JP6115829B2 - Working part structure of work vehicle - Google Patents

Description

  The present invention relates to a prime mover structure of a work vehicle including an oxidation catalyst device that oxidizes unburned gas contained in engine exhaust gas.

  Conventionally, in order to prevent the fine particles contained in the engine exhaust gas from being scattered to the outside, there has been proposed a drive part structure for a working vehicle in which an exhaust gas purification device equipped with a collecting filter is provided inside the fuselage on the upper surface of the engine. (Patent Document 1).

  Also, on the outside of the engine body, a radiator that cools the water circulating in the engine and a fan that sucks outside air between the engine and the radiator are provided, and the rotation direction of the fan is switched by moving the tension operation body. There has been proposed a prime mover structure for a working vehicle that cools a radiator and removes dust, dust and the like attached to a filter body of a cover provided outside the radiator (Patent Document 2).

JP 2013-1132 A Japanese Patent Laid-Open No. 2001-263063

However, in the prime mover structure of the working vehicle of Patent Document 1, the inner side of the body of the exhaust gas purification device protrudes inward from the heat shield cover arranged on the lower side of the operation seat. There has been a problem of raising the temperature in the operation seat by blowing the surrounding air to the operation seat.
Further, since the tail pile for guiding the exhaust gas of the exhaust gas purification device to the outside is extended below the threshing device, a problem has been pointed out that the exhaust gas is discharged outside without effectively utilizing the preheating of the exhaust gas.

In the driving part structure of the working vehicle of Patent Document 2, the ability of exhausting the inside air outside the engine room in the reverse direction of the fan is lower than the ability of the outside air to suck into the engine room in the forward direction of the fan. , Swarf and dust adhering to the filter body mounted on the engine room cover cannot be removed sufficiently, and the filter body is clogged with the dust and dust that cannot be removed, and the cooling efficiency of the radiator is reduced. As a result, there is a problem that the engine is overheated.
In addition, since the fan is switched between the forward rotation direction and the reverse rotation direction by rotating the tension operating body including the transmission belt, there is a problem that the transmission belt is extremely deteriorated and the maintenance and inspection work is frequently performed. there were.
Therefore, the main problem of the present invention is to eliminate such problems.

The present invention that has solved the above problems is as follows.
According to the first aspect of the present invention, the engine (E) is disposed below the cockpit (6) and the cockpit (6), and the engine (E) is disposed at a portion inside the fuselage above the engine (E). An oxidation catalyst device (11) that oxidizes unburned fuel in exhaust gas discharged from the engine is disposed along the front-rear direction , and the engine (E) and an engine (E provided on the right side of the engine (E)) Between the radiator (50) that cools the cooling water circulating through the radiator) (50) that can be switched between a driving state and a stopped state, and an exhaust dust exhaust fan that can be switched between the driving state and the stopped state. (30) is disposed, and a heat shield cover (95) is provided between the side panel (6A) disposed inside the fuselage in the cockpit (6) and the oxidation catalyst device (11) in a side view, and the shield is provided . The thermal cover (95) is connected to the oxidation catalyst device ( 1) a front side plate (95A) provided on the front side of the front part and extending in the vertical direction, and provided on the upper side of the upper part of the oxidation catalyst device (11), from the upper end part of the front side plate (95A) to the rear side. An extending horizontal plate (95B), and an inclined plate (95C) provided on the rear side of the rear portion of the oxidation catalyst device (11) and extending downwardly from the rear end of the horizontal plate (95B). The inclined plate (95C) is formed by only the rear plate (95D) extending downward from the rear end of the inclined plate (95C), and the heat shield cover (95) is spaced from the oxidation catalyst device (11) by a predetermined distance. The lower part of the front plate (95A) and the lower part of the rear plate (95D) are respectively lower than the lower part of the oxidation catalyst device (11) on the front and rear sides of the oxidation catalyst device (11). The oxidation catalyst device (11) is connected to the engine (E). The stay (11B) provided on the upper left side is detachably attached by two front and rear support members (11A), and the stay (11B) oxidizes the air heated by the oxidation catalyst device (11). It is the drive part structure of the working vehicle which formed the opening part (11C) for ventilating to the threshing apparatus (3) provided in the left side of the catalyst apparatus (11) .

According to a second aspect of the present invention, the temperature sensor (11D) for measuring the internal temperature of the oxidation catalyst device (11) is provided at an outer peripheral portion of the oxidation catalyst device (11) on the radiator fan (20) side. 1. A driving part structure of a working vehicle according to 1 .

According to a third aspect of the present invention, the radiator fan (20) and the dust exhaust fan (30) are provided on the same axis, and one of the radiator fan (20) and the dust exhaust fan (30) is in a driving state and the other Is provided with driving state switching means (45) for switching the two in a non-driving state, and an oxidation catalyst device (11) for oxidizing unburned fuel in the exhaust gas discharged from the engine (E) is provided in the engine. (E) is provided on the upper side of the cylindrical rotary shaft (34) that supports the dust exhaust fan (30), and the rotary shaft (24) that supports the radiator fan (20) is provided. 3. The drive part structure of a working vehicle according to claim 1, wherein (24) is arranged above the center in the vertical direction of the radiator (50).

According to a fourth aspect of the present invention, the oxidation catalyst device (11) is disposed outside the outer peripheral portions of the radiator fan (20) and the dust exhaust fan (30) in the axial direction of the rotating shaft (24). Item 4. A driving part structure of a working vehicle according to Item 3 .

According to a fifth aspect of the present invention, the driving state switching means (45) is disposed outside the outer peripheral portions of the radiator fan (20) and the dust exhaust fan (30) in the axial direction of the rotating shaft (24). And the driving part switching means (45) is a driving part structure of a working vehicle according to claim 3 or 4 , wherein the driving state switching means (45) is arranged on the rear side of the machine body from the oxidation catalyst device (11).

The invention which concerns on Claim 6 has arrange | positioned the radiator hose (50A) which connects the said engine (E) and a radiator (50) above the outer peripheral part of the said radiator fan (20) and a dust exhaust fan (30). It is a motive part structure of the working vehicle of any one of Claims 3-5 .

In the invention according to claim 7 , the rear transmission shaft (110) to which the rotation of the engine (E) is transmitted is provided on the rear side of the body of the engine (E), and a first pulley (121) is provided on the rear transmission shaft (110). ) And a second pulley (131), a third pulley (23) is provided on the rotating shaft (24), a fourth pulley (33) is provided on the cylindrical rotating shaft (34), and the first pulley ( 121) and the third pulley (23), the first belt (122) is wound, the second pulley (131) and the fourth pulley (33) are wound around the second belt (132), and the first belt ( 122. The driving portion structure for a working vehicle according to any one of claims 3 to 6 , wherein 122) is disposed closer to the engine (E) than the second belt (132).

According to the first aspect of the present invention, the oxidation catalyst device (11) that oxidizes unburned fuel in the exhaust gas discharged from the engine (E) is disposed in the front-rear direction at a portion inside the fuselage at the upper part of the engine (E). Between the engine (E) and the radiator (50) that cools the cooling water circulating through the engine (E) provided on the right side of the engine (E). A radiator fan (20) for sucking outside air and an exhaust dust exhaust fan (30) that can be switched between a driving state and a stopped state are arranged, and a side panel (inside the fuselage seat (6) inside the airframe in a side view) 6A) and the oxidation catalyst device (11) are provided with a heat shield cover (95), and the heat shield cover (95) extends in the vertical direction provided on the front side of the front portion of the oxidation catalyst device (11). Front plate (95A) and oxidation contact A horizontal plate (95B) provided on the upper upper side of the device (11) and extending rearward from the upper end of the front plate (95A), and a horizontal plate (95B) provided on the rear side of the rear portion of the oxidation catalyst device (11). ) And the rear side plate (95D) extending downward from the rear end portion of the inclined plate (95C), and the heat shield cover. (95) is provided at a predetermined interval with respect to the oxidation catalyst device (11), and the lower part of the front plate (95A) and the lower part of the rear plate (95D) are connected to the front side and the rear side of the body of the oxidation catalyst device (11). The oxidation catalyst device (11) extends below the lower portion of the oxidation catalyst device (11), and the oxidation catalyst device (11) is attached to a stay (11B) provided on the upper left side of the engine (E). The stay (11B) is detachably attached by the support member (11A). Since was formed an opening for blowing the threshing device provided on the left side of the oxidation catalyst device heated air (11) (3) by the oxidation catalyst device (11) (11C), the radiator fan ( The oxidation catalyst device (11) arranged along the front-rear direction can be efficiently cooled by the outside air drawn in by 20). Moreover, since the ventilation to the cockpit (6) of the inside air heated by the oxidation catalyst device (11) is blocked by the heat shield cover (95), the temperature rise in the cockpit (6) can be suppressed. it can.

Further, in order to outside air sucked by La Jietafan (20) can be prevented from escaping in the longitudinal direction of the oxidation catalyst device (11), the oxidation catalyst device by the outside air sucked by the radiator fan (20) (11) further It can be cooled efficiently. Furthermore, the air heated by the oxidation catalyst device (11) can be efficiently blown by the threshing device (3) provided on the left side of the oxidation catalyst device (11).

According to the invention described in claim 2 , in addition to the effect of the invention described in claim 1, the temperature sensor (11D) for measuring the internal temperature of the oxidation catalyst device (11) is used as a radiator fan in the oxidation catalyst device (11). Since the temperature sensor (11D) can be cooled by the outside air drawn in by the radiator fan (20), the temperature sensor (11D) of the temperature sensor (11D) associated with an excessive temperature rise is provided. Malfunctions can be prevented.

According to the invention described in claim 3 , in addition to the effect of the invention described in claim 1 or 2 , the radiator fan (20) and the dust exhaust fan (30) are provided on the same axis, and the radiator fan (20) Drive state switching means (45) is provided for switching the dust exhaust fan (30) in a contradictory manner so that one is driven and the other is not driven, and the exhaust fan in the exhaust gas discharged from the engine (E) An oxidation catalyst device (11) that oxidizes the fuel is arranged on the upper side of the engine (E), and supports the radiator fan (20) through the cylindrical rotary shaft (34) that supports the dust fan (30). The rotating shaft (24) is provided, and the rotating shaft (24) is arranged above the center in the vertical direction of the radiator (50), so that the outside air sucked by the radiator fan (20) Placed on the top That effectively blown into the oxidation catalyst device (11), it is possible to suppress the temperature rise of the oxidation catalyst device (11).

  Further, when the radiator fan (20) is not driven, the dust exhaust fan (30) is driven, so that the inside air heated by the engine (E) and the oxidation catalyst device (11) can be quickly discharged to the outside. The overheating of E) can be suppressed.

According to the invention described in claim 4 , in addition to the effect of the invention described in claim 3 , the oxidation catalyst device (11) is connected to the radiator fan (20) and the dust exhaust fan (20) in the axial direction of the rotating shaft (24). 30), it is possible to prevent the oxidation catalyst device (11) from obstructing discharge of the inside air to the outside when the dust exhaust fan (30) is driven.

According to the invention described in claim 5 , in addition to the effect of the invention described in claim 3 or 4 , the driving state switching means (45) is connected to the radiator fan (20) and the exhaust fan in the axial direction of the rotating shaft (24). The radiator fan (20) is driven because the dust fan (30) is arranged outside the outer peripheral portion and the drive state switching means (45) is arranged behind the oxidation catalyst device (11). It is possible to prevent the driving state switching means (45) from obstructing the blowing of the sucked outside air during the state.

According to the invention of claim 6 , in addition to the effect of the invention of any one of claims 3 to 5 , the radiator hose (50A) for connecting the engine (E) and the radiator (50) Since the radiator fan (20) and the dust exhaust fan (30) are disposed above the outer peripheral portions, the radiator hose (50A) becomes an obstacle to the ventilation of the outside air sucked when the radiator fan (20) is driven. This can prevent the radiator hose (50A) from being an obstacle to exhausting the inside air to the outside when the dust exhaust fan (30) is in a driving state.

According to the invention described in claim 7 , in addition to the effect of the invention described in any one of claims 3 to 6 , the rear transmission shaft (110) to which the rotation of the engine (E) is transmitted is connected to the engine (E ), The rear transmission shaft (110) is provided with the first pulley (121) and the second pulley (131), the rotary shaft (24) is provided with the third pulley (23), and the cylindrical rotary shaft (34) is provided with a fourth pulley (33), the first belt (122) is wound around the first pulley (121) and the third pulley (23), the second pulley (131) and the fourth pulley (33). The second belt (132) is wound around the first belt (122), and the first belt (122) is disposed closer to the engine (E) than the second belt (132).・ Inspection work can be performed easily.

It is a right view of a combine. It is a top view of a combine. It is a principal part rear view of an engine room. It is a principal part left view of an engine room. It is a principal part right view of an engine room. It is a principal part right view of the periphery of a drive state switching means. It is a principal part rear view around a radiator fan and a dust exhaust fan. It is a principal part left side view of the 1st and 2nd tension roller periphery. (A) is the principal part rear view of the state which has been biased and arranged in the engine side, and (b) is the biased arrangement in the opposite side of the engine. It is a transmission diagram. It is a right view of an engine and an oxidation catalyst device. It is a top view of an engine and an oxidation catalyst device. It is a rear view of an engine and an oxidation catalyst device. It is a left view of an engine and an oxidation catalyst device. It is a principal part left view explaining a thermal insulation cover and a tail pipe. It is a principal part rear view explaining a heat shield cover and a tail pipe. (A) is a left side view, (b) is a plan view, and (c) is a rear view for explaining the oxidation catalyst device and the heat shield cover.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. For the sake of easy understanding, the explanation is given with the direction shown for the sake of convenience with the front as the front, the rear as the rear, the right hand side as the right side, and the left hand side as the left side, as viewed from the operator boarding the cockpit. However, the configuration is not limited by these.

As shown in FIGS. 1 and 2, the combine is provided with a traveling device 2 composed of a pair of left and right crawlers below the machine frame 1, and on the upper left side of the machine frame 1 is a threshing device 3 that performs threshing and sorting. are mounted on the front side of the threshing device 3, cutting device 4 is provided to harvest fields of grain stalks. The grains threshed and selected by the threshing apparatus 3 are stored in a Glen tank 5 provided on the right side of the threshing apparatus 3, and the stored grains are discharged to the outside by the discharge cylinder 7.

  On the upper right side of the fuselage frame 1, a cockpit 6 including an operation unit on which an operator gets on is provided. Below the cockpit 6, an engine room 8 on which an engine E is mounted is provided. Further, a cover 8A for maintenance / inspection of the engine room 8 is mounted on the right side of the engine room 8, and a filter body formed of a steel plate or the like is formed at the middle and lower parts of the cover 8A in the vertical direction. 8B is attached.

As shown in FIGS. 3 to 5, an engine E is provided inside the engine room 8.
As shown in FIGS. 11 to 14, an oxidation catalyst device 11 such as a DOC that oxidizes unburned fuel in exhaust gas discharged from the engine E is provided on the upper left side of the engine E. Thereby, the inside air heated by the oxidation catalyst device 11 can be efficiently blown toward the threshing device 3, and drying of the threshing grains in the threshing device 3 can be promoted.

  The oxidation catalyst device 11 is detachably attached to a stay 11B provided on the upper left side of the engine E by two front and rear support members 11A. Further, the left side portion of the front support member 11A is connected to a stay 11E extending in the left-right direction from the upper right side of the engine E. Thereby, the rigidity of the support member 11A and the stay 11B is increased, and the deformation of the support member 11A and the stay 11B due to vibration of the engine E can be prevented, and the oxidation catalyst device 11 can be reliably supported.

  In order to efficiently oxidize unburned fuel in the exhaust gas while maintaining the internal temperature of the oxidation catalyst device 11 within a predetermined use temperature, a temperature sensor 11D that measures the internal temperature of the oxidation catalyst device 11 includes: It is provided on the radiator fan 20 side of the outer peripheral portion of the oxidation catalyst device 11 and is disposed on the inner side partitioned by a heat shield cover 95 described later. Thereby, the outside air sucked by the radiator fan 20 is blown to the temperature sensor 11D, and erroneous measurement accompanying a temperature rise can be prevented.

  On the right side of the engine E, there is provided a radiator 50 that cools cooling water supplied to the engine E at a predetermined interval. A rubber radiator hose 50A that connects the engine E and the radiator 50 is provided in the engine room 8. It is provided at the same height as the oxidation catalyst device 11. Thereby, it is not necessary to provide the radiator hose 50 </ b> A in the space between the engine E and the radiator 50, and a large space can be secured between the engine E and the radiator 50.

  Between the engine E and the radiator 50, a radiator fan 20 that sucks outside air from the outside of the engine room 8 to the inside, and a left side of the radiator fan 20 exhausts the inside air from the inside of the engine room 8 to the outside. A dust exhaust fan 30 is provided for removing dust adhering to the filter body 8B.

  When the radiator fan 20 rotates, the cooling efficiency of the radiator 50 can be increased by sucking outside air into the engine room 8 through the filter body 8B of the cover 8A and blowing it to the surface of the radiator 50 or the like. . Further, when the dust exhaust fan 30 rotates, the inside air is exhausted to the outside through the filter body 8B of the cover 8A, and the inside air is blown to the filter body 8B, thereby removing dust attached to the filter body 8B. Thus, the efficiency of the outside air suction by the radiator fan 20 can be kept constant. For convenience, the rotation of the radiator fan 20 and the dust exhaust fan 30 is referred to as a drive state, and the stop of the rotation of the radiator fan 20 and the dust exhaust fan 30 is referred to as a stop state.

  The radiator fan 20 is formed of a central portion attached to the rotary shaft 24 and blades extending in the radial direction from the central portion. In this embodiment, eight blades are provided at a predetermined interval in the circumferential direction of the central portion in order to increase the efficiency of sucking outside air by the radiator fan 20. It can be changed to the number of sheets.

  Similarly, the dust exhaust fan 30 is formed of a central portion attached to the cylindrical rotary shaft 34 and blades extending from the central portion in the radial direction. In order to prevent a reduction in outside air suction efficiency by the radiator fan 20, the outer diameter of the blades of the dust exhaust fan 30 is formed smaller than the outer diameter of the blades of the radiator fan 20. Further, in order to simplify the transmission configuration of the radiator fan 20 and the dust exhaust fan 30 and to effectively use the space in the engine room 8, the blade angle of the blade of the dust fan 30 is the blade blade of the radiator fan 20. It is erected at the center with a blade angle opposite to the angle. Thereby, even if the rotation direction transmitted to the cylindrical rotating shaft 34 to which the dust exhaust fan 30 is attached and the rotation direction transmitted to the rotation shaft 24 to which the radiator fan 20 is attached are the same rotation direction, the radiator. The fan 20 can suck outside air and blow it to the inside of the engine room 8, and the dust exhaust fan 30 can exhaust the inside air to the outside of the engine room 8. In addition, although eight blades of the dust exhaust fan 30 are provided at predetermined intervals in the circumferential direction of the central portion, any number can be set within a range in which a desired air blowing capacity can be obtained.

  Between the radiator 50 and the cover 8A, an oil cooler 51 that cools oil supplied to a hydraulic cylinder that moves up and down the reaping device 4 and an intercooler 52 that cools a combustion gas mixture supplied to the engine E are provided. It has been.

  The front part of the oil cooler 51 is attached to the front part of the plate 1F via the butterfly 53, and the rubber hose 54 connecting the oil cooler 51 and the hydraulic cylinder is in an opening 55 formed in the plate 1G. It is inserted. Thereby, at the time of maintenance / inspection work of the radiator 50, the oil cooler 51 can be rotated by the butterfly 53, and the right side of the radiator 50 can be opened to easily perform maintenance / inspection of the radiator 50.

  The upper and lower portions of the intercooler 52 are respectively attached to the plate 1F via support members 56, and a metal pipe 57A located on the right side of the plate 1F connecting the intercooler 52 and the engine E is formed on the plate 1G. It is fixed to the outer periphery of the opening 58.

  Further, the metal pipe 57 </ b> B located on the left side of the plate 1 </ b> F connecting the intercooler 52 and the engine E is provided at the same height as the oxidation catalyst device 11 in the engine room 8. Thereby, it is not necessary to provide the pipe 57B in the space between the engine E and the radiator 50, and a large space can be secured between the engine E and the radiator 50.

  The plate 1F is attached to the right front frame 1A and the right rear frame 1B of the frames 1A to 1D that support the cockpit 6 via support members 59A. Similarly, the plate 1G is attached to the right front frame 1A and the right rear frame 1B via support members 59B.

As shown in FIG. 10, the rotational power of the engine E is transmitted to the crankshaft 60 extending from the engine E toward the right side, and the rotational power transmitted to the crankshaft 60 is a pulley 61, a belt 62, and a pulley 63. Is transmitted to the rear transmission shaft 110 that supports the pulley 63.
A water pump shaft 60A positioned above the crankshaft 60 of the engine E instead of the crankshaft 60, an alternator shaft 60D positioned on the upper left side of the crankshaft 60, and a fly extending from the engine E toward the left side. The rotational power transmitted to the wheel shaft 60B can be transmitted to the rear transmission shaft 110 via a pulley, a belt, or the like. A belt 60E is wound around a pulley that is supported by the crankshaft 60, the water pump shaft 60A, and the alternator shaft 60D, and the rotational power of the crankshaft 60 is transmitted through the belt 60E to the water pump. It is transmitted to shaft 60A and alternator shaft 60D.

  The rotational power transmitted to the rear transmission shaft 110 is a rotation that supports the pulley 23 via a pulley 121, a belt (“first belt” in claims) 122, and a pulley (“third pulley” in claims) 23. The radiator fan 20 that is transmitted to the shaft 24 and supported by the right end of the rotating shaft 24 is rotated.

  Similarly, the rotational power transmitted to the rear transmission shaft 110 passes through the pulley 131, the belt (“second belt” in claim) 132, and the pulley (“fourth pulley” in claim) 33. The dust exhaust fan 30, which is transmitted to the supporting cylindrical rotating shaft 34 and supported at the right end of the cylindrical rotating shaft 34, is rotated. The rotating shaft 24 is fitted inside the support portion 25 via a bearing, and the cylindrical rotating shaft 34 is fitted outside the support portion 25 via a bearing.

  The tension roller 26 is provided on the pulley 122 (the “first pulley” in the claims) and the belt 122 wound around the pulley 23, and the tension roller 26 changes the tension of the belt 122 to transmit the rotational power. Connect and disconnect.

  Similarly, the pulley 132 (the “second pulley” in the claims) 131 and the belt 132 wound around the pulley 33 are provided with a tension roller 36, and the tension roller 36 changes the tension of the belt 132 to rotate the power. Connect and shut off the transmission.

  The belt 122 that transmits rotational power to the radiator fan 20 is provided closer to the engine E than the belt 132 that transmits rotational power to the dust exhaust fan 30. Thus, maintenance / inspection work of the belt 122 that deteriorates earlier than the belt 132 due to a long driving time can be easily performed.

  Further, the rotational power transmitted to the rear transmission shaft 110 is transmitted to a shaft 71 extending rearward from the transmission gear box 70 through a transmission gear box 70 having a pair of opposed bevel gears.

  The rotational power transmitted to the shaft 71 is transmitted to the discharge spiral shaft 75 that supports the pulley 74 via the pulley 72, the belt 73, and the pulley 74. The discharge spiral shaft 75 is provided in the lower part of the Glen tank 5 so as to extend in the front-rear direction, and transfers the grains stored in the Glen tank 5 to the discharge cylinder 7 and is a spiral built in the discharge cylinder 7. Drive the shaft. The belt 73 wound around the pulley 72 and the belt 73 is provided with a tension roller (not shown), and the tension of the belt 73 is changed by the tension roller to connect and disconnect the transmission of the rotational power.

  In the present specification, the intermediate transmission unit 150 refers to a part composed of the pulley 61, the belt 62, the pulley 63, the rear transmission shaft 110, the pulley 121, the pulley 131, the transmission gear box 70, the shaft 71, and the pulley 72. The fan transmission unit 160 includes a belt 122, a tension roller 26, a pulley 23, a rotating shaft 24, a radiator fan 20, a belt 132, a tension roller 36, a pulley 33, a cylindrical rotating shaft 34, and a dust exhaust fan 30. The discharge transmission part 170 is a part composed of the belt 73, the pulley 74, and the discharge spiral shaft 75.

  As shown in FIGS. 3 to 5, the intermediate transmission unit 150 is provided in the rear part of the engine room 8. The pulley 63, the rear transmission shaft 110, the pulley 121, the pulley 131, the transmission gear box 70, the shaft 71, and the pulley 72 of the intermediate transmission unit 150 are located behind the right rear frame 1B and the left rear frame 1D in a side view. In addition, it is provided in the space S on the front side of the front wall 5A of the Glen tank 5.

  The belt 122, the tension roller 26, the pulley 23, the belt 132, the tension roller 36, and the pulley 33 of the fan transmission unit 160 are disposed on the right side of the engine E and on the left side of the radiator fan 20. It is provided in the space B on the left side of the screen. That is, the fan transmission unit 160 is provided so as to enter the space B from the intermediate transmission unit 150 provided on the rear side of the engine room 8.

Thereby, the parts provided in the space | interval part B can be decreased, the engine E and the radiator fan 20 can be provided close, and the engine E can be cooled efficiently with the external air suck | inhaled by the radiator fan 20.
Further, the crankshaft 60 of the engine E and the pulley 63 of the intermediate transmission unit 150 can be provided close to each other, and the transmission loss of the rotational power caused by the belt 62 can be reduced.
Further, maintenance and inspection work of the intermediate transmission unit 150 can be easily performed, and the intermediate transmission unit 150 can be manufactured to be small and light.

Next, the driving state switching means 45 that switches the driving states of the radiator fan 20 and the dust exhaust fan 30 will be described.
As shown in FIG. 6 and the like, the drive state switching means 45 is provided on the rear side of the left rear frame 1D located on the left rear side of the engine room 8. More specifically, the drive state switching means 45 supports a reservoir tank 92 that temporarily stores a part of the cooling water circulating through the engine E and the radiator 50 extending from the left rear frame 1D toward the rear side. The bracket 91 is detachably connected to the upper portion of the stay 90 by a fastening means such as a bolt. Thereby, the maintenance / inspection work of the drive state switching unit 45 can be easily performed, and the drive state switching unit 45 can be prevented from obstructing the ventilation of the radiator fan 20 and the dust exhaust fan 30.

  The bracket 91 is coupled to the stay 90 by fastening together using a fastening means for supporting the reservoir tank 92 to the stay 90, and the drive state switching means 45 is attached to the left side surface of the bracket 91 on the side opposite to the reservoir tank 92. Installed. Thereby, the number of parts can be reduced, and it is possible to prevent the drive state switching means 45 from being damaged by the cooling water splashed from the reservoir tank 92 when the reservoir tank 92 is damaged.

  A substantially rectangular plate 45E is supported on an output shaft 45D of a drive state switching means 45 having a motor and a speed reducer. As shown in FIG. 6, two pins 45 </ b> C are erected on the plate 45 </ b> E at a predetermined distance from the output shaft 45 </ b> D in the front-rear direction. The rear ends of the inner cables 80B provided in the outer cable 80A of the connecting means 80 are connected to the two pins 45C. The output shaft 45D extends from the drive state switching means 45 toward the right side, and the plate 45E, the inner cable 80B, and the like are provided above the reservoir tank 92. Thereby, the space above the reservoir tank 92 can be effectively utilized.

Next, the connection of the tension rollers 26 and 36 for connecting and shutting off the transmission of the rotational power by changing the tension of the connecting means 80 and the belts 122 and 132 will be described.
As shown in FIGS. 7 and 8, the front end portion of the outer cable 80 </ b> A of the one side connecting means 80 is supported by a stay 81 provided on the rear upper portion of a rear arm portion 142 of a bracket 140 described later. In addition, the rotary shaft 24 is provided outside the outer periphery of the radiator fan 24 and the dust exhaust fan 30 when viewed in the axial direction. Thereby, the connection means 80 and the stay 81 do not become an obstacle to the ventilation of the radiator fan 20 and the dust exhaust fan 30 and can improve the ventilation efficiency of the radiator fan 20 and the dust exhaust fan 30.

The front end portion of the inner cable 80B of the connecting means 80 is connected to a belt stopper 26C of a tension roller 26 that connects and shuts off transmission of rotational power by changing the tension of the belt 122 wound around the pulley 23 and the pulley 121. It is connected via an elastic member 82. Thereby, the frequency | count that an excessive load is added to the drive state switching means 45 can be decreased, and the durability of the drive state switching means 45 can be improved.
The belt stopper 26C is formed in a substantially square shape when viewed in the axial direction of the rotary shaft 24, and includes a belt contact portion on the front end side that contacts the belt 122 and a connection portion that is fixed to the tension arm 26B. Yes. In addition, a front end portion of the inner cable 80B is connected to an intermediate portion of the connection portion via an elastic member 82.

  The tension roller 26 includes a tension arm 26B that is rotatably attached to a support shaft 86 provided in the left and right direction at a rear lower portion of a rear arm portion 142 of a bracket 140, which will be described later, and a tension arm 26B that is rotatable at a tip end portion of the tension arm 26B. The roller 26A is supported, and a belt stopper 26C fixed to the base of the tension arm 26B is provided. The support shaft 86 is provided outside the outer periphery of the radiator fan 24 and the dust exhaust fan 30. Thereby, the support shaft 86 does not become an obstacle to the ventilation of the radiator fan 20 and the dust exhaust fan 30, and the ventilation efficiency of the radiator fan 20 and the dust exhaust fan 30 can be improved.

  The tension arm 26 </ b> B of the tension roller 26 and the lower portion of the stay 81 are connected by a spring 85 that urges the tension roller 26 toward the belt 122.

  Similarly, as shown in FIGS. 7 and 8, the front end portion of the outer cable 80A of the connecting means 80 on the other side is supported by a stay 81 provided on the rear upper portion of a rear arm portion 142 of a bracket 140 described later, The stay 81 is provided outside the outer periphery of the radiator fan 24 and the dust exhaust fan 30 when viewed in the axial direction of the rotating shaft 24.

  The front end portion of the inner cable 80B of the linking means 80 changes the tension of the belt 33 wound around the pulley 33 and the pulley 131, and connects or disconnects the transmission of the rotational power to the belt stopper 36C of the tension roller 36, such as a spring. It is connected via an elastic member 82. The stay 81 is provided outside the outer periphery of the radiator fan 24 in the axial direction of the rotating shaft 24. The belt stopper 36C is formed in a substantially square shape when viewed in the axial direction of the rotary shaft 24, and includes a belt contact portion on the front end side that contacts the belt 132 and a connection portion fixed to the tension arm 36B. Yes. In addition, a front end portion of the inner cable 80B is connected to an intermediate portion of the connection portion via an elastic member 82.

  The tension roller 36 includes a tension arm 36B that is rotatably attached to a support shaft 86 that is provided in a left-right direction at a rear lower portion of a rear arm portion 142 of a bracket 140, which will be described later, and a tension arm 36B that is rotatable at a tip end portion of the tension arm 36B. The roller 36A is supported, and a belt stopper 36C fixed to the base of the tension arm 26B is provided.

  The tension arm 36 </ b> B of the tension roller 36 and the lower portion of the stay 81 are connected by a spring 85 that urges the tension roller 36 toward the belt 132.

FIG. 8 illustrates a state of the tension rollers 26 and 36 in which the radiator fan 20 is in a driving state and the dust exhaust fan 30 is in a stopped state.
As shown in FIG. 8, when the plate 45E is rotated by the driving state switching means 45 and the inner cable 80B of the connecting means 80 is pulled in and the belt stopper 26C of the tension roller 26 rotates clockwise, the tension roller 26 The roller 26 </ b> A presses the belt 122, and the belt stopper 26 </ b> C of the tension roller 26 is separated from the belt 122 to be in a non-braking state, and transmits the rotational power of the engine E transmitted to the pulley 121 to the pulley 23.

  On the other hand, when the plate 45E is rotated by the drive state switching means 45 to push the inner cable 80B of the connecting means 80 and the belt stopper 36C of the tension roller 36 rotates counterclockwise, the roller 36A of the tension roller 36 is The belt stopper 36 </ b> C of the tension roller 36 is separated from the belt 132 and presses the belt 132 to be in a braking state, thereby quickly interrupting transmission of the rotational power of the engine E transmitted to the pulley 131 to the pulley 23. As a result, in FIG. 8, the rotation of the dust exhaust fan 30 can be quickly stopped, and the air blown by the radiator fan 20 can be prevented from being hindered.

  The driving state switching means 45 is automatically driven by a control device (not shown) in accordance with the state of the cooling water of the radiator 50 and the like. A switching lever can also be provided in the cockpit 6 or in the space S of the engine room 8 and the front wall 5A of the Glen tank 5 so that the switching can be manually operated.

Next, the rotating shaft 24 to which the radiator fan 20 is attached and the bracket 140 that supports the cylindrical rotating shaft 34 to which the dust exhaust fan is attached will be described.
As shown in FIGS. 7 and 8, the bracket 140 has a rotating shaft 24 fitted in the center portion of the bracket 140 and a support portion 25 that fits the cylindrical rotating shaft 34 is fixed thereto. As shown in FIG. The support part 25 in the bracket 140 is provided at a position biased upward from the center part in the vertical direction of the radiator 50. Thereby, the outside air drawn in by the radiator fan 20 is blown to the upper side of the engine E, and the engine E and the oxidation catalyst device 11 provided on the upper side of the engine E can be efficiently cooled.

  The bracket 140 is formed in a three-pronged shape having three arm portions extending radially in the radial direction around the support portion 25 as viewed in the axial direction of the rotating shaft 24. That is, the bracket 140 extends from the support portion 25 to a substantially upper front side, a rear arm portion 142 extending from the support portion 25 to a substantially rear side, and extends from the support portion 25 to a substantially lower side. The lower arm part 143 to be used is provided.

The front arm portion 141 is inclined to the right side (outside the fuselage) as it extends to the front end side, and the front end portion is connected to the right front frame 1A. The rear arm part 142 extends in a direction perpendicular to the rotation shaft 24, and the tip part is connected to the right rear frame 1B. The lower arm portion 143 is inclined to the right side (outside the fuselage) as it extends to the distal end side, and the distal end portion is connected to a bracket 1E fixed to the upper side of the fuselage frame 1.
Thereby, the ventilation efficiency of the radiator fan 20 and the dust exhaust fan 30 can be improved without obstructing the ventilation of the radiator fan 20 and the dust exhaust fan 30. In addition, the rigidity of the bracket 140 is increased, the rotating shaft 24 and the cylindrical rotating shaft 34 can be stably supported, and the radiator fan 20 and the dust exhaust fan 30 can be stably rotated. Furthermore, since the front end portions of the front arm portion 141 and the lower arm portion 143 are inclined toward the right side (outside the fuselage), the spacing portion B can be widely formed on the front side and the lower side of the bracket 140, so that the radiator fan 20, Maintenance / inspection work of the dust exhaust fan 30 and the engine E can be easily performed.

Next, means for changing the mounting position on the rear transmission shaft 110 of the pulley 63 will be described.
As shown in FIG. 9, the pulley 63 to which the rotational power of the engine E is transmitted is fixed to the rear transmission shaft 110 by a key 64. A keyway 111 is formed on the outer peripheral surface of the rear transmission shaft 110. Since the key 64 inserted into the key groove 111 is interposed between the pulley 63 and the rear transmission shaft 110, the pulley 63 is fixed to the rear transmission shaft 110 in a state where relative rotation is impossible. The key grooves 111 are formed at two locations on the outer peripheral surface of the rear transmission shaft 110 with an interval in the axial direction of the rear transmission shaft 110.
Further, collars 112 and 113 are fitted on the outer peripheral surface of the rear transmission shaft 110. The collars 112 and 113 are members that restrict the pulley 63 from moving in the axial direction of the rear transmission shaft 110. Note that the length of the collar 113 in FIG. 9 in the left-right direction is larger than the length of the collar 112 in the left-right direction.

Thereby, as shown to Fig.9 (a), (b), the attachment position in the axial center direction of the rear part transmission shaft 110 of the pulley 63 can be changed easily.
9A shows a state in which the pulley 63 is attached to the left side in the axial direction of the rear transmission shaft 110, and FIG. 9B shows the right side in the axial direction of the rear transmission shaft 110. The state attached to is shown. When the attachment position of the pulley 63 is changed, the insertion position of the key 64 is changed, and the collars 112 and 113 arranged on the left and right sides of the pulley 63 are exchanged on the left and right sides to be fitted on the rear transmission shaft 110. Further, the position of the tension roller 115A, 115B that presses the pulley 61 and the belt 62 wound around the pulley 63 is changed in accordance with the change of the position of the pulley 63.

  The tension rollers 115A and 115B include a roller 118 and a tension arm 117 that supports the roller 118. In the tension rollers 115A and 115B, a pin 117A provided at the base of the tension arm 117 is rotatably supported on a support portion 116 attached to the body frame 1 by fastening means such as a bolt. A spring (not shown) is connected to the tension arm 117 in order to urge the tension rollers 115A and 115B to the belt 62.

  As shown in FIG. 9A, when the pulley 63 is attached to the left side in the axial direction of the rear transmission shaft 110, the left tension roller 115A provided with the tension arm 117 on the right side of the roller 118 is used. As shown in FIG. 9B, when the pulley 63 is attached to the right side in the axial direction of the rear transmission shaft 110, the right tension roller is provided with a tension arm 117 on the left side of the roller 118. It is preferred to use 115B.

  The tension arm 117 of the left tension roller 115A extends in a direction away from the rear transmission shaft 110 while bending in the axial direction of the rear transmission shaft 110. On the other hand, the tension arm 117 of the right tension roller 115B does not bend in the axial direction of the rear transmission shaft 110 but extends away from the rear transmission shaft 110, and a pin 117A provided at the base of the tension arm 117 The left tension roller 115A is longer in the left-right direction than the pin 117A. The right tension roller 115B is preferably provided on the right side of the left tension roller 115A.

Next, a method for preventing the inside air around the oxidation catalyst device 11 heated by the oxidation catalyst device 11 provided on the upper side of the engine E from flowing into the cockpit 6 will be described.
As shown in FIGS. 15 and 16, a heat insulating cover 95 is provided between the oxidation catalyst device 11 and the side panel 6 </ b> A where the main transmission lever of the cockpit 6 is provided. By providing the heat shield cover 95, dust such as waste can be prevented from accumulating on the oxidation catalyst device 11, and ignition of dust such as waste can be prevented, and electrical equipment provided around the oxidation catalyst device 11 can be prevented. The temperature rise of components can be prevented.

  As shown in FIG. 17, the heat shield cover 95 includes a front plate 95A extending in the vertical direction, a horizontal plate 95B extending in the front-rear direction from the upper end portion of the front plate 95A, and a rear end portion of the horizontal plate 95B. The inclined plate 95 </ b> C extends while being inclined downward and the rear plate 95 </ b> D extends vertically from the rear end portion of the inclined plate 95 </ b> C. The front plate 95A, the horizontal plate 95B, the inclined plate 95C, and the rear plate 95D are integrally formed by bending a thin steel plate.

  The front plate 95A is a weld nut provided on the left front frame 1C, and the horizontal plate 95B is a weld nut provided on a left frame 1H extending in the front-rear direction connected to the left front frame 1C and the left rear frame 1D. The rear plate 95D is detachably attached to the nut by a bolt on a weld nut provided on the left rear frame 1D. Thereby, at the time of maintenance / inspection work of the oxidation catalyst device 11, the heat shield cover 95 can be removed from the left front frame 1 </ b> C and the like, and maintenance / inspection work of the oxidation catalyst device 11 can be easily performed.

The heat shield cover 95 is provided so as to cover the front portion, the upper portion, and the rear portion of the oxidation catalyst device 11 with a predetermined distance from the oxidation catalyst device 11.
As shown in FIG. 17, the front plate 95A of the heat shield cover 95 is provided along the left front frame 1C provided at a predetermined interval from the front portion of the oxidation catalyst device 11, and the lower portion of the front plate 95A. Is extended below the lower part of the front part of the oxidation catalyst device 11. Further, the horizontal plate 95 </ b> B of the heat shield cover 95 is provided along the left frame 1 </ b> H provided at a predetermined interval from the upper part of the oxidation catalyst device 11. Further, the rear plate 95D of the heat insulating cover 95 is provided along the left rear frame 1D provided at a predetermined interval from the rear portion of the oxidation catalyst device 11, and the lower portion of the rear plate 95D is provided at the lower portion of the oxidation catalyst device. 11 extends below the lower part of the rear part. Thus, the outside air sucked by the radiator fan 20 can be efficiently blown from the right side to the left side to cool the oxidation catalyst device 11 and the inside air heated by the oxidation catalyst device 11 is provided on the left side of the oxidation catalyst device 11. The threshing grain in the threshing device 3 can be dried by efficiently blowing air to the threshing device 3.
In order to efficiently blow the inside air heated by the oxidation catalyst device 11 through the threshing device 3 provided on the left side of the oxidation catalyst device 11, an opening 11C is provided in the stay 11B that supports the oxidation catalyst device 11. Is preferred.

  The upper end of the right rear frame 1B and the upper end of the left rear frame 1D are connected by a rear frame 1K extending in the left-right direction, and the cockpit 6 and the engine E are located below the left frame 1H. An engine room cover 96 is provided so as to be detachable. The engine room cover 96 is provided in a portion surrounded by the left and right front frames 1A and 1C and the left and right rear frames 1B and 1D, and is mainly a cockpit 6 around the engine E heated by the engine E. The air flow to the cockpit seat 6 around the oxidation catalyst device 11 heated by the oxidation catalyst device 11 can be blocked in cooperation with the heat shield cover.

Next, the tail pipe 15 that guides the exhaust gas discharged from the oxidation catalyst device 11 to the outside will be described.
As shown in FIGS. 15 and 16, the tail pipe 15 includes a first pipe 16 whose front is connected to the exhaust port 12 of the oxidation catalyst device 11 and a second pipe whose front is connected to the rear of the first pipe 16. A pipe 17 and a third pipe 18 having a front portion connected to the rear portion of the second pipe 17 are formed.

  The first pipe 16 extends from the front part connected to the exhaust port 12 of the oxidation catalyst device 11 to the lower rear side when viewed from the left side, and is connected to the exhaust port 12 of the oxidation catalyst device 11 when viewed from the rear side. It is curved and extends from the front part toward the lower left side. Thereby, interference can also be avoided with the threshing input pulley 3B provided on the rear upper side of the flywheel shaft 60B that transmits the rotational power of the engine E to the carp 3A or the like of the threshing device 3.

The second pipe 17 extends from the front part connected to the rear part of the first pipe 16 in the left side view toward the lower rear side, and from the front part connected to the rear part of the first pipe 16 in the rear view. It extends toward the lower right side. In addition, the rear-end part of the 2nd pipe 17 is located in front of 3 C of front walls of the threshing apparatus 3 in side view.
In addition, the inner diameter of the front portion of the second pipe 17 is formed larger than the outer diameter of the rear portion of the first pipe 16, and the front portion of the second pipe 17 is larger than the outer peripheral portion of the rear portion of the first pipe 16. And are fitted outside at a predetermined interval. As a result, the exhaust gas discharged from the first pipe 16 to the second pipe 17 causes a negative pressure in the front portion of the second pipe 17, and the gap between the rear portion of the first pipe 16 and the front portion of the second pipe 17. The outside air can be sucked into the front portion of the second pipe 17 and the temperature of the exhaust gas discharged to the second pipe 17 can be lowered.

The third pipe 18 extends from the front part connected to the rear part of the second pipe 16 located on the front side of the front wall 3C of the threshing device 3 in the left side view, and extends in the threshing device 3. After reaching the front bent part facing the lower part of the cereal cylinder 13 for cerealing the grain of the grain to the grain tank 5, and extending again from the front bent part toward the lower rear side and facing the body frame 1 It reaches the side bent portion, extends again from the rear bent portion toward the lower rear side, and reaches the rear portion. In addition, the rear downward inclination angle extending from the front bent portion of the third pipe 18 toward the rear bent portion is a rear lower inclination angle extending from the front portion of the third pipe 18 toward the front bent portion, and It is set to be larger than a rearward downward inclination angle extending from the rear bent portion of the third pipe 18 toward the rear portion. Thereby, accumulation of dust, such as waste, on the third pipe 18 can be prevented, and the part of the third pipe 18 facing the threshing device 3 can be set long, so that the threshing device 3 It is also possible to promote the drying of the kernel.
The third pipe 18 extends linearly from the front part connected to the rear part of the second pipe 16 toward the lower rear side. Note that the outer periphery of the third pipe 18 is covered with a cover having a substantially octagonal cross section so that the third pipe 18 is in direct contact with the waste on the field and the fire of the waste is prevented.

  As shown in FIG. 16, the engine E is biased to the threshing device 3 and the tail pipe 15 is provided in the space W formed between the threshing device 3 and the Glen tank 5. The engine E and the tail pipe 15 can be efficiently cooled by the traveling wind sucked in. Further, by providing the joint position of the rear part of the second pipe 17 of the tail pipe 15 and the front part of the third pipe 18 in the space W, the replacement work of the third pipe 18 damaged due to a collision with a field or the like can be easily performed. You can also. Furthermore, in order to cool the hose 54 such as the oil cooler 51, it is preferable to provide the hose 54 such as the oil cooler 51 in the space W formed between the threshing device 3 and the glen tank 5.

3 Threshing device 6 Cockpit 6A Side panel 11 Oxidation catalyst device
11A Support member
11B stay
11C Opening 11D Temperature sensor 20 Radiator fan 23 Pulley (third pulley)
24 Rotating shaft 30 Dust exhaust fan 33 Pulley (fourth pulley)
34 Cylindrical rotating shaft 45 Driving state switching means 50 Radiator 50A Radiator hose 95 Heat shield cover 95A Front plate
95B horizontal plate
95C Inclined plate 95D Rear plate 110 Rear transmission shaft 121 Pulley (first pulley)
122 belt (first belt)
131 pulley (second pulley)
132 Belt (second belt)
E engine

Claims (7)

The engine (E) is arranged below the cockpit (6) and the cockpit (6),
An oxidation catalyst device (11) that oxidizes unburned fuel in the exhaust gas discharged from the engine (E) is disposed along the front-rear direction at a site inside the fuselage at the top of the engine (E).
Between the engine (E) and a radiator (50) that cools the cooling water circulating through the engine (E) provided on the right side of the engine (E), it can be switched between a driving state and a stopped state for intake of outside air. A radiator fan (20) and a dust exhaust fan (30) for exhaust that can be switched between a driving state and a stopped state are arranged;
A heat shield cover (95) is provided between the side panel (6A) disposed inside the airframe in the cockpit (6) and the oxidation catalyst device (11) in a side view ,
The heat shield cover (95) is arranged on the front side plate (95A) provided in the front side of the front portion of the oxidation catalyst device (11) and on the upper side of the upper portion of the oxidation catalyst device (11). A horizontal plate (95B) provided rearward from the upper end of the front plate (95A), and a rear end of the horizontal plate (95B) provided on the rear side of the oxidation catalyst device (11). An inclined plate (95C) extending in a downwardly inclined manner and a rear side plate (95D) extending downward from the rear end of the inclined plate (95C),
The heat shield cover (95) is provided at a predetermined interval with respect to the oxidation catalyst device (11),
The lower part of the front side plate (95A) and the lower side of the rear side plate (95D) are respectively extended below the lower part of the oxidation catalyst device (11) on the front side and the rear side of the oxidation catalyst device (11). Let
The oxidation catalyst device (11) is detachably attached to a stay (11B) provided on the upper left side of the engine (E) by two front and rear support members (11A).
The stay (11B) is formed with an opening (11C) for blowing air heated by the oxidation catalyst device (11) to a threshing device (3) provided on the left side of the oxidation catalyst device (11). Structure of the working part of the working vehicle. The driving unit of a working vehicle according to claim 1, wherein provided on the outer circumferential region of the fan (20) side temperature sensor (11D) for measuring the internal temperature, the in the oxidation catalyst device (11) of the oxidation catalyst device (11) Construction. The radiator fan (20) and the dust exhaust fan (30) are provided on the same axis,
Drive state switching means (45) for switching the radiator fan (20) and the dust exhaust fan (30) in a contradictory manner so that one is driven and the other is not driven;
An oxidation catalyst device (11) for oxidizing unburned fuel in the exhaust gas discharged from the engine (E) is disposed on the upper side of the engine (E),
A rotating shaft (24) for supporting the radiator fan (20) is provided through the cylindrical rotating shaft (34) for supporting the dust exhaust fan (30).
The driving | running | working part structure of the working vehicle of Claim 1 or 2 which has arrange | positioned the said rotating shaft (24) above the center of the up-down direction of a radiator (50). The motive power of the working vehicle according to claim 3 , wherein the oxidation catalyst device (11) is disposed outside the outer peripheral portions of the radiator fan (20) and the dust exhaust fan (30) in the axial direction of the rotating shaft (24). Part structure. The drive state switching means (45) is disposed outside the outer periphery of the radiator fan (20) and the dust exhaust fan (30) when viewed in the axial direction of the rotating shaft (24), and the drive state switching means. The working part structure of the working vehicle according to claim 3 or 4 , wherein (45) is arranged on the rear side of the machine body relative to the oxidation catalyst device (11). The radiator hose (50A) for connecting said engine (E) to the radiator (50), any one of claims 3 to 5 than the outer peripheral portion is disposed on the upper side of the radiator fan (20) and dust-exhaust fan (30) 2. A driving part structure of a working vehicle according to item 1. A rear transmission shaft (110) through which the rotation of the engine (E) is transmitted is provided on the rear side of the engine (E),
A first pulley (121) and a second pulley (131) are provided on the rear transmission shaft (110), a third pulley (23) is provided on the rotating shaft (24), and a first pulley is mounted on the cylindrical rotating shaft (34). 4 pulleys (33) are provided,
The first belt (122) is wound around the first pulley (121) and the third pulley (23), the second belt (132) is wound around the second pulley (131) and the fourth pulley (33), The working part structure for a working vehicle according to any one of claims 3 to 6 , wherein the first belt (122) is disposed closer to the engine (E) than the second belt (132).

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