on the right front portion of the floor step 13. As shown in FIG. 1, the second injection nozzle 52 is arranged at a position lower than the driver's seat 3 (near the foot of the driver OP). However, the second injection nozzle 52 may be arranged at a height position near the seat surface 3b of the driver's seat 3 or at a position higher than the seat surface 3b.

A water pipe (not shown) that guides the water in the tank 40 (the first tank 41 and / or the second tank 42) to the second injection nozzle 52 is connected to the second injection nozzle 52. This water pipe is connected to the tank 40 via a pump 61 (see FIG. 14) when the second injection nozzle 52 is a one-fluid nozzle. When the second injection nozzle 52 is a two-fluid nozzle, the water nozzle is connected to the tank 40, and the air nozzle is connected to an air supply source such as an air compressor.

The protective frame 9 may include at least one of the first injection nozzle 51 and the second injection nozzle 52, but it is preferable that the protection frame 9 includes both. By using the first injection nozzle 51 and the second injection nozzle 52 in combination, mist can be injected toward the driver from the rear and front of the driver seated in the driver's seat 3. Therefore, for example, the nape of the driver and the face can be cooled at the same time, and an excellent cooling effect can be obtained.

The injection nozzle 50 may include other injection nozzles arranged at different positions from the first injection nozzle 51 and the second injection nozzle 52. The other injection nozzles can be arranged at arbitrary positions such as, for example, in the vicinity of the second delivery unit 36, in the vicinity of the third delivery unit 37, and on the side (left side, right side) of the driver's seat 3.
The work vehicle 1 is provided with a changing mechanism 80 that can change the direction of the injection nozzle 50 (first injection nozzle 51, second injection nozzle 52). FIG. 16 is a diagram showing an example of the changing mechanism 80. The changing mechanism 80 shown in FIG. 16 has a first connecting member 81 and a second connecting member 82. The first connecting member 81 is a bendable bellows-shaped cylinder, and is connected to a water pipe (water pipe 62 or the like) that guides the water in the tank 40 to the injection nozzle 50. The second connecting member 82 has a first portion 82a connected to the first connecting member 81 and a second portion 82b connected to the injection nozzle 50. Inside the second connecting member 82, a passage 83 penetrating the first portion 82a and the second portion 82b is formed. The water that has entered the first connecting member 81 from the water pipe 62 is injected from the injection nozzle 50 through the passage 83 inside the second connecting member 82.

As shown by the arrow Z1, the second connecting member 82 is rotatable around the axis X1 of the water pipe 62. By rotating the second connecting member 82 around the axis X1, the direction of the injection nozzle 50 can be changed around the axis X1. Further, by bending the first connecting member 81, the direction of the injection nozzle 50 can be changed by tilting it with respect to the axis X1. For example, FIG. 16A shows a state in which the injection nozzle 50 faces forward, FIG. 16B shows a state in which the injection nozzle 50 faces backward, and FIG. 16C shows a state in which the injection nozzle 50 is tilted diagonally downward. Is.

The configuration of the changing mechanism 80 is not limited to the configuration shown in FIG. 16, and may be another configuration using, for example, a motor or gears. The rotation and tilting of the injection nozzle 50 using the changing mechanism 80 may be performed manually or mechanically using a motor or the like.
In the changing mechanism 80, the direction of the first injection nozzle 51 is such that the water (mist) MT ejected from the first left nozzle 51L and the water (mist) MT ejected from the first right nozzle 51R are above the driver's seat 3. It is possible to change between the first direction (see FIG. 17) where the vehicle merges at and the second direction (see FIG. 18) where the vehicle does not merge above the driver's seat 3. As shown in FIG. 17, when the direction of the first injection nozzle 51 is set to the first direction, the mist MT can be concentrated and applied to the driver OP from diagonally left rear and diagonally right rear. In this case, since the mist concentration region MR can be generated around the driver OP, the driver OP can be effectively cooled. As shown in FIG. 18, when the direction of the first injection nozzle 51 is the second direction, the mist curtain (mist barrier) MC can be generated on the side and the front of the driver OP, so that the driver OP can be generated. Can be protected from dust and the like.

Further, in the changing mechanism 80, the direction of the second injection nozzle 52 is such that the water (mist) MT ejected from the second left nozzle 52L and the water (mist) MT ejected from the second right nozzle 52R are in the driver's seat 3. It is possible to change between a first direction (see FIG. 15) that merges above the driver's seat 3 and a second direction (see FIG. 19) that does not merge above the driver's seat 3. As shown in FIG. 15, when the direction of the second injection nozzle 52 is set to the first direction, the mist MT can be concentrated and applied to the driver OP from the diagonally left front and the diagonally right front. In this case, since the mist concentration region MR can be generated around the driver OP, the driver OP can be effectively cooled. As shown in FIG. 19, when the direction of the second injection nozzle 52 is set to the second direction, the mist curtain MC can be generated on the side and the rear of the driver OP, so that the driver OP can be generated from dust or the like. It becomes possible to protect.

Further, although not shown, by using the first injection nozzle 51 and the second injection nozzle 52 in combination and setting both nozzles in the first direction, four directions (diagonal to the left) with respect to the driver OP. Since the mist can be concentrated and applied from the rear, diagonally right rear, diagonally left front, diagonally right front), the driver can be cooled more effectively.
Further, although not shown, the first injection nozzle 51 and the second injection nozzle 52 are used in combination, and both nozzles are oriented in the second direction, so that the driver OP can be sideways, forward, and rearward. Since the mist curtain can be generated, the driver OP can be more effectively protected from dust and the like.

Further, as shown in FIG. 20, the changing mechanism 80 can change the injection direction of the first injection nozzle 51 to the rear. FIG. 20 shows a state in which the injection direction of the first injection nozzle 51 is rearward and downward. In this case, the first injection nozzle 51 can inject water toward the work device W1 side mounted on the rear mounting portion 12A to the rear of the vehicle body 2. Therefore, when the work device W1 (for example, a cultivator or the like) is mounted on the rear mounting portion 12A and the work is performed, it becomes possible to spray mist toward the source of dust generated by the work of the work device W1. It is possible to prevent dust from scattering and reaching the vicinity of the driver OP.

Further, as shown in FIG. 21, the changing mechanism 80 can change the injection direction of the second injection nozzle 52 forward. FIG. 21 shows a state in which the injection direction of the second injection nozzle 52 is forward and upward. In this case, the second injection nozzle 52 can inject the mist MT toward the work device W2 side mounted on the front mounting portion 12B to the front of the vehicle body 2. Therefore, when the work device W2 (for example, a front loader or the like) is mounted on the front mounting portion 12B and the work is performed, the work is directed toward the source of the dust E1 generated by the work by the work device W2 (for example, the transportation of the earth and sand D1). It is possible to spray the mist MT, and it is possible to prevent dust from scattering and reaching the vicinity of the driver OP.

Further, as shown in FIGS. 22 and 23, by using the first injection nozzle 51 and the second injection nozzle 52 in combination, both a cooling effect and a dustproof effect on the driver OP can be obtained. In FIG. 22, the mist MT is injected from the first injection nozzle 51 to the driver OP, and the mist MT is injected from the second injection nozzle 52 toward the source of the dust E1 generated by the work of the work device W2. Indicates the state of being. In FIG. 23, the mist MT is injected from the second injection nozzle 52 to the driver OP, and the mist MT is injected from the first injection nozzle 51 toward the source of the dust E1 generated by the work of the work device W1. Indicates the state of being. In this way, by using the first injection nozzle 51 behind the driver OP and the second injection nozzle 52 in front of the driver OP together, both a cooling effect and a dustproof effect on the driver OP can be obtained. Can be done.

When the protection frame 9 is a protection frame in which the air conditioner mist is used in combination, the usage mode in which the air conditioner air CW is applied to the driver OP (air conditioner air mode) (see FIG. 13) and the usage mode in which the driver OP is cooled by the mist MT (see FIG. 13). Mist mode) (see FIG. 24) can be used properly.
As shown in FIG. 13, in the case of the air-conditioning wind mode, the air-conditioning wind CW can be locally applied to the driver OP. For example, the air conditioner wind CW can be applied to the neck of the driver OP from the first transmission unit 35, and the air conditioner air CW can be applied to the head of the driver OP from the third transmission unit 37. In this way, by locally applying air-conditioning air (cold air or warm air) to the neck and head, which are areas where a feeling of coolness and warmth is likely to be obtained, the driver OP is effectively given a feeling of coolness or warmth. Can be given. Further, since the cold air or warm air concentrated region CR can be generated around the head of the driver OP, the driver OP can be effectively given a cool feeling or a warm feeling.

As shown in FIG. 24, in the mist mode, the mist MT can be injected to the driver OP side. For example, by injecting the mist MT around the driver OP from the first injection nozzle 51, the temperature around the driver OP can be lowered by utilizing the heat of vaporization when the mist evaporates. Further, the driver OP can be protected from dust and the like by generating the mist curtain MC around the driver OP.

When cold air is used in the air-conditioned air mode, the driver OP has an excellent local cooling effect on the body. On the other hand, the mist mode is excellent in the cooling effect around the driver OP. Therefore, when the driver OP feels the heat, he / she can properly use the cold air in the air-conditioning air mode and the mist mode according to the outside air temperature and his / her preference.
The driver OP can also use the cold air in the air-conditioned air mode in combination with the mist mode. In this case, a high cooling effect due to both cold air and mist can be obtained, and a dustproof effect due to the mist curtain and a dustproof effect due to the air curtain can also be obtained.

In this way, by adopting one or both of the air-conditioning wind mode and the mist mode, the work vehicle having no cabin (the driver's seat 3 is open to the outside air) has a cabin. It is possible to obtain comfort (coolness or warmth) and dustproof effect similar to those of a work vehicle.
As shown in FIG. 9, a drink holder 85 can be attached to the protective frame 9. The drink holder 85 is a holder capable of holding a drinking water container CN (for example, a PET bottle, a water bottle, etc.) in contact with or close to the outer peripheral surface of the protective frame 9. The drink holder 85 is composed of, for example, a box body in which the lower portion is closed and the upper portion is open, and the drinking water container CN can be taken in and out from the upper portion. The drink holder 85 is attached to a portion of the protective frame 9 in which the air-conditioning air passage 32 is formed (for example, the upright portion 15). Thereby, the beverage held in the drink holder 85 can be cooled or heated by the cold air or the warm air passing through the air-conditioning air passage 32.

It is preferable that the protective frame 9 of the above-described embodiment is removable from the vehicle body 2. As a result, the protective frame of the existing work vehicle 1 can be removed, and the protective frame 9 can be attached to the vehicle body 2 in place of the protective frame. Therefore, the air conditioning equipment (air conditioning air supply structure and / or mist supply structure) can be retrofitted to the work vehicle 1 that does not have the cabin and the air conditioning equipment.

When the protective frame 9 has an air conditioner air supply structure, it is preferable that the protective frame 9 is detachable from the vehicle body 2 together with the air conditioner unit 30. Thereby, the protective frame of the existing work vehicle 1 can be removed, and the protective frame 9 having the air conditioner unit 30, the air conditioner air passage 32, and the air conditioner air sending unit 33 can be attached to the vehicle body 2 in place of the protective frame. Therefore, the air conditioning equipment (air conditioning air supply structure) can be retrofitted to the work vehicle 1 that does not have the cabin and the air conditioning equipment. In this case, the power supply such as a battery or an alternator mounted on the vehicle body 2 and the air conditioner unit 30 are connected by a power supply line such as a wire harness.

When the protective frame 9 has a mist supply structure, it is preferable that the protective frame 9 can be attached to and detached from the vehicle body 2 together with the tank 40, the injection nozzle 50, and the supply device 60. Thereby, the protective frame of the existing work vehicle 1 can be removed, and the protective frame 9 having the tank 40, the injection nozzle 50, and the supply device 60 can be attached to the vehicle body 2 in place of the protective frame. Therefore, the cooling equipment (mist supply structure) can be retrofitted to the work vehicle 1 that does not have the cabin and the cooling equipment. In this case, the power supply such as a battery or an alternator mounted on the vehicle body 2 and the supply device 60 (pump 61, air compressor, air blower, etc.) are connected by a power supply line such as a wire harness.

When the protective frame 9 has both an air conditioner air supply structure and a mist supply structure, it is preferable that the protective frame 9 is detachable from the vehicle body 2 together with the air conditioner unit 30, the tank 40, the injection nozzle 50, and the supply device 60. .. As a result, the protection frame of the existing work vehicle 1 is removed, and instead of the protection frame, the air conditioner unit 30, the air conditioner air passage 32, the air conditioner air transmission unit 33, the tank 40, the injection nozzle 50, and the supply device 60 are provided. The frame 9 can be attached to the vehicle body 2. Therefore, air conditioning equipment (air conditioning air supply structure and mist supply structure) can be retrofitted to the work vehicle 1 that does not have a cabin and air conditioning equipment. In this case, the power supply such as a battery or an alternator mounted on the vehicle body 2 is connected to the air conditioner unit 30 and the supply device 60 by a power supply line such as a wire harness.

Further, the protection frame 9 having the air conditioning equipment may be configured by retrofitting the existing protection frame (protection frame having no air conditioning equipment) with the air conditioning air supply structure and / or the mist supply structure.
The work vehicle 1 can switch between the supply of air-conditioned air by the air-conditioned air supply structure and the injection of mist by the mist supply structure. In addition, it is possible to switch between the supply of air-conditioning air and the combined use of mist injection and the use of either one. Further, it is possible to select the air-conditioning air sending unit that sends out the air-conditioning air (selecting any one or more of the first sending unit 35, the second sending unit 36, and the third sending unit 37). Further, it is possible to select an injection nozzle for injecting mist (select one or both of the first injection nozzle 51 and the second injection nozzle 52). Further, the direction of the injection nozzle 50 (first injection nozzle 51, second injection nozzle 52) can be changed. It is preferable that these switching, selection, and change can be performed by operating an operation unit (switch, lever, dial, etc.) in the vicinity of the driver's seat 3.

Further, the control device mounted on the work vehicle 1 may automatically perform the above-mentioned switching, selection, and change control based on the mounting status of the work devices W1 and W2 and the type of the work device. Further, a sensor capable of measuring the surrounding environment (temperature, humidity, wind speed, wind direction, etc.) is attached to the vehicle body 2, work devices W1, W2, etc., and the control device switches, selects, and selects the above-mentioned based on the measured value of the sensor. The change may be controlled automatically. When performing these controls, communication such as information and control signals between the work devices W1 and W2 and the control device can be performed via ISOBUS or the like.

FIG. 25 is a side view showing another embodiment of the work vehicle 1. The work vehicle 1 of the present embodiment is a construction machine provided with a protective frame 9, and is specifically a backhoe.
The work vehicle (backhoe) 1 includes a vehicle body 2, a driver's seat 3 mounted on the vehicle body 2, and a traveling device 4 that supports the vehicle body 2 so as to be able to travel.
The vehicle body 2 is a swivel table that can turn around an axial center in the vertical direction. The traveling device 4 is a crawler type traveling device. A mounting portion 12 (front mounting portion 12B) on which the working device W2 is mounted is provided on the front portion of the vehicle body 2. The work device W2 includes a boom 90, an arm 91, a work tool (bucket) 92, and the like, and can excavate the ground. A bonnet 10 that covers the prime mover and the like is arranged on the rear upper portion of the vehicle body 2.

The protective frame 9 is attached to the vehicle body 2. Although FIG. 25 shows the protection frame 9 of the third embodiment, it may be the protection frame 9 of the first embodiment or the second embodiment. Further, the protective frame 9 may be any of "air conditioner mist combined form", "mist form", and "air conditioner mist combined form".
Further, although the work vehicle (backhoe) 1 shown in FIG. 25 includes the first injection nozzle 51 as the injection nozzle 50, it may include both the first injection nozzle 51 and the second injection nozzle 52.

In the protective frame 9, the standing portion 15 stands on the vehicle body 2. The leg portion 21 extends rearward and downward from the lower part of the standing portion 15. It is attached to the rear part of the vehicle body 2. However, the shape of the leg portion 21 is not limited to the shape shown in the figure, and may extend from the lower part of the standing portion 15 to the front lower part, or from the lower part of the standing portion 15 to the lower left or the lower right. It may be extended. Further, the mounting position of the mounting portion 22 is not limited to the position shown in the figure, and may be mounted on the side portion or the front portion of the vehicle body 2. Other configurations of the protection frame 9 are as described above.

According to the work vehicle 1 of the above embodiment, the effects described below are obtained.
The work vehicle 1 according to the embodiment of the present invention includes a vehicle body 2, a driver's seat 3 mounted on the vehicle body 2, a protective frame 9 for protecting a driver standing upright so as to extend above the driver's seat 3. The air-conditioning unit 30 that generates air-conditioning air, the air-conditioning air passage 32 that is provided inside the protective frame 9 and allows the air-conditioning air generated in the air-conditioning unit 30 to pass through, and the air-conditioning air that passes through the air-conditioning air passage 32 on the driver's seat 3 side. It is provided with an air-conditioning wind sending unit 33 that sends out toward.

According to this configuration, in the work vehicle 1 provided with the protection frame 9 for protecting the driver, the driver OP can be provided with the air-conditioning air supply structure capable of supplying the air-conditioning air. Therefore, it is possible to apply the air-conditioning air adjusted to a comfortable temperature to the driver OP, and it is possible to give comfort to the driver OP and reduce the physical burden on the driver OP. Further, even if the work vehicle does not have a cabin (the driver's seat 3 is open to the outside air), the work vehicle 1 can obtain an excellent air conditioning effect due to the air conditioning air.

Further, the protective frame 9 includes a standing portion 15 including a left standing portion 15L and a right standing portion 15R standing at intervals in the vehicle body width direction, and a connecting portion 16 connecting the left standing portion 15L and the left standing portion 15L. The air-conditioned air sending unit 33 is provided in the standing unit 15 and includes a first transmitting unit 35 that sends out air-conditioned air from the rear to the front of the driver's seat 3.
According to this configuration, the air-conditioning air can be blown from behind to the driver OP seated in the driver's seat 3. Therefore, the driver OP can be cooled or heated from the rear, and the air-conditioned wind can prevent the dust generated in front of the driver from hitting the driver's face due to work or running.

Further, the air-conditioning air sending section 33 includes a second sending section 36 provided in the connecting section 16 to send the air-conditioning air from the rear upper part to the front lower part of the driver's seat 3.
According to this configuration, the air-conditioning air can be applied to the driver OP seated in the driver's seat 3 from the rear upper side. Therefore, it is possible to effectively give the driver OP a cool feeling and a warm feeling by applying an air-conditioning wind to the nape of the neck and the back of the head, which are parts where a cool feeling and a warm feeling are easily obtained.

Further, the protective frame 9 includes a roof portion 26 attached to the upper part of the upright portion 15 and covering the upper part of the driver's seat 3, and a front extension portion 27 extending forward from the connecting portion 16 along the lower surface of the roof portion 26. The air-conditioned air sending unit 33 includes a third transmitting unit 37 provided in the front extension unit 27 to send out air-conditioned air from above to the bottom of the driver's seat 3.
According to this configuration, the air-conditioning air can be applied to the driver OP seated in the driver's seat 3 from above. Therefore, it is possible to effectively give the driver OP a cool feeling and a warm feeling by applying an air-conditioning wind to the top of the head, which is a part where a cool feeling and a warm feeling are easily obtained. Further, it is possible to obtain a dustproof effect by generating an air curtain by air conditioning wind in front of the driver OP.

Further, the air conditioner unit 30 is attached to the protective frame 9.
According to this configuration, it is not necessary to secure a space on the vehicle body 2 for installing the air conditioner unit 30. Further, by integrating the air conditioner unit 30 and the protective frame 9, when the protective frame 9 is attached to the vehicle body 2, the air conditioner unit 30 can also be attached as an integral body with the protective frame 9.

Further, the connecting portion 16 connects the upper connecting portion 17 that connects the upper end of the left standing portion 15L and the upper end of the left standing portion 15L, and the left standing portion 15L and the left standing portion 15L below the upper connecting portion 17. The air conditioner unit 30 is attached to the lower connecting portion 18 behind the driver's seat 3, including the lower connecting portion 18.
According to this configuration, since the air conditioner unit 30 is arranged behind the driver's seat 3, the air conditioner unit 30 does not interfere with the driver. Further, by attaching the air conditioner unit 30 to the lower connecting portion 18 of the protective frame 9, it is possible to prevent the air conditioner unit 30 from raising the position of the center of gravity of the work vehicle 1.

Further, the protective frame 9 can be attached to and detached from the vehicle body 2 together with the air conditioner unit 30.
According to this configuration, the protective frame of the existing work vehicle 1 can be removed and the protective frame 9 can be attached to the vehicle body 2 in place of the protective frame. Therefore, the air conditioning equipment (air conditioning air supply structure) can be retrofitted to the work vehicle 1 that does not have the cabin and the air conditioning equipment.

Further, the work vehicle 1 includes a tank 40 for storing water, an injection nozzle 50 for injecting water in a mist form, and a supply device 60 for supplying the water in the tank 40 to the injection nozzle 50. Is provided on the protective frame 9 and can inject water toward the driver's seat 3 side.
According to this configuration, it is possible to obtain a work vehicle 1 having a mist supply structure in addition to the air-conditioning air supply structure. Therefore, it is possible to obtain a cooling effect and a dustproof effect by using both cold air and mist. Thereby, it is possible to provide the work vehicle 1 which can obtain the comfort (cool feeling) similar to that of the work vehicle having the cabin without having the cabin.

The work vehicle 1 according to an embodiment of the present invention includes a vehicle body 2, a driver's seat 3 mounted on the vehicle body 2, a protective frame 9 for protecting a driver standing upright so as to extend above the driver's seat 3, and a protective frame 9. A tank 40 for storing water, an injection nozzle 50 for injecting water in a mist form, and a supply device 60 for supplying the water in the tank 40 to the injection nozzle 50 are provided, and the internal space of the protective frame 9 is the tank 40. It constitutes a water storage space.

According to this configuration, in the work vehicle 1 provided with the protection frame 9 for protecting the driver and equipped with the mist supply structure capable of injecting mist-like water to the driver, the installation space of the tank for storing water is surely secured. Can be secured. Specifically, since the internal space of the protective frame 9 constitutes the water storage space of the tank 40, the installation space of the tank 40 can be reliably secured without securing the installation space in the vicinity of the protective frame 9. Further, even in a work vehicle having no cabin (the driver's seat 3 is open to the outside air), an excellent cooling effect can be obtained by the mist.

Further, the protective frame 9 has an upright portion 15 that stands up behind the driver's seat 3 and a leg portion 21 that extends downward from the upright portion 15 and is arranged behind the vehicle body 2, and has an internal space of the leg portion 21. Consists of the water storage space of the tank 40.
According to this configuration, the legs 21 constituting the tank 40 are arranged behind the vehicle body 2, so that the installation space for the tank 40 can be easily secured. Further, it is possible to prevent the center of gravity of the work vehicle 1 from becoming high due to the installation of the tank 40.

Further, the leg portion 21 includes a left leg portion 21L and a right leg portion 21R arranged at intervals in the vehicle body width direction, and the tank 40 includes a first tank 41 and a second tank 42, and a first tank. The 41 is configured by using the internal space of the protective frame 9 as a water storage space, and the second tank 42 connects the left leg portion 21L and the right leg portion 21R.
According to this configuration, since a sufficient amount of water can be secured by the first tank 41 and the second tank 42, it is possible to inject mist for a long time. Further, since the second tank 42 functions as a reinforcing material for reinforcing the leg portion 21, the rigidity of the protective frame 9 can be improved without providing a reinforcing material for connecting the left leg portion 21L and the right leg portion 21R. can.

Further, the injection nozzle 50 includes a first injection nozzle 51 provided on the upright portion 15 and capable of injecting water from the rear of the driver's seat 3 toward the driver's seat 3 side.
According to this configuration, the mist can be injected from the rear to the driver OP seated in the driver's seat 3 by the first injection nozzle 51. Therefore, the nape of the driver OP, the back of the head, the arms, and the like can be cooled by the mist from behind. It is also possible to generate a mist curtain (mist barrier) in front of the driver OP to obtain a dustproof effect.

Further, the injection nozzle 50 includes a second injection nozzle 52 arranged in front of the driver's seat 3, and the second injection nozzle 52 can inject water from the front of the driver's seat 3 toward the driver's seat 3. ..
According to this configuration, the second injection nozzle 52 can inject mist from the front to the driver OP seated in the driver's seat 3. Therefore, the face, chest, and the like of the driver OP can be cooled by the mist from the front. It is also possible to generate a mist curtain (mist barrier) behind the driver OP to obtain a dustproof effect.

Further, the work vehicle 1 includes a rear mounting portion 12A on which the work device W1 can be mounted behind the vehicle body 2, and the first injection nozzle 51 faces the vehicle body 2 toward the work device W1 mounted on the rear mounting portion 12A. It is possible to spray water to the rear.
According to this configuration, when the work device W1 is mounted on the rear mounting portion 12A and the work is performed, the mist can be sprayed toward the source of the dust generated by the work of the work device W1, and the dust is scattered. It is possible to prevent the vehicle from reaching the surroundings of the driver.

Further, the work vehicle 1 includes a front mounting portion 12B on which the work device W2 can be mounted in front of the vehicle body 2, and the second injection nozzle 52 faces the vehicle body 2 toward the work device W2 mounted on the front mounting portion 12B. It is possible to spray water to the front.
According to this configuration, when the work device W2 is mounted on the front mounting portion 12B and the work is performed, the mist can be sprayed toward the source of the dust generated by the work by the work device W2, and the dust is scattered. It is possible to prevent the vehicle from reaching the surroundings of the driver.

Further, the work vehicle 1 is provided with a changing mechanism 80 that can change the direction of the injection nozzle 50, and the injection nozzle 50 is a left nozzle 51L, 52L arranged to the left of the driver's seat 3 in the vehicle body width direction. Including the right nozzles 51R and 52R arranged to the right of the driver's seat 3, the changing mechanism 80 directs the injection nozzle 50 from the water ejected from the left nozzles 51L and 52L and the right nozzles 51R and 52R. It is possible to change the first direction in which the sprayed water meets above the driver's seat 3 and the second direction in which the jetted water does not merge above the driver's seat 3.

According to this configuration, when the direction of the injection nozzle 50 is set to the first direction, the mist MT can be concentrated and applied to the driver OP, so that the driver OP can be effectively cooled. Will be. Further, when the direction of the injection nozzle 50 is set to the second direction, a mist curtain (mist barrier) can be generated in the vicinity of the driver OP, so that the driver OP can be protected from dust and the like. ..

Further, the protective frame 9 can be attached to and detached from the vehicle body 2 together with the tank 40, the injection nozzle 50, and the supply device 60.
According to this configuration, the protective frame of the existing work vehicle 1 can be removed and the protective frame 9 can be attached to the vehicle body 2 in place of the protective frame. Therefore, the cooling equipment (mist supply structure) can be retrofitted to the work vehicle 1 that does not have the cabin and the cooling equipment.

Further, the work vehicle 1 has an air conditioner unit 30 that generates cold air that cools the driver OP seated in the driver's seat 3, and a cold air passage 32 that is provided inside the protective frame 9 and through which the cold air generated by the air conditioner unit 30 passes. And a cold air delivery unit 33 that sends out cold air that has passed through the cold air passage 32 toward the driver's seat 3.
According to this configuration, it is possible to obtain a work vehicle 1 having a cold air supply structure in addition to the mist supply structure. Therefore, it is possible to obtain a cooling effect and a dustproof effect by using both cold air and mist. Thereby, it is possible to provide the work vehicle 1 which can obtain the comfort (cool feeling) similar to that of the work vehicle having the cabin without having the cabin.

Further, inside the protective frame 9, a first space 38 constituting an air-conditioned air passage (cold air passage) 32 and a second space 39 constituting a water storage space of the tank 40 are formed.
According to this configuration, the internal space of the protective frame 9 can be effectively used as a space for air conditioning air (cold air) and mist distribution. Further, it is not necessary to secure a large space outside the protective frame 9 for installing a duct constituting an air-conditioning air passage (cold air passage) or a tank for storing water. Further, by setting the upper part of the protective frame 9 as the first space 38 and the lower part as the second space 39, the position of the center of gravity of the protective frame 9 is lowered, and the work vehicle 1 can be stabilized.

Further, the supply device 60 has a water pipe 62 that guides the water in the tank 40 to the injection nozzle, the water pipe 62 is inserted inside the protective frame 9, and the air conditioning air passage (cold air passage) 32 is , Is formed between the inner surface of the protective frame 9 and the outer surface of the water pipe 62.
According to this configuration, the water pipe 62 and the air-conditioned air passage (cold air passage) 32 are double pipes (the water pipe 62 is the inner pipe and the air-conditioned air passage (cold air passage) 32 is the outer pipe) inside the protective frame 9. Can be configured as. Therefore, the inside of the protective frame 9 can be effectively used, and the water flowing through the water pipe 62 can be cooled by flowing cold air through the air-conditioning air passage (cold air passage) 32.

Further, the injection nozzle 50 is arranged in the vicinity of the air conditioning air delivery unit (cold air delivery unit) 33.
According to this configuration, the mist injected from the injection nozzle 50 can be diffused by the air conditioning air sent from the air conditioning air sending unit (cold air sending unit) 33, and the cooling effect can be enhanced.
Further, the work vehicle 1 removes impurities contained in the first water guide portion 72 that guides the drain water generated from the air conditioner unit 30 to the tank 40 and the water that is guided to the tank 40 through the first water guide portion 72. The filter 71 and the like are provided.

According to this configuration, the drain water generated from the air conditioner unit 30 can be stored in the tank 40 after removing impurities by the filter 71, and can be used as mist to be injected from the injection nozzle 50.
Further, the work vehicle 1 contains impurities contained in the second water guide portion 73 that guides the dew condensation water adhering to the surface of the protective frame 9 to the tank 40 and the water that is guided to the tank 40 through the second water guide portion 73. It includes a filter 71 for removing.

According to this configuration, the dew condensation water adhering to the surface of the protective frame 9 can be stored in the tank 40 after removing impurities by the filter 71, and can be used as mist to be injected from the injection nozzle 50.
Although one embodiment of the present invention has been described above, it should be considered that the embodiments disclosed this time are exemplary in all respects and are not restrictive. The scope of the present invention is shown by the scope of claims rather than the above description, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

1 Work vehicle 2 Body 3 Driver's seat 9 Protective frame 12A Rear mounting part 12B Front mounting part 15 Standing part 21 Leg part 21L Left leg part 21R Right leg part 30 Air conditioner unit 32 Cold air passage 33 Cold air sending part 38 First space 39 Second Space 40 Tank 41 1st tank 42 2nd tank 50 Injection nozzle 51 1st injection nozzle 51L Left nozzle 51R Right nozzle 52 2nd injection nozzle 52L Left nozzle 52R Right nozzle 60 Supply device 71 Filter 72 1st headrace 73 2nd water guide Part 80 Change mechanism OP Driver W1 Working device W2 Working device

Claims (15)

With the car body
The driver's seat mounted on the car body and
A protective frame for driver protection that stands up so as to extend above the driver's seat,
A tank for storing water and
A spray nozzle that sprays water in the form of a mist,
A supply device that supplies the water in the tank to the injection nozzle,
Equipped with
A work vehicle in which the internal space of the protective frame constitutes the water storage space of the tank. The protective frame has an upright portion that stands up behind the driver's seat and legs that extend downward from the upright portion and are arranged behind the vehicle body.
The work vehicle according to claim 1, wherein the internal space of the legs constitutes the water storage space of the tank. The legs include a left leg and a right leg that are spaced apart in the width direction of the vehicle body.
The tank includes a first tank and a second tank.
The first tank is configured with the internal space of the protective frame as a water storage space.
The work vehicle according to claim 2, wherein the second tank is connected to the left leg portion and the right leg portion. The work vehicle according to claim 2 or 3, wherein the injection nozzle includes a first injection nozzle provided in the upright portion and capable of injecting water from the rear of the driver's seat toward the driver's seat side. The injection nozzle includes a second injection nozzle arranged in front of the driver's seat.
The work vehicle according to any one of claims 1 to 4, wherein the second injection nozzle can inject water from the front of the driver's seat toward the driver's seat side. A rear mounting part on which the work device can be mounted is provided at the rear of the vehicle body.
The work vehicle according to claim 4, wherein the first injection nozzle can inject water toward the work device side mounted on the rear mounting portion to the rear of the vehicle body. A front mounting part on which a work device can be mounted is provided in front of the vehicle body.
The work vehicle according to claim 5, wherein the second injection nozzle can inject water toward the work device side mounted on the front mounting portion to the front of the vehicle body. It is equipped with a changing mechanism that allows the direction of the injection nozzle to be changed.
The injection nozzle includes a left nozzle arranged to the left of the driver's seat and a right nozzle arranged to the right of the driver's seat in the vehicle body width direction.
The changing mechanism adjusts the direction of the injection nozzle to a first direction in which the water ejected from the left nozzle and the water ejected from the right nozzle meet above the driver's seat and above the driver's seat. The work vehicle according to any one of claims 1 to 7, which can be changed to a second direction that does not merge. The work vehicle according to any one of claims 1 to 8, wherein the protective frame is detachable from the vehicle body together with the tank, the injection nozzle, and the supply device. An air conditioner unit that generates cold air to cool the driver seated in the driver's seat, and
A cold air passage provided inside the protective frame and through which cold air generated by the air conditioner unit passes,
A cold air delivery unit that sends cold air through the cold air passage toward the driver's seat,
The work vehicle according to any one of claims 1 to 9. The work vehicle according to claim 10, wherein a first space constituting the cold air passage and a second space constituting the water storage space of the tank are formed inside the protective frame. The supply device has a water pipe that guides the water in the tank to the injection nozzle.
The water pipe is inserted inside the protective frame, and the water pipe is inserted into the inside of the protective frame.
The work vehicle according to claim 10 or 11, wherein the cold air passage is formed between the inner surface of the protective frame and the outer surface of the water pipe. The work vehicle according to any one of claims 10 to 12, wherein the injection nozzle is arranged in the vicinity of the cold air delivery unit. The first water guide section that guides the drain water generated from the air conditioner unit to the tank,
A filter for removing impurities contained in the water guided to the tank through the first water guide section,
The work vehicle according to any one of claims 10 to 13. A second water guiding portion that guides dew condensation water adhering to the surface of the protective frame to the tank, and
A filter for removing impurities contained in the water guided to the tank through the second water guide section,
The work vehicle according to any one of claims 10 to 14.

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