JP2019110776A - Combine - Google Patents

Abstract

To provide a combine capable of reducing a weight on a front part of a grain tank, and easily discharging used urea water to an external part from an urea water tank in an exhaust emission control device.SOLUTION: A mud guard cover (55) extending in a cross direction is provided on an upper side of a crawler (2A) of a travel device (2), an exhaust emission control device (20) for purifying exhaust gas of an engine (E) is provided between a thresher (4) and a grain tank (7). An urea water tank (28) of the exhaust emission control device (20) is arranged in a lower space of a right bottom wall (7G) of the grain tank (7), a water supply port (28A) of the urea water tank (28) is arranged in the vicinity of a rear wall (7D) of the grain tank (7) in a machine body cross direction, and a scupper (28B) of the urea water tank (28) is at an upper side on outside of the mud guard cover (55).SELECTED DRAWING: Figure 9

Description

  The present invention relates to a combine equipped with an exhaust gas purification device.

  In the conventional combine, when the SCR catalyst is mounted as an exhaust purification device, the urea aqueous solution tank storing urea aqueous solution is supported at the front of the right bottom wall of the grain tank storing grain and the water supply port of the urea tank It is known that the technology has been made to face the front wall of the gren tank. (Patent Document 1)

JP, 2016-42850, A

  However, in the technique described in Patent Document 1, the weight of the front of the gren tank becomes heavy, and the gren tank can be easily returned from the open position (maintenance position) to the storage position (storage operation position) on the machine frame. In addition, there is a problem that the used aqueous urea solution can not be easily taken out from the aqueous urea solution tank of the exhaust gas purification device.

  Therefore, an object of the present invention is to provide a combine capable of reducing the weight of the front of the glen tank and easily discharging the used urea water to the outside from the urea water tank of the exhaust purification device. .

The present invention which solved the above-mentioned subject is as follows.
That is, according to the first aspect of the present invention, the traveling device (2) is provided under the body frame (1), and the harvesting device (3) for harvesting the grain is provided on the front side of the body frame (1) A threshing device (4) for threshing grain is provided on the rear left side of the reaper (3), and a control unit (5) on which a rider gets on the rear right side of the reaper (3) is provided. ) In the lower part of the engine room (6) containing the engine (E) and in the rear side of the control part (5) a combine tank provided with a grain tank (7) for storing threshed grains,
A mudguard cover (55) extending in the front-rear direction is provided above the crawler (2A) of the traveling device (2), and the engine (E) is disposed between the threshing device (4) and the gren tank (7). An exhaust gas purification device (20) for purifying the exhaust gas, the exhaust gas purification device (20) comprising: a DPF (21) for removing particulate matter in the exhaust gas discharged from the engine (E); It has SCR catalyst (22) which reduces and purifies the nitrogen oxide substance in the exhaust gas after DPF (21) passage with ammonia generated from urea water, and the outlet of said DPF (21) and SCR catalyst (22) An injector (24) for injecting urea water in a connecting pipe (23) connecting the inlet of the inlet, and a supply device (26) for supplying urea water to the injector (24), and the supply device (26) For storing urea water supplied by A tank (28) is provided, the urea aqueous solution tank (28) is disposed in a space below the right bottom wall (7G) of the gren tank (7), and a water supply port (28A) of the urea aqueous solution tank (28) The water tank is disposed in the vicinity of the rear wall (7D) of the gren tank (7) in the longitudinal direction of the airframe, and the drainage port (28B) of the urea water tank (28) is disposed above the outside of the mudguard cover (55). It is a combine characterized by that.

  The invention according to claim 2 is the combine according to claim 1, wherein a pedestal (71) is provided on the front side of the urea water tank (28) for mounting a container (70) storing urea water for replenishment. .

  The invention according to claim 3 is the combine according to claim 1 or 2, wherein a battery (76) for supplying power to the supply device (26) is provided on the front side of the urea aqueous solution tank (28).

  In the invention according to claim 4, a radiator (80) is provided outside the engine (E) in the engine room (6), and a fan (81) is provided between the engine (E) and the radiator (80). The fan (81) is configured to be switched between a normal rotation state in which external air is sucked into the engine room (6), a rotation stop state, and a reverse rotation state in which the air in the engine room (6) is discharged to the outside. When the temperature of urea water detected by the sensor (75) provided in the urea water tank (28) is lower than a predetermined temperature, the fan (81) is stopped rotating, and detected by the sensor (75) If the temperature of the aqueous urea solution is higher than a predetermined temperature, switching between the forward rotation state and the reverse rotation state of the fan (81) is repeated, and between the supply device (26) and the aqueous urea tank (28), Urea water A combine according to claim 1 in which the first hose (27A) and the radiator water is arranged to be parallel to a second hose to pass (27B) to pass.

  The invention according to claim 5 is characterized in that a first cover (67) extending downward from the lower part of the right wall (7B) of the gren tank (7) is provided, and the urea water tank (28) is the gren tank The combine according to any one of claims 1 to 4, which is disposed between the right bottom wall (7G) of (7) and the first cover (67).

  In the invention according to claim 6, the second cover (68) is detachably provided at the lower part of the first cover (67), and the second cover (68) is from the lower end of the first cover (67). A first extension extending downward, a second extension extending downward to the left from the lower end of the first extension, and a lower end of the right bottom wall 7G from the lower end of the second extension The combine according to claim 5, wherein the right side wall and the bottom wall of the aqueous urea solution tank (28) are covered with the second cover (68).

  The invention according to claim 7 supports the urea aqueous solution tank (28) to the right bottom wall (7G) and the first cover (67) via a hanging member (90), and the hanging member (90), a substantially U-shaped front suspension portion (91) for supporting the front portion of the urea water tank (28), and a substantially U-shaped back portion for supporting the rear portion of the urea water tank (28) It comprises the side suspension part (92) and the connection part (93) which connects the left part of the front side suspension part (91) and the rear side suspension part (92), and the front side in the right bottom wall (7G) A first reinforcing plate (63) provided with an engaging member at a site where the left connecting portion (91D) of the hanging portion (91) and the left connecting portion (92D) of the rear hanging portion (92) are engaged. Right side connection part (91E) of the front side hanging part (91) of the first cover (67) and a rear side hanging part (92 Right connecting portion (92E) at the site to be engaged in a combine of claim 5 or 6, wherein providing the second reinforcing plate is engaging member provided (64).

  The invention according to claim 8 is the combine according to claim 7, wherein a plurality of substantially hook-shaped support members (96) are provided at intervals in the front-rear direction at the connecting portion (93).

  According to the invention of claim 1, a mudguard cover (55) extending in the front-rear direction is provided above the crawler (2A) of the traveling device (2), and the threshing device (4) and the gren tank (7) In the meantime, an exhaust gas purification device (20) for purifying the exhaust gas of the engine (E) is provided, and the exhaust gas purification device (20) removes the particulate matter in the exhaust gas discharged from the engine (E) 21) and an SCR catalyst (22) for purifying the nitrogen oxides in the exhaust gas after passing through the DPF (21) by reduction with ammonia generated from urea water, and an outlet of the DPF (21) and the SCR catalyst An injector (24) for injecting urea water is provided in a connection pipe (23) connecting the inlet of (22), and a supplier (26) for supplying urea water to the injector (24); Urea that stores urea water supplied by A tank (28) is provided, and the urea aqueous solution tank (28) is disposed in the space below the right bottom wall (7G) of the gren tank (7), and the water supply port (28A) of the urea aqueous solution tank (28) The water tank (7) is disposed near the rear wall (7D) of the gren tank (7), and the drainage port (28B) of the urea water tank (28) is arranged above the outside of the mudguard cover (55). The weight of the fore part of) can be reduced, for example, when the gren tank (7) can be opened and closed from the storage position on the machine to the maintenance position outside the machine, the gren tank (7) is stored from the maintenance position It can be easily returned to the working position. In addition, the urea aqueous solution can be easily replenished to the urea aqueous solution tank (28). Furthermore, a large space can be secured under the urea water tank (28), and after use urea water can be easily drained downward from the drainage port (28B), corrosion of the mudguard cover (55) by the urea water Can be prevented.

  According to the invention of claim 2, in addition to the effect of the invention of claim 1, a pedestal (70) on which a container (70) storing urea aqueous solution for replenishment is placed on the front side of the urea aqueous solution tank (28). 71), so that when the urea aqueous solution is replenished to the urea aqueous solution tank (28), the container (70) can be replenished while being placed on the pedestal (71), and the urea aqueous solution tank (28) can be replenished. Urea solution can be easily replenished.

According to the invention of claim 3, in addition to the effect of the invention of claim 1 or 2, a battery (76) for supplying power to the supply device (26) is provided on the front side of the urea aqueous solution tank (28). Therefore, even after the engine (E) is stopped, the feed device (26) can be reversely driven to suck the urea water in the hose back to the urea water tank (28).

  According to the invention of claim 4, in addition to the effect of the invention according to any one of claims 1 to 3, a radiator (80) is provided outside the engine (E) in the engine room (6), A fan (81) is provided between the engine (E) and the radiator (80), and the fan (81) is operated in a forward rotation state for sucking external air into the engine room (6), a rotation stop state, an engine room ( 6) It is configured to switch to a reverse rotation state in which the air inside is discharged to the outside, and when the temperature of the aqueous urea solution detected by the sensor (75) provided in the aqueous urea solution tank (28) is lower than a predetermined temperature When the temperature of the aqueous urea solution detected by the sensor (75) is higher than the predetermined temperature, the switching between the forward rotation state and the reverse rotation state of the fan (81) is repeated, and the supply device (26) is turned off. ) And urea water tank Since the first hose (27A) through which the urea water passes and the second hose (27B) through which the radiator water passes are arranged in parallel between (28), the urea stored in the urea water tank (28) Freezing of water can be prevented, and overheating of the engine (E) can also be prevented.

  According to the invention of claim 5, in addition to the effect of the invention according to any one of claims 1 to 4, it extends downward from the lower portion of the right wall (7B) of the glen tank (7). Since the first cover (67) was provided and the urea aqueous solution tank (28) was disposed between the right bottom wall (7G) of the glen tank (7) and the first cover (67), the urea aqueous solution tank (28) It is possible to prevent damage due to collision with an obstacle such as a bag.

According to the sixth aspect of the present invention, in addition to the effects of the fifth aspect, the second cover (68) is detachably provided on the lower portion of the first cover (67), and the second cover (68) A first extension extending downward from the lower end of the first cover (67), a second extension extending downward to the left from the lower end of the first extension, and a second extension And the right side wall and the bottom wall of the urea aqueous solution tank (28) are covered with the second cover (68), so that the urea is formed. It is possible to more effectively prevent the water tank (28) from colliding with an obstacle such as a weir and damaging it.

  According to the invention of claim 7, in addition to the effect of the invention of claim 5 or 6, the urea aqueous solution tank (28) is suspended from the right bottom wall (7G) and the first cover (67). A U-shaped front suspension portion (91) for supporting the suspension member (90) through the member (90) and supporting the front portion of the urea water tank (28); and the urea water tank (28) U-shaped rear suspension part (92) for supporting the rear of the rear part, and a connection part (93) for connecting the left part of the front suspension part (91) and the rear suspension part (92) An engagement member is provided at a site where the left connection (91D) of the front suspension (91) and the left connection (92D) of the rear suspension (92) in the right bottom wall (7G) are engaged. Provided with the first reinforcing plate (63), and the right connecting portion (91E) of the front hanging portion (91) of the first cover (67) Since the second reinforcing plate (64) provided with the engaging member is provided at the site where the right side connecting part (92E) of the rear side hanging part (92) is engaged, the urea water tank (28) is suspended The suspension member (90) can be easily attached to and detached from the right bottom wall (7G) and the first cover (67) in a state of being attached to the member (90). Moreover, the rigidity of the right bottom wall (66) of the gren tank (7) can be enhanced, and the deformation of the right bottom wall (66) due to the stored weight of grain and the like can be prevented.

  According to the eighth aspect of the present invention, in addition to the effect of the seventh aspect, the connecting portion (93) is provided with a plurality of substantially hook-shaped support members (96) spaced apart in the front-rear direction. Therefore, the connecting pipe connected to the urea aqueous solution tank (25) can be fixed to the support member (96) to prevent the connecting pipe from drooping.

It is a left view of a combine. It is a top view of a combine. It is a left view explaining an engine and a purification device. It is a right side view explaining an engine and a purification device. It is a top view explaining an engine and a purification device. It is a front view explaining the purification device provided in the crevice of the grain tank. It is a rear view explaining the purification apparatus provided in the recessed part of the grain tank. It is a top view explaining the purification device provided in the crevice of the grain tank. It is a rear view explaining the urea water tank provided in the grain tank. It is a right view explaining a urea water tank provided in a grain tank. It is an enlarged rear view explaining the urea water tank provided in the grain tank. It is an enlarged right side view explaining the urea water tank provided in the grain tank. It is a right side view explaining the suspension member of a urea water tank. It is a front view explaining the suspension member of a urea water tank. It is a front view explaining a fan of an engine room. It is a left view explaining a fan of an engine room.

  As shown in FIGS. 1 and 2, the combine is provided with a traveling device 2 consisting of a pair of left and right crawlers 2A traveling on the soil surface below the body frame 1, and cutting the field bales on the front side of the body frame 1. A harvesting device 3 is provided, a threshing device 4 for threshing / sorting the cropped grain to the rear left side of the harvesting device 3 is provided, and a control unit 5 on which an operator boarding is provided on the rear right side of the harvesting device 3 It is done.

  Under the control unit 5 is provided an engine room 6 equipped with an engine E, and on the rear side of the control unit 5 is provided a gren tank 7 for storing threshed and sorted grains. A discharge auger 8 comprising a vertical discharge auger 8A extending in the vertical direction for discharging the grain to the outside and a horizontal discharge auger 8B extending in the front and rear direction is provided on the rear side.

  As shown in FIGS. 3 to 5, an intake pipe (not shown) for supplying the purified air is connected to the intake port of the engine E, and the exhaust port of the engine E is an exhaust gas burned by the engine E. The front side exhaust pipe 10 which exhausts to the outside is connected.

  An exhaust gas purification device 20 for purifying impurities in the exhaust gas is connected to the outlet of the front side exhaust pipe 10. The exhaust purification device 20 has a DPF 21 for removing particulate matter in the exhaust gas, and an SCR catalyst 22 for purifying nitrogen oxides (NOx) in the exhaust gas exhausted from the DPF 21 by reducing ammonia with ammonia generated from urea water. It consists of

  An injector 24 which is a valve for injecting urea water to the SCR catalyst 22 via the connecting pipe 23 is connected to the rear of the flexible connecting pipe 23 connecting the outlet of the DPF 21 and the inlet of the SCR catalyst 22 The injection device 24 is connected to a supply device 26 which is a pump for supplying urea aqueous solution via a flexible hose 25. The supply device 26 stores urea aqueous solution via a flexible hose 27. A urea water tank 28 is connected. Further, a flexible rear side exhaust pipe 11 for discharging the exhaust gas after purification to the outside is connected to the outlet of the SCR catalyst 22.

  The front portion of the exhaust gas purification device 20 faces the rear left side of the engine room 6 and extends to a storage chamber 60 for storing an electric board provided on the rear left side of the engine room 6. Thereby, the cut of the recessed part 30 of the grain tank 7 mentioned later can be made small, and the reduction | decrease in the storage capacity of the grain tank 7 can be suppressed.

  A heat shield 61 is provided on the front side of the front portion of the exhaust purification device 20 at a predetermined interval. As a result, it is possible to prevent the electric substrate from becoming excessively hot, and to prevent the ambient temperature of the control seat 5A of the control unit 5 from rising. Further, in the present embodiment, the heat shield 61 is erected on the front side of the front portion of the exhaust gas purification device 20, but exhaust gas purification is performed so as to cover the front portion of the exhaust gas purification device 20 extending to the storage chamber 60. It is preferable to provide the heat shield 61 on the upper side, the left side and the right side of the front part of the device 20, and it is more preferable to form the heat shield 61 in a double structure.

  The connection pipe 23 is provided on the upper portion between the DPF 21 and the SCR catalyst 22 so as to extend substantially linearly in the front-rear direction, and the injection device 24 is connected to the rear side of the connection pipe 23. In addition, the injection device 24 is fixed to a support member (not shown) provided at the rear of the SCR catalyst 22. Thereby, urea water can be efficiently injected from the injection device 24 to the SCR catalyst 22 through the connection pipe 23.

  The supply device 26 is attached to a reinforcing plate 17 connected between the right front longitudinal frame 14 and the right rear longitudinal frame 15 supporting the horizontal frame 16 for fixing the exhaust gas purification device 20. It is provided below the middle portion of the exhaust gas purification device 20 in the front-rear direction. As a result, the length of the hose 25 connecting the injection device 24 and the supply device 26 can be shortened, and urea water can be efficiently supplied from the supply device 26 to the injection device 24. As described later, the urea aqueous solution tank 28 is provided at the rear of the right bottom wall 7G of the grain tank 7.

  As shown in FIGS. 6-8, the rear exhaust pipe 11 extends rearward from the outlet of the SCR catalyst 22 in a plan view, and is bent approximately 90 degrees to the left on the right side of the injection device 24 in the recess 30 It is later extended to the left side, is bent approximately 90 degrees to the rear side at the right part of the threshing device 4 and then extends to the rear side and reaches the left side of the grain barrel 18. The rear exhaust pipe 11 extends from the center of the SCR catalyst 22 toward the upper right side of the threshing device 4 in a front view, and the central part of the rear exhaust pipe 11 extends from the horizontal frame 16 to the rear It is fixed to the stay (illustration omitted) extended. Thus, exhaust gas can be exhausted to the rear of the cockpit 5A, and the surrounding environment of the cockpit 5A can be maintained at a predetermined level or more.

  The grain transfer barrel 18 is a device for transferring the grain threshed and sorted by the grain removal device 4 to the gren tank 7, and the lower part of the grain transfer barrel 18 is fixed to the lower part of the right wall 4 B of the grain removing device 4, The upper portion of the grain transfer barrel 18 is fixed to the upper portion of the left wall 7A of the gren tank 7.

  The DPF 21 and the SCR catalyst 22 of the exhaust gas purification device 20 are provided between the threshing device 4 and the gren tank 7 along the longitudinal direction of the airframe, and extend from the airframe 1 to the upper front longitudinal frame 13 The right front vertical frame 14 and the horizontal frame 16 fixed to the upper part of the right rear vertical frame 15 are placed. The DPF 21 is provided on the left side which is the threshing device 4 side, and the SCR catalyst 22 is provided on the right side which is the grain tank 7 side.

  The upper wall 4E of the threshing apparatus 4 is located below the upper wall 7E of the grain tank 7, and is inclined downward toward the grain tank 7 and extends in the front-rear direction on the right front side of the upper wall 4E. The inclined portion 4G is formed. Further, in the front view, the upper end portions of the DPF 21 and the SCR catalyst 22 are provided to be biased lower than the upper wall 4E. Thus, the stay 45 extending from the inclined portion 4G of the threshing device 4 to the upper right side above the DPF 21 and the SCR catalyst 22, and the vertical position restriction extending from the left wall 7A of the grain tank 7 to the left side A member (not shown) can be provided, and the vertical position regulating member can be engaged with the stay 45 to regulate the vertical position of the glen tank 7.

  The grain tank 7 is formed of a left wall 7A, a right wall 7B, a front wall 7C, a rear wall 7D, an upper wall 7E, a left bottom wall 7F, and a right bottom wall 7G. A recess 30 whose front and left sides are open is formed in the portion of the left wall 7A located on the front side of the grain transfer barrel 18, and in the portion of the left wall 7A located on the back side of the grain transfer barrel 18, A convex portion 50 formed to bulge toward the threshing device 4 is formed.

  In a front view, the SCR catalyst 22 enters the recess 30, and the DPF 21 is provided outside the recess 30. Thereby, the DPF 21 and the SCR catalyst 22 can be provided side by side in the left-right direction between the threshing device 4 and the gren tank 7, and the depression 30 is made smaller to suppress the reduction of the storage capacity of the gren tank 7. be able to.

  In addition, the exhaust gas purification device 20 is provided at a relatively low position. As a result, the distance from the engine E to the exhaust gas purification device 20 is shortened, and the decrease in the exhaust gas purification action of the exhaust gas purification device 20 can be reduced. In addition, the atmosphere temperature of the DPF 21 and the SCR catalyst 22 is less likely to decrease due to the presence of the upper portion of the right wall 4B of the threshing device 4 and the recess 30 of the grain tank 7, and the reduction of the exhaust purification function can be reduced.

  The portion of the left wall 7A located on the front side of the grain transfer barrel 18 is an upper left wall 31 extending downward from the left end of the upper wall 7E and a lower right side from the lower end of the upper left wall 31 in front view The upper inclined wall 32 extending toward the bottom, the middle left wall 33 extending downward from the lower end of the upper slanting wall 32, and the lower inclined wall 34 extending downward to the left from the lower end of the middle left wall 33 And the lower left wall 35 extending downward from the lower end of the lower inclined wall 34. Further, the lower end portion of the lower left wall 35 extends to the left end of the left bottom wall 7F of the grain tank 7, and the grain is conveyed to the vertical discharge auger 8A at the bottom of the left bottom wall 7F and the right bottom wall 7G. A transport spiral 36 extending in the front-rear direction is provided.

  The downward inclination angle of the upper inclined wall 32 is formed to be steeper than the downward inclination angle of the lower inclined wall 34. As a result, the grain transported to the grain tank 7 by the grain transfer barrel 18 can be smoothly dropped to the lower part of the grain tank 7, and the grain can be efficiently transported by the transport spiral 36. The downward inclination angle of the upper inclined wall 32 is preferably formed to be steeper than the repose angle at which grains can fall under their own weight. In the present embodiment, the downward inclination angle of the inclined wall 32 is set to the upper surface of the airframe 1 The inclination angle to the right is 45 degrees. The downward inclination angle of the lower inclined wall 34 is formed to be a downward inclination angle of 30 degrees with respect to the upper surface of the airframe frame 1 in order to increase the storage capacity of the grain tank 7. Further, an intermediate left wall 33 connecting the upper inclined wall 32 and the lower inclined wall 34 is formed at a position deviated to the right of the upper side of the transport spiral 36. Thereby, the grain transported to the gren tank 7 by the grain rising barrel 18 can be dropped smoothly by the lower part of the gren tank 7.

  An outer peripheral portion of the exhaust gas purification device 20 is covered with a cover 40, and the cover 40 is a right cover 41 extending upward from a portion of the horizontal frame 16 positioned on the right side of the SCR catalyst 22. An upper right inclined cover 42 extending from the upper end to the upper left, an upper left inclined cover 43 extending from the left end of the upper right inclined cover 42 to the lower left, and a lower end from the left end of the upper left inclination cover 43 It is formed by the left cover 44 which reaches the part of the horizontal frame 16 located on the left side of the DPF 21 as it is. As a result, deposition of scale and the like can be prevented on the outer peripheral portion of the DPC and the like of the exhaust gas purification device 20, and ignition of the scale and the like can be prevented.

  In the front view, the upper right inclined cover 42 and the upper left inclined cover 43 are formed in a substantially mountain shape, and in the present embodiment, the right downward inclination of the upper right inclined cover 42 is gentler than the left downward inclination of the upper left inclination cover 43 Although formed, conversely to this, the right downward inclination of the upper right inclination cover 42 can be formed to be steeper than the left downward inclination of the upper left inclination cover 43. Thereby, it is possible to prevent the accumulation on the upper right inclined cover 42 such as straw mixed in the grain discharged from the discharge auger 8.

  As shown in FIGS. 9 and 10, a urea aqueous solution tank 28 is provided on the right of the rear of the right bottom wall 7G of the gren tank 7. The urea aqueous solution tank 28 is detachably suspended to the right bottom wall 7G of the glen tank 7 via the suspending member 90 and the fixed cover 67 which is fixed to the lower part of the right wall 7B of the glen tank 7 and extends downward. It is done. Thereby, the weight of the front part of the glen tank 7 can be reduced, and the gren tank 7 can be smoothly moved from the storage position to the open position and from the open position to the storage position.

  The water supply port 28A of the urea aqueous solution tank 28 is formed on the rear side of the upper wall of the urea aqueous solution tank 28, and a portion of the rear wall 7D of the glen tank 7 facing the urea aqueous solution tank is notched in a substantially pentagonal shape. A cutaway portion 65 is formed. Thus, the urea water can be easily replenished to the urea water tank 28 from the rear of the glen tank 7.

  A drain port 28B formed on the lower wall of the urea water tank 28 is disposed on the upper right side of a mudguard cover 55 provided on the upper side of the crawler 2A on the right side of the traveling device 2 and extending in the front-rear direction. As a result, a large space can be secured under the drainage port 28B of the urea water tank 28, and the used urea water can be easily drained to the drainage tank from the drainage port 28B. Corrosion can be prevented.

  On the lower side of the fixed cover 67, there is provided a removable cover ("second cover" in the claims) which is detachably fixed to the lower part of the fixed cover ("the first cover" in the claims). The removable cover 68 has a first extension extending downward from the lower end of the fixed cover 67, a second extension extending downward to the left from the lower end of the first extension, and a second extension. A third extension extending from the lower end of the existing portion to the left below the urea aqueous solution tank 28 and extending to the lower portion of the right bottom wall 7G is formed. Thereby, it is possible to prevent the urea aqueous solution tank 28 from colliding with the soil and being damaged while the combine is traveling.

  A pedestal 71 on which a container 70 such as a plastic bag containing urea aqueous solution to be replenished to the urea aqueous solution tank 28 is placed at a position on the front side of the urea aqueous solution tank 28 in the right bottom wall 7G of the glen tank 7 It is provided. Accordingly, when the urea aqueous solution is replenished to the urea aqueous solution tank 28, the container 70 can be replenished in a state of being placed on the pedestal 71, and the urea aqueous solution can be easily replenished to the urea aqueous solution tank 28. . The pedestal 71 is bridged by a pair of left and right hanging members 72 extending downward from the right bottom wall 7G of the grain tank 7.

  A sensor 75 is provided to measure the temperature of the aqueous urea solution provided at the front portion of the upper wall of the aqueous urea tank 28, and the supply device 26 and sensor 75 are provided at the top of the front wall of the aqueous urea tank 28 when the engine E is stopped. And the like are provided with a battery 76 for supplying power. As a result, even after the engine E is stopped, the supply device 26 can be reversely driven to suck the urea water in the hose back to the urea water tank 28. The battery 76 can also be provided with a pedestal on the front side of the urea aqueous solution tank 28 and always equipped.

  As shown in FIGS. 11 and 12, a reinforcing plate having a triangular cross-sectional shape extending in the front-rear direction is formed on the right surface of the right bottom wall 7G of the glen tank 7 ("first reinforcing plate" in the claims) A reinforcing plate 64 ("second reinforcing plate" in the claims) having a triangular cross-sectional shape extending in the front-rear direction is provided on the left surface of the fixed cover 67 in a downward direction. . Thereby, the rigidity of the right bottom wall 7G of the glen tank 7 and the fixed cover 67 can be enhanced, and the deformation of the right bottom wall 7G of the glen tank 7 and the fixed cover 67 can be prevented.

  As shown in FIGS. 13 and 14, the suspending member 90 includes a substantially U-shaped front suspending portion 91 formed of round steel or the like, and a substantially U-shaped rear hanging formed of round steel or the like. A portion 92 and a connecting portion 93 extending in the front-rear direction formed of flat steel or the like for connecting the left portion of the front side hanging portion 91 and the left portion of the rear side hanging portion 92 are formed. Thereby, deformation or the like of the suspending member 90 can be prevented, and when the urea water tank 28 is attached to and detached from the suspending member 90, the connecting portion 93 can be prevented from being an obstacle.

  In the front view of the machine body, the front suspension portion 91 includes a left vertical portion 91A extending in the vertical direction, a right vertical portion 91B extending in the vertical direction, a lower portion of the left vertical portion 91A and a lower portion of the right vertical portion 91B. It forms from the horizontal part 91C extended to the left-right direction to connect.

  A plate-like left connecting portion 91D having a circular through hole for inserting an engaging member such as a bolt erected on the reinforcing plate 63 is provided on the upper portion of the left vertical portion 91A, and the right vertical portion 91A In the upper part of the plate, there is provided a plate-like right connecting portion 91E in which an oblong through hole having a major axis in the vertical direction for inserting an engaging member such as a bolt erected on the reinforcing plate 64 is formed. There is.

  In the front view of the machine body, the rear suspension 92 is a left vertical portion 92A extending in the vertical direction, a right vertical portion 92B extending in the vertical direction, a lower portion of the left vertical portion 92A and a lower portion of the right vertical portion 92B. Are formed from a horizontal portion 92C extending in the left-right direction connecting the two.

  A plate-like left connecting portion 92D having a circular through hole for inserting an engaging member such as a bolt erected on the reinforcing plate 63 is provided on the upper portion of the left vertical portion 92A, and the right vertical portion 92A In the upper part of the plate, there is provided a plate-like right connecting portion 92E in which an oblong through hole having a major axis in the vertical direction for inserting an engaging member such as a bolt erected on the reinforcing plate 64 is formed There is.

  As a result, after fixing the left connection portion 91D of the front suspension portion 91 and the left connection portion 92D of the rear suspension portion 92 respectively to the engaging members provided upright on the reinforcement plate 63, the standing members are erected on the reinforcement plate 64. The right connecting part 91E of the front hanging part 91 and the right connecting part 92E of the rear hanging part 92 are engaged with each other while moving in the vertical direction, and the hanging member 90 is formed as a reinforcing plate 63. And the reinforcing plate 64 can be easily attached and detached.

  A plate-like front connecting portion 94 for fixing the front wall of the urea water tank 28 is provided substantially at the middle in the left-right direction of the horizontal portion 91C of the front suspension portion 91. The through holes are formed at predetermined intervals in the vertical direction and through which fastening means such as bolts are inserted.

  A plate-shaped rear side connection portion 95 for fixing the rear wall of the urea water tank 28 is provided substantially in the middle in the left and right direction of the horizontal portion 92C of the rear side suspension portion 92. A through hole is formed at a central portion of the through hole for inserting fastening means such as a bolt at a predetermined interval in the vertical direction. Thereby, the urea water tank 28 can be reliably fixed to the suspension member 90. In addition, since the hanging member 90 can be easily attached and detached between the reinforcing plate 63 and the reinforcing plate 64, the urea aqueous solution tank 28 may be attached to and detached from between the reinforcing plate 63 and the reinforcing plate 64 together with the suspending member 90. it can.

  The vertical length of the left vertical portion 92A of the rear side hanging portion 92 is equal to the vertical length of the left vertical portion 91A of the front side hanging portion 91, and the right side of the rear side hanging portion 92 is formed. The vertical length of the vertical portion 92B is longer than the vertical length of the right vertical portion 91B of the front hanging portion 91. Thereby, the urea aqueous solution tank 28 can be suspended between the right bottom wall 7G of the glen tank 7 and the fixed cover 67 via the suspending member 90 while maintaining the horizontal posture without tilting in the longitudinal direction.

  The connecting portion 93 is provided with two support members 96 formed in a hook shape for supporting the plurality of hoses 27 at predetermined intervals in the front-rear direction. Thereby, it is possible to prevent the hose 27 from hanging down. The two hoses 27 are hoses (a "first hose" in claims) 27A for supplying urea water, and the two hoses 27 are hoses for supplying radiator water circulated through the engine E (claims) 'Second hose') 27B.

  The hose 27A and the hose 27B extend rearward from the aqueous urea tank 28 in parallel in the vertical direction, and then curve to extend the rear surface of the rear wall 7D of the glen tank 7 to the left, and then curve Then, the left surface of the left bottom wall 7F of the front glen tank 7 is extended to the front side to reach the supply device 26. As a result, when the gren tank 7 is moved from the storage position to the open position and from the open position to the storage position, the hose 27 can be easily bent to move the gren tank 7 smoothly. Further, the urea water supplied to the hose 27A is heated by the radiator water heated by the engine E supplied to the hose 27B, and freezing of the urea water can be prevented.

  As shown in FIGS. 15 and 16, a radiator 80 is provided on the right side of the engine E mounted in the engine compartment 6, and a fan 81 is provided between the engine E and the radiator 80. The fan 81 is supported by a rotating shaft 83 supported by a connecting member 82A which is provided on two arms 82 provided on the rear side of the radiator cover.

  A pulley 84A and a pulley 85A are provided on the left side of the rotating shaft 83. A pulley 84B is provided on the right side of the counter shaft 77 of the engine E, and a pulley 85B is provided on the right side of the output shaft 78 of the engine E. A belt 84C is wound around the pulleys 84A and 84B, and a belt 85C is wound around the pulleys 85A and 85B.

  The tension of the belt 84C is switched between a tensioned state and a relaxed state by a tension arm 84D provided with a roller at its tip, and the tension of the belt 85C is brought into a tensioned state and a slackened by a tension arm 85D provided with a roller at its tip Can be switched to

  The base of the tension arm 84D is fixed to a laterally extending rotary shaft 84E rotatably fixed to the connecting member 82A, and the base of the tension arm 85D is horizontally fixed to the connecting member 82A. It is being fixed to the rotating shaft 85E which extends.

  The base of the arm 84F extending forward and backward is fixed to the rotating shaft 84E, and the base of the arm 85F extending upward and backward is fixed to the rotating shaft 85E. The tip of the arm 84F and the tip of the arm 85F The parts are connected by a connecting member 86 made of round steel or the like. Thus, the tension arm 85D can be rotated in conjunction with the rotation of the tension arm 84D.

  The base of the operating arm 87 extending upward and backward is fixed to the rotating shaft 85E, and the tip of the operating arm 87 is a crank provided on the output shaft 88A of the tension arm motor 88 via a spring and a rod. It is connected to an arm 89. Thus, the tension arm 84D is rotated by one motor 88 to switch the tension of the belt 84C to the tension state, the intermediate state between tension and relaxation, and the relaxation state, and the tension arm 85D is rotated to rotate the belt 85C. The tension can be switched to the tension state, an intermediate state between tension and relaxation, and the relaxation state to switch the fan 81 to the normal rotation state, the stop state, and the reverse rotation state.

  The motor 88 is operated by a controller provided in the steering unit 5, and the output shaft 88A of the motor 88 is pivoted to the neutral position when the measurement value of the sensor 75 is below the temperature at which the urea water freezes. . As a result, the fan 81 is stopped, and the urea water can be warmed by the radiator water heated by the engine E to prevent freezing of the urea water. On the other hand, when the measured value of the sensor 75 is higher than the temperature at which the urea water freezes, the output shaft 88A of the motor 88 rotates clockwise and counterclockwise at constant time intervals in axial view of the output shaft 88A. Rotate. As a result, the fan 81 switches between the normal rotation state and the reverse rotation state at constant time intervals to prevent overheating of the engine E and efficiently remove the deposits attached to the engine compartment cover 6A of the engine compartment 6 it can.

  That is, when the output shaft 88A of the motor 88 is in the neutral position, the tension arm 84D is rotated to set the tension of the belt 84C to an intermediate state, and the tension arm 85D is rotated to rotate the tension of the belt 85C. Make it As a result, the fan 81 is stopped, the temperature in the engine compartment 6 rises, and the temperature of the radiator water supplied to the hose 27B rises, and is supplied to the hose 27A juxtaposed to the hose 27B. The urea water is heated to prevent freezing of the urea water.

  When the output shaft 88A of the motor 88 rotates from the neutral position to the clock position in the axial view of the output shaft 88A, the rotational shaft 85E rotates in the clockwise direction in the axial view of the output shaft 85E. The leading end of the tension arm 85D moves in a direction away from the belt 85C, and the tension of the belt 85C is relaxed. On the other hand, when the rotating shaft 85E rotates in the clockwise direction, the leading end of the tension arm 84D moves toward the belt 85C, and the tension of the belt 84C becomes tense. As a result, the fan 81 rotates in the normal direction, which is the clockwise direction, to be in the positive rotation state in the axial center view of the rotating shaft 83, and the inside of the engine room 6 from the outside through the engine room cover 6A The air can be sucked into the radiator 80 to cool the radiator 80, the engine E, and the like.

  Furthermore, when the output shaft 88A of the motor 88 rotates from the neutral position to the counterclockwise position in the axial view of the output shaft 88A, the rotational shaft 85E rotates in the counterclockwise direction in the axial view of the output shaft 85E. As a result, the leading end of the tension arm 85D moves toward the belt 85C, and the tension of the belt 85C is tightened. On the other hand, when the rotating shaft 85E rotates counterclockwise, the tip end of the tension arm 84D moves in the direction of separating from the belt 85C, and the tension of the belt 84C is relaxed. As a result, the fan 81 rotates in the reverse direction, which is a counterclockwise direction, into the reverse rotation state in the axial view of the rotating shaft 83, and the air in the engine room 6 through the engine room cover 6A of the engine room 6 It can be discharged to the outside to remove deposits such as scraps adhering to the engine compartment cover 6A.

Reference Signs List 1 airframe frame 2 traveling device 2A crawler 3 reaper 4 threshing device 5 control unit 6 engine room 7 grain tank 7B right wall 7D back wall 7G right bottom wall 20 exhaust purification device 21 DPF
22 SCR catalyst 23 connecting pipe 24 injector 26 supply device 27A hose (first hose)
27B hose (second hose)
28 urea water tank 28A water supply port 28B drain port 55 mudguard cover 63 reinforcing plate (first reinforcing plate)
64 Reinforcement plate (2nd reinforcement plate)
67 Fixed cover (first cover)
68 Detachable cover (second cover)
70 container 71 pedestal 75 sensor 76 battery 80 radiator 81 fan 90 hanging member 91 front hanging part 91D left connecting part 91E right connecting part 92 rear side hanging part 92D left connecting part 92E right connecting part 93 connecting part 96 supporting member E engine

  The present invention relates to a combine equipped with an exhaust gas purification device.

  In the conventional combine, when the SCR catalyst is mounted as an exhaust purification device, the urea aqueous solution tank storing urea aqueous solution is supported at the front of the right bottom wall of the grain tank storing grain and the water supply port of the urea tank It is known that the technology has been made to face the front wall of the gren tank. (Patent Document 1)

JP, 2016-42850, A

  However, in the technique described in Patent Document 1, the weight of the front of the gren tank becomes heavy, and the gren tank can be easily returned from the open position (maintenance position) to the storage position (storage operation position) on the machine frame. In addition, there is a problem that the used aqueous urea solution can not be easily taken out from the aqueous urea solution tank of the exhaust gas purification device.

  Therefore, an object of the present invention is to provide a combine capable of reducing the weight of the front of the glen tank and easily discharging the used urea water to the outside from the urea water tank of the exhaust purification device. .

The present invention which solved the above-mentioned subject is as follows.
That is, according to the first aspect of the present invention, the traveling device (2) is provided under the body frame (1), and the harvesting device (3) for harvesting the grain is provided on the front side of the body frame (1) A threshing device (4) for threshing grain is provided on the rear left side of the reaper (3), and a control unit (5) on which a rider gets on the rear right side of the reaper (3) is provided. ) In the lower part of the engine room (6) containing the engine (E) and in the rear side of the control part (5) a combine tank provided with a grain tank (7) for storing threshed grains,
A mudguard cover (55) extending in the front-rear direction is provided above the crawler (2A) of the traveling device (2), and the engine (E) is disposed between the threshing device (4) and the gren tank (7). An exhaust gas purification device (20) for purifying the exhaust gas, the exhaust gas purification device (20) comprising: a DPF (21) for removing particulate matter in the exhaust gas discharged from the engine (E); It has SCR catalyst (22) which reduces and purifies the nitrogen oxide substance in the exhaust gas after DPF (21) passage with ammonia generated from urea water, and the outlet of said DPF (21) and SCR catalyst (22) An injector (24) for injecting urea water in a connecting pipe (23) connecting the inlet of the inlet, and a supply device (26) for supplying urea water to the injector (24), and the supply device (26) For storing urea water supplied by Tank provided (28), the urea water tank (28), disposed on the right bottom wall (7G) a rear portion of the right outer downwardly formed space of the grain tank (7), the urea water tank (28 Water supply port (28A) in the longitudinal direction of the airframe in the vicinity of the rear wall (7D) of the gren tank (7), and the drainage port (28B) of the urea water tank (28) 55) and is provided with a first cover (67) extending downward from the lower part of the right wall (7B) of the gren tank (7), and the urea water tank (28) is The urea water tank (28) is disposed between the right bottom wall (7G) of the tank (7) and the first cover (67), and the urea water tank (28) against the right bottom wall (7G) and the first cover (67). A suspension member (90) is supported, and the suspension member (90) is supported by the urea water tank. A substantially U-shaped front suspension portion (91) for supporting the front portion of the hood (28); and a substantially U-shaped rear suspension portion (92) for supporting the rear portion of the urea water tank (28) A left connecting portion (93) connecting the left side of the front side hanging portion (91) and the rear side hanging portion (92), the left side of the front side hanging portion (91) in the right bottom wall (7G) A first reinforcing plate (63) provided with a first engaging member is provided at a site where the connecting portion (91D) and the left connecting portion (92D) of the rear suspension portion (92) are engaged, A second engagement member is provided at a portion where the right connection portion (91E) of the front suspension portion (91) and the right connection portion (92E) of the rear suspension portion (92) of the cover (67) are engaged. A second reinforcing plate (64), and the cross-sectional shape of the first reinforcing plate (63) and the second reinforcing plate (64) A circular first through hole is formed in the shape of a triangle, and the first engaging portion is inserted into the left connecting portion (91D) and the left connecting portion (92D), and the right connecting portion (91E) and the right connecting portion are formed. An oval second through hole having a major axis in the vertical direction for inserting the second engaging portion is formed in the portion (92E) .

  The invention according to claim 2 is the combine according to claim 1, wherein a pedestal (71) is provided on the front side of the urea water tank (28) for mounting a container (70) storing urea water for replenishment. .

  The invention according to claim 3 is the combine according to claim 1 or 2, wherein a battery (76) for supplying power to the supply device (26) is provided on the front side of the urea aqueous solution tank (28).

  In the invention according to claim 4, a radiator (80) is provided outside the engine (E) in the engine room (6), and a fan (81) is provided between the engine (E) and the radiator (80). The fan (81) is configured to be switched between a normal rotation state in which external air is sucked into the engine room (6), a rotation stop state, and a reverse rotation state in which the air in the engine room (6) is discharged to the outside. When the temperature of urea water detected by the sensor (75) provided in the urea water tank (28) is lower than a predetermined temperature, the fan (81) is stopped rotating, and detected by the sensor (75) If the temperature of the aqueous urea solution is higher than a predetermined temperature, switching between the forward rotation state and the reverse rotation state of the fan (81) is repeated, and between the supply device (26) and the aqueous urea tank (28), Urea water A combine according to claim 1 in which the first hose (27A) and the radiator water is arranged to be parallel to a second hose to pass (27B) to pass.

In the fifth aspect of the present invention, the second cover (68) is detachably provided under the first cover (67), and the second cover (68) is provided from the lower end of the first cover (67). A first extension extending downward, a second extension extending downward to the left from the lower end of the first extension, and a lower end of the right bottom wall 7G from the lower end of the second extension to be formed from a third extending portion which extends, the right side wall and the bottom wall of the urea water tank (28) is a combine of claim 1, wherein the covering by the second cover (68).

A sixth aspect of the present invention is the combine according to the first aspect , wherein a plurality of substantially hook-shaped support members (96) are provided on the connection portion (93) at intervals in the front-rear direction.

According to the invention of claim 1, a mudguard cover (55) extending in the front-rear direction is provided above the crawler (2A) of the traveling device (2), and the threshing device (4) and the gren tank (7) In the meantime, an exhaust gas purification device (20) for purifying the exhaust gas of the engine (E) is provided, and the exhaust gas purification device (20) removes the particulate matter in the exhaust gas discharged from the engine (E) 21) and an SCR catalyst (22) for purifying the nitrogen oxides in the exhaust gas after passing through the DPF (21) by reduction with ammonia generated from urea water, and an outlet of the DPF (21) and the SCR catalyst An injector (24) for injecting urea water is provided in a connection pipe (23) connecting the inlet of (22), and a supplier (26) for supplying urea water to the injector (24); Urea that stores urea water supplied by Tank (28) is provided, the urea water tank (28), disposed on the right bottom wall (7G) a rear portion of the right outer downward the space formed in grain tank (7), the water supply of the urea water tank (28) The port (28A) is arranged in the longitudinal direction of the airframe in the vicinity of the rear wall (7D) of the gren tank (7), and the outlet (28B) of the urea water tank (28) is located above the outside of the mudguard cover (55). Since it arrange | positions, the weight of the front part of a gren tank (7) can be reduced, for example, when gren tank (7) is comprised so that opening / closing from the storage operation position on an airframe to the maintenance position of the airframe outer side is possible, this gren tank (7) can be easily returned from the maintenance position to the storage operation position. In addition, the urea aqueous solution can be easily replenished to the urea aqueous solution tank (28). Furthermore, a large space can be secured under the urea water tank (28), and after use urea water can be easily drained downward from the drainage port (28B), corrosion of the mudguard cover (55) by the urea water Can be prevented.
In addition, a first cover (67) extending downward from the lower part of the right wall (7B) of the gren tank (7) is provided, and the urea water tank (28) is used as the right bottom wall (7G) of the gren tank (7). And the first cover (67), it is possible to prevent the urea aqueous solution tank (28) from colliding with an obstacle such as a weir and damaging it.
Furthermore, the urea aqueous solution tank (28) is supported via the suspending member (90) with respect to the right bottom wall (7G) and the first cover (67), and the suspending member (90) is 28) a substantially U-shaped front suspension portion (91) for supporting the front portion, a substantially U-shaped rear suspension portion (92) for supporting a rear portion of the urea water tank (28), and a front suspension A left connecting part (91D) of the front hanging part (91) in the right bottom wall (7G), which comprises the lowering part (91) and a connecting part (93) connecting the left part of the rear side hanging part (92) A first reinforcing plate (63) provided with a first engaging member is provided at a position where the left connecting portion (92D) of the rear suspension portion (92) is engaged, and the front side of the first cover (67) At the site where the right connecting part (91E) of the hanging part (91) and the right connecting part (92E) of the rear hanging part (92) are engaged Since the second reinforcing plate (64) provided with the second engaging member is provided, the hanging member (90) is mounted on the right bottom wall in a state where the urea water tank (28) is attached to the hanging member (90). (7G) and can be easily attached and detached from the first cover (67). Moreover, the rigidity of the right bottom wall (66) of the gren tank (7) can be enhanced, and the deformation of the right bottom wall (66) due to the stored weight of grain and the like can be prevented.

  According to the invention of claim 2, in addition to the effect of the invention of claim 1, a pedestal (70) on which a container (70) storing urea aqueous solution for replenishment is placed on the front side of the urea aqueous solution tank (28). 71), so that when the urea aqueous solution is replenished to the urea aqueous solution tank (28), the container (70) can be replenished while being placed on the pedestal (71), and the urea aqueous solution tank (28) can be replenished. Urea solution can be easily replenished.

According to the invention of claim 3, in addition to the effect of the invention of claim 1 or 2, a battery (76) for supplying power to the supply device (26) is provided on the front side of the urea aqueous solution tank (28). Therefore, even after the engine (E) is stopped, the feed device (26) can be reversely driven to suck the urea water in the hose back to the urea water tank (28).

  According to the invention of claim 4, in addition to the effect of the invention according to any one of claims 1 to 3, a radiator (80) is provided outside the engine (E) in the engine room (6), A fan (81) is provided between the engine (E) and the radiator (80), and the fan (81) is operated in a forward rotation state for sucking external air into the engine room (6), a rotation stop state, an engine room ( 6) It is configured to switch to a reverse rotation state in which the air inside is discharged to the outside, and when the temperature of the aqueous urea solution detected by the sensor (75) provided in the aqueous urea solution tank (28) is lower than a predetermined temperature When the temperature of the aqueous urea solution detected by the sensor (75) is higher than the predetermined temperature, the switching between the forward rotation state and the reverse rotation state of the fan (81) is repeated, and the supply device (26) is turned off. ) And urea water tank Since the first hose (27A) through which the urea water passes and the second hose (27B) through which the radiator water passes are arranged in parallel between (28), the urea stored in the urea water tank (28) Freezing of water can be prevented, and overheating of the engine (E) can also be prevented.

According to the invention of claim 5, wherein, in addition to the effects of the invention of claim 1, wherein the lower portion of the first cover (67) is provided a second cover (68) removably, the second cover (68) A first extension extending downward from the lower end of the first cover (67), a second extension extending downward to the left from the lower end of the first extension, and a second extension And the right side wall and the bottom wall of the urea aqueous solution tank (28) are covered with the second cover (68), so that the urea is formed. It is possible to more effectively prevent the water tank (28) from colliding with an obstacle such as a weir and damaging it.

According to the sixth aspect of the invention, in addition to the effect of the invention of the first aspect , the connection portion (93) is provided with a plurality of substantially hook-shaped support members (96) at intervals in the front-rear direction. Therefore, the connecting pipe connected to the urea aqueous solution tank (25) can be fixed to the support member (96) to prevent the connecting pipe from drooping.

It is a left view of a combine. It is a top view of a combine. It is a left view explaining an engine and a purification device. It is a right side view explaining an engine and a purification device. It is a top view explaining an engine and a purification device. It is a front view explaining the purification device provided in the crevice of the grain tank. It is a rear view explaining the purification apparatus provided in the recessed part of the grain tank. It is a top view explaining the purification device provided in the crevice of the grain tank. It is a rear view explaining the urea water tank provided in the grain tank. It is a right view explaining a urea water tank provided in a grain tank. It is an enlarged rear view explaining the urea water tank provided in the grain tank. It is an enlarged right side view explaining the urea water tank provided in the grain tank. It is a right side view explaining the suspension member of a urea water tank. It is a front view explaining the suspension member of a urea water tank. It is a front view explaining a fan of an engine room. It is a left view explaining a fan of an engine room.

  As shown in FIGS. 1 and 2, the combine is provided with a traveling device 2 consisting of a pair of left and right crawlers 2A traveling on the soil surface below the body frame 1, and cutting the field bales on the front side of the body frame 1. A harvesting device 3 is provided, a threshing device 4 for threshing / sorting the cropped grain to the rear left side of the harvesting device 3 is provided, and a control unit 5 on which an operator boarding is provided on the rear right side of the harvesting device 3 It is done.

  Under the control unit 5 is provided an engine room 6 equipped with an engine E, and on the rear side of the control unit 5 is provided a gren tank 7 for storing threshed and sorted grains. A discharge auger 8 comprising a vertical discharge auger 8A extending in the vertical direction for discharging the grain to the outside and a horizontal discharge auger 8B extending in the front and rear direction is provided on the rear side.

  As shown in FIGS. 3 to 5, an intake pipe (not shown) for supplying the purified air is connected to the intake port of the engine E, and the exhaust port of the engine E is an exhaust gas burned by the engine E. The front side exhaust pipe 10 which exhausts to the outside is connected.

  An exhaust gas purification device 20 for purifying impurities in the exhaust gas is connected to the outlet of the front side exhaust pipe 10. The exhaust purification device 20 has a DPF 21 for removing particulate matter in the exhaust gas, and an SCR catalyst 22 for purifying nitrogen oxides (NOx) in the exhaust gas exhausted from the DPF 21 by reducing ammonia with ammonia generated from urea water. It consists of

  An injector 24 which is a valve for injecting urea water to the SCR catalyst 22 via the connecting pipe 23 is connected to the rear of the flexible connecting pipe 23 connecting the outlet of the DPF 21 and the inlet of the SCR catalyst 22 The injection device 24 is connected to a supply device 26 which is a pump for supplying urea aqueous solution via a flexible hose 25. The supply device 26 stores urea aqueous solution via a flexible hose 27. A urea water tank 28 is connected. Further, a flexible rear side exhaust pipe 11 for discharging the exhaust gas after purification to the outside is connected to the outlet of the SCR catalyst 22.

  The front portion of the exhaust gas purification device 20 faces the rear left side of the engine room 6 and extends to a storage chamber 60 for storing an electric board provided on the rear left side of the engine room 6. Thereby, the cut of the recessed part 30 of the grain tank 7 mentioned later can be made small, and the reduction | decrease in the storage capacity of the grain tank 7 can be suppressed.

  A heat shield 61 is provided on the front side of the front portion of the exhaust purification device 20 at a predetermined interval. As a result, it is possible to prevent the electric substrate from becoming excessively hot, and to prevent the ambient temperature of the control seat 5A of the control unit 5 from rising. Further, in the present embodiment, the heat shield 61 is erected on the front side of the front portion of the exhaust gas purification device 20, but exhaust gas purification is performed so as to cover the front portion of the exhaust gas purification device 20 extending to the storage chamber 60. It is preferable to provide the heat shield 61 on the upper side, the left side and the right side of the front part of the device 20, and it is more preferable to form the heat shield 61 in a double structure.

  The connection pipe 23 is provided on the upper portion between the DPF 21 and the SCR catalyst 22 so as to extend substantially linearly in the front-rear direction, and the injection device 24 is connected to the rear side of the connection pipe 23. In addition, the injection device 24 is fixed to a support member (not shown) provided at the rear of the SCR catalyst 22. Thereby, urea water can be efficiently injected from the injection device 24 to the SCR catalyst 22 through the connection pipe 23.

  The supply device 26 is attached to a reinforcing plate 17 connected between the right front longitudinal frame 14 and the right rear longitudinal frame 15 supporting the horizontal frame 16 for fixing the exhaust gas purification device 20. It is provided below the middle portion of the exhaust gas purification device 20 in the front-rear direction. As a result, the length of the hose 25 connecting the injection device 24 and the supply device 26 can be shortened, and urea water can be efficiently supplied from the supply device 26 to the injection device 24. As described later, the urea aqueous solution tank 28 is provided at the rear of the right bottom wall 7G of the grain tank 7.

  As shown in FIGS. 6-8, the rear exhaust pipe 11 extends rearward from the outlet of the SCR catalyst 22 in a plan view, and is bent approximately 90 degrees to the left on the right side of the injection device 24 in the recess 30 It is later extended to the left side, is bent approximately 90 degrees to the rear side at the right part of the threshing device 4 and then extends to the rear side and reaches the left side of the grain barrel 18. The rear exhaust pipe 11 extends from the center of the SCR catalyst 22 toward the upper right side of the threshing device 4 in a front view, and the central part of the rear exhaust pipe 11 extends from the horizontal frame 16 to the rear It is fixed to the stay (illustration omitted) extended. Thus, exhaust gas can be exhausted to the rear of the cockpit 5A, and the surrounding environment of the cockpit 5A can be maintained at a predetermined level or more.

  The grain transfer barrel 18 is a device for transferring the grain threshed and sorted by the grain removal device 4 to the gren tank 7, and the lower part of the grain transfer barrel 18 is fixed to the lower part of the right wall 4 B of the grain removing device 4, The upper portion of the grain transfer barrel 18 is fixed to the upper portion of the left wall 7A of the gren tank 7.

  The DPF 21 and the SCR catalyst 22 of the exhaust gas purification device 20 are provided between the threshing device 4 and the gren tank 7 along the longitudinal direction of the airframe, and extend from the airframe 1 to the upper front longitudinal frame 13 The right front vertical frame 14 and the horizontal frame 16 fixed to the upper part of the right rear vertical frame 15 are placed. The DPF 21 is provided on the left side which is the threshing device 4 side, and the SCR catalyst 22 is provided on the right side which is the grain tank 7 side.

  The upper wall 4E of the threshing apparatus 4 is located below the upper wall 7E of the grain tank 7, and is inclined downward toward the grain tank 7 and extends in the front-rear direction on the right front side of the upper wall 4E. The inclined portion 4G is formed. Further, in the front view, the upper end portions of the DPF 21 and the SCR catalyst 22 are provided to be biased lower than the upper wall 4E. Thus, the stay 45 extending from the inclined portion 4G of the threshing device 4 to the upper right side above the DPF 21 and the SCR catalyst 22, and the vertical position restriction extending from the left wall 7A of the grain tank 7 to the left side A member (not shown) can be provided, and the vertical position regulating member can be engaged with the stay 45 to regulate the vertical position of the glen tank 7.

  The grain tank 7 is formed of a left wall 7A, a right wall 7B, a front wall 7C, a rear wall 7D, an upper wall 7E, a left bottom wall 7F, and a right bottom wall 7G. A recess 30 whose front and left sides are open is formed in the portion of the left wall 7A located on the front side of the grain transfer barrel 18, and in the portion of the left wall 7A located on the back side of the grain transfer barrel 18, A convex portion 50 formed to bulge toward the threshing device 4 is formed.

  In a front view, the SCR catalyst 22 enters the recess 30, and the DPF 21 is provided outside the recess 30. Thereby, the DPF 21 and the SCR catalyst 22 can be provided side by side in the left-right direction between the threshing device 4 and the gren tank 7, and the depression 30 is made smaller to suppress the reduction of the storage capacity of the gren tank 7. be able to.

  In addition, the exhaust gas purification device 20 is provided at a relatively low position. As a result, the distance from the engine E to the exhaust gas purification device 20 is shortened, and the decrease in the exhaust gas purification action of the exhaust gas purification device 20 can be reduced. In addition, the atmosphere temperature of the DPF 21 and the SCR catalyst 22 is less likely to decrease due to the presence of the upper portion of the right wall 4B of the threshing device 4 and the recess 30 of the grain tank 7, and the reduction of the exhaust purification function can be reduced.

  The portion of the left wall 7A located on the front side of the grain transfer barrel 18 is an upper left wall 31 extending downward from the left end of the upper wall 7E and a lower right side from the lower end of the upper left wall 31 in front view The upper inclined wall 32 extending toward the bottom, the middle left wall 33 extending downward from the lower end of the upper slanting wall 32, and the lower inclined wall 34 extending downward to the left from the lower end of the middle left wall 33 And the lower left wall 35 extending downward from the lower end of the lower inclined wall 34. Further, the lower end portion of the lower left wall 35 extends to the left end of the left bottom wall 7F of the grain tank 7, and the grain is conveyed to the vertical discharge auger 8A at the bottom of the left bottom wall 7F and the right bottom wall 7G. A transport spiral 36 extending in the front-rear direction is provided.

  The downward inclination angle of the upper inclined wall 32 is formed to be steeper than the downward inclination angle of the lower inclined wall 34. As a result, the grain transported to the grain tank 7 by the grain transfer barrel 18 can be smoothly dropped to the lower part of the grain tank 7, and the grain can be efficiently transported by the transport spiral 36. The downward inclination angle of the upper inclined wall 32 is preferably formed to be steeper than the repose angle at which grains can fall under their own weight. In the present embodiment, the downward inclination angle of the inclined wall 32 is set to the upper surface of the airframe 1 The inclination angle to the right is 45 degrees. The downward inclination angle of the lower inclined wall 34 is formed to be a downward inclination angle of 30 degrees with respect to the upper surface of the airframe frame 1 in order to increase the storage capacity of the grain tank 7. Further, an intermediate left wall 33 connecting the upper inclined wall 32 and the lower inclined wall 34 is formed at a position deviated to the right of the upper side of the transport spiral 36. Thereby, the grain transported to the gren tank 7 by the grain rising barrel 18 can be dropped smoothly by the lower part of the gren tank 7.

  An outer peripheral portion of the exhaust gas purification device 20 is covered with a cover 40, and the cover 40 is a right cover 41 extending upward from a portion of the horizontal frame 16 positioned on the right side of the SCR catalyst 22. An upper right inclined cover 42 extending from the upper end to the upper left, an upper left inclined cover 43 extending from the left end of the upper right inclined cover 42 to the lower left, and a lower end from the left end of the upper left inclination cover 43 It is formed by the left cover 44 which reaches the part of the horizontal frame 16 located on the left side of the DPF 21 as it is. As a result, deposition of scale and the like can be prevented on the outer peripheral portion of the DPC and the like of the exhaust gas purification device 20, and ignition of the scale and the like can be prevented.

  In the front view, the upper right inclined cover 42 and the upper left inclined cover 43 are formed in a substantially mountain shape, and in the present embodiment, the right downward inclination of the upper right inclined cover 42 is gentler than the left downward inclination of the upper left inclination cover 43 Although formed, conversely to this, the right downward inclination of the upper right inclination cover 42 can be formed to be steeper than the left downward inclination of the upper left inclination cover 43. Thereby, it is possible to prevent the accumulation on the upper right inclined cover 42 such as straw mixed in the grain discharged from the discharge auger 8.

  As shown in FIGS. 9 and 10, a urea aqueous solution tank 28 is provided on the right of the rear of the right bottom wall 7G of the gren tank 7. The urea aqueous solution tank 28 is detachably suspended to the right bottom wall 7G of the glen tank 7 via the suspending member 90 and the fixed cover 67 which is fixed to the lower part of the right wall 7B of the glen tank 7 and extends downward. It is done. Thereby, the weight of the front part of the glen tank 7 can be reduced, and the gren tank 7 can be smoothly moved from the storage position to the open position and from the open position to the storage position.

  The water supply port 28A of the urea aqueous solution tank 28 is formed on the rear side of the upper wall of the urea aqueous solution tank 28, and a portion of the rear wall 7D of the glen tank 7 facing the urea aqueous solution tank is notched in a substantially pentagonal shape. A cutaway portion 65 is formed. Thus, the urea water can be easily replenished to the urea water tank 28 from the rear of the glen tank 7.

  A drain port 28B formed on the lower wall of the urea water tank 28 is disposed on the upper right side of a mudguard cover 55 provided on the upper side of the crawler 2A on the right side of the traveling device 2 and extending in the front-rear direction. As a result, a large space can be secured under the drainage port 28B of the urea water tank 28, and the used urea water can be easily drained to the drainage tank from the drainage port 28B. Corrosion can be prevented.

  On the lower side of the fixed cover 67, there is provided a removable cover ("second cover" in the claims) which is detachably fixed to the lower part of the fixed cover ("the first cover" in the claims). The removable cover 68 has a first extension extending downward from the lower end of the fixed cover 67, a second extension extending downward to the left from the lower end of the first extension, and a second extension. A third extension extending from the lower end of the existing portion to the left below the urea aqueous solution tank 28 and extending to the lower portion of the right bottom wall 7G is formed. Thereby, it is possible to prevent the urea aqueous solution tank 28 from colliding with the soil and being damaged while the combine is traveling.

  A pedestal 71 on which a container 70 such as a plastic bag containing urea aqueous solution to be replenished to the urea aqueous solution tank 28 is placed at a position on the front side of the urea aqueous solution tank 28 in the right bottom wall 7G of the glen tank 7 It is provided. Accordingly, when the urea aqueous solution is replenished to the urea aqueous solution tank 28, the container 70 can be replenished in a state of being placed on the pedestal 71, and the urea aqueous solution can be easily replenished to the urea aqueous solution tank 28. . The pedestal 71 is bridged by a pair of left and right hanging members 72 extending downward from the right bottom wall 7G of the grain tank 7.

  A sensor 75 is provided to measure the temperature of the aqueous urea solution provided at the front portion of the upper wall of the aqueous urea tank 28, and the supply device 26 and sensor 75 are provided at the top of the front wall of the aqueous urea tank 28 when the engine E is stopped. And the like are provided with a battery 76 for supplying power. As a result, even after the engine E is stopped, the supply device 26 can be reversely driven to suck the urea water in the hose back to the urea water tank 28. The battery 76 can also be provided with a pedestal on the front side of the urea aqueous solution tank 28 and always equipped.

  As shown in FIGS. 11 and 12, a reinforcing plate having a triangular cross-sectional shape extending in the front-rear direction is formed on the right surface of the right bottom wall 7G of the glen tank 7 ("first reinforcing plate" in the claims) A reinforcing plate 64 ("second reinforcing plate" in the claims) having a triangular cross-sectional shape extending in the front-rear direction is provided on the left surface of the fixed cover 67 in a downward direction. . Thereby, the rigidity of the right bottom wall 7G of the glen tank 7 and the fixed cover 67 can be enhanced, and the deformation of the right bottom wall 7G of the glen tank 7 and the fixed cover 67 can be prevented.

  As shown in FIGS. 13 and 14, the suspending member 90 includes a substantially U-shaped front suspending portion 91 formed of round steel or the like, and a substantially U-shaped rear hanging formed of round steel or the like. A portion 92 and a connecting portion 93 extending in the front-rear direction formed of flat steel or the like for connecting the left portion of the front side hanging portion 91 and the left portion of the rear side hanging portion 92 are formed. Thereby, deformation or the like of the suspending member 90 can be prevented, and when the urea water tank 28 is attached to and detached from the suspending member 90, the connecting portion 93 can be prevented from being an obstacle.

  In the front view of the machine body, the front suspension portion 91 includes a left vertical portion 91A extending in the vertical direction, a right vertical portion 91B extending in the vertical direction, a lower portion of the left vertical portion 91A and a lower portion of the right vertical portion 91B. It forms from the horizontal part 91C extended to the left-right direction to connect.

  In the upper portion of the left vertical portion 91A, a circular through hole for inserting an engagement member ("first engagement member" in the claims) such as a bolt erected on the reinforcing plate 63 ("first A plate-shaped left connecting portion 91D in which a through hole is formed is provided, and an upper part of the right vertical portion 91A is an engaging member such as a bolt erected on the reinforcing plate 64 (the second engaging portion in the claims) There is provided a plate-like right connecting portion 91E in which an oblong through hole (a "second through hole" in the claims) having a major axis in the vertical direction, through which the connecting member is inserted, is formed.

  In the front view of the machine body, the rear suspension 92 is a left vertical portion 92A extending in the vertical direction, a right vertical portion 92B extending in the vertical direction, a lower portion of the left vertical portion 92A and a lower portion of the right vertical portion 92B. Are formed from a horizontal portion 92C extending in the left-right direction connecting the two.

  A plate-like left connecting portion 92D having a circular through hole for inserting an engaging member such as a bolt erected on the reinforcing plate 63 is provided on the upper portion of the left vertical portion 92A, and the right vertical portion 92A In the upper part of the plate, there is provided a plate-like right connecting portion 92E in which an oblong through hole having a major axis in the vertical direction for inserting an engaging member such as a bolt erected on the reinforcing plate 64 is formed There is.

  As a result, after fixing the left connection portion 91D of the front suspension portion 91 and the left connection portion 92D of the rear suspension portion 92 respectively to the engaging members provided upright on the reinforcement plate 63, the standing members are erected on the reinforcement plate 64. The right connecting part 91E of the front hanging part 91 and the right connecting part 92E of the rear hanging part 92 are engaged with each other while moving in the vertical direction, and the hanging member 90 is formed as a reinforcing plate 63. And the reinforcing plate 64 can be easily attached and detached.

  A plate-like front connecting portion 94 for fixing the front wall of the urea water tank 28 is provided substantially at the middle in the left-right direction of the horizontal portion 91C of the front suspension portion 91. The through holes are formed at predetermined intervals in the vertical direction and through which fastening means such as bolts are inserted.

  A plate-shaped rear side connection portion 95 for fixing the rear wall of the urea water tank 28 is provided substantially in the middle in the left and right direction of the horizontal portion 92C of the rear side suspension portion 92. A through hole is formed at a central portion of the through hole for inserting fastening means such as a bolt at a predetermined interval in the vertical direction. Thereby, the urea water tank 28 can be reliably fixed to the suspension member 90. In addition, since the hanging member 90 can be easily attached and detached between the reinforcing plate 63 and the reinforcing plate 64, the urea aqueous solution tank 28 may be attached to and detached from between the reinforcing plate 63 and the reinforcing plate 64 together with the suspending member 90. it can.

  The vertical length of the left vertical portion 92A of the rear side hanging portion 92 is equal to the vertical length of the left vertical portion 91A of the front side hanging portion 91, and the right side of the rear side hanging portion 92 is formed. The vertical length of the vertical portion 92B is longer than the vertical length of the right vertical portion 91B of the front hanging portion 91. Thereby, the urea aqueous solution tank 28 can be suspended between the right bottom wall 7G of the glen tank 7 and the fixed cover 67 via the suspending member 90 while maintaining the horizontal posture without tilting in the longitudinal direction.

  The connecting portion 93 is provided with two support members 96 formed in a hook shape for supporting the plurality of hoses 27 at predetermined intervals in the front-rear direction. Thereby, it is possible to prevent the hose 27 from hanging down. The two hoses 27 are hoses (a "first hose" in claims) 27A for supplying urea water, and the two hoses 27 are hoses for supplying radiator water circulated through the engine E (claims) 'Second hose') 27B.

  The hose 27A and the hose 27B extend rearward from the aqueous urea tank 28 in parallel in the vertical direction, and then curve to extend the rear surface of the rear wall 7D of the glen tank 7 to the left, and then curve Then, the left surface of the left bottom wall 7F of the front glen tank 7 is extended to the front side to reach the supply device 26. As a result, when the gren tank 7 is moved from the storage position to the open position and from the open position to the storage position, the hose 27 can be easily bent to move the gren tank 7 smoothly. Further, the urea water supplied to the hose 27A is heated by the radiator water heated by the engine E supplied to the hose 27B, and freezing of the urea water can be prevented.

  As shown in FIGS. 15 and 16, a radiator 80 is provided on the right side of the engine E mounted in the engine compartment 6, and a fan 81 is provided between the engine E and the radiator 80. The fan 81 is supported by a rotating shaft 83 supported by a connecting member 82A which is provided on two arms 82 provided on the rear side of the radiator cover.

  A pulley 84A and a pulley 85A are provided on the left side of the rotating shaft 83. A pulley 84B is provided on the right side of the counter shaft 77 of the engine E, and a pulley 85B is provided on the right side of the output shaft 78 of the engine E. A belt 84C is wound around the pulleys 84A and 84B, and a belt 85C is wound around the pulleys 85A and 85B.

  The tension of the belt 84C is switched between a tensioned state and a relaxed state by a tension arm 84D provided with a roller at its tip, and the tension of the belt 85C is brought into a tensioned state and a slackened by a tension arm 85D provided with a roller at its tip Can be switched to

  The base of the tension arm 84D is fixed to a laterally extending rotary shaft 84E rotatably fixed to the connecting member 82A, and the base of the tension arm 85D is horizontally fixed to the connecting member 82A. It is being fixed to the rotating shaft 85E which extends.

  The base of the arm 84F extending forward and backward is fixed to the rotating shaft 84E, and the base of the arm 85F extending upward and backward is fixed to the rotating shaft 85E. The tip of the arm 84F and the tip of the arm 85F The parts are connected by a connecting member 86 made of round steel or the like. Thus, the tension arm 85D can be rotated in conjunction with the rotation of the tension arm 84D.

  The base of the operating arm 87 extending upward and backward is fixed to the rotating shaft 85E, and the tip of the operating arm 87 is a crank provided on the output shaft 88A of the tension arm motor 88 via a spring and a rod. It is connected to an arm 89. Thus, the tension arm 84D is rotated by one motor 88 to switch the tension of the belt 84C to the tension state, the intermediate state between tension and relaxation, and the relaxation state, and the tension arm 85D is rotated to rotate the belt 85C. The tension can be switched to the tension state, an intermediate state between tension and relaxation, and the relaxation state to switch the fan 81 to the normal rotation state, the stop state, and the reverse rotation state.

  The motor 88 is operated by a controller provided in the steering unit 5, and the output shaft 88A of the motor 88 is pivoted to the neutral position when the measurement value of the sensor 75 is below the temperature at which the urea water freezes. . As a result, the fan 81 is stopped, and the urea water can be warmed by the radiator water heated by the engine E to prevent freezing of the urea water. On the other hand, when the measured value of the sensor 75 is higher than the temperature at which the urea water freezes, the output shaft 88A of the motor 88 rotates clockwise and counterclockwise at constant time intervals in axial view of the output shaft 88A. Rotate. As a result, the fan 81 switches between the normal rotation state and the reverse rotation state at constant time intervals to prevent overheating of the engine E and efficiently remove the deposits attached to the engine compartment cover 6A of the engine compartment 6 it can.

  That is, when the output shaft 88A of the motor 88 is in the neutral position, the tension arm 84D is rotated to set the tension of the belt 84C to an intermediate state, and the tension arm 85D is rotated to rotate the tension of the belt 85C. Make it As a result, the fan 81 is stopped, the temperature in the engine compartment 6 rises, and the temperature of the radiator water supplied to the hose 27B rises, and is supplied to the hose 27A juxtaposed to the hose 27B. The urea water is heated to prevent freezing of the urea water.

  When the output shaft 88A of the motor 88 rotates from the neutral position to the clock position in the axial view of the output shaft 88A, the rotational shaft 85E rotates in the clockwise direction in the axial view of the output shaft 85E. The leading end of the tension arm 85D moves in a direction away from the belt 85C, and the tension of the belt 85C is relaxed. On the other hand, when the rotating shaft 85E rotates in the clockwise direction, the leading end of the tension arm 84D moves toward the belt 85C, and the tension of the belt 84C becomes tense. As a result, the fan 81 rotates in the normal direction, which is the clockwise direction, to be in the positive rotation state in the axial center view of the rotating shaft 83, and the inside of the engine room 6 from the outside through the engine room cover 6A The air can be sucked into the radiator 80 to cool the radiator 80, the engine E, and the like.

  Furthermore, when the output shaft 88A of the motor 88 rotates from the neutral position to the counterclockwise position in the axial view of the output shaft 88A, the rotational shaft 85E rotates in the counterclockwise direction in the axial view of the output shaft 85E. As a result, the leading end of the tension arm 85D moves toward the belt 85C, and the tension of the belt 85C is tightened. On the other hand, when the rotating shaft 85E rotates counterclockwise, the tip end of the tension arm 84D moves in the direction of separating from the belt 85C, and the tension of the belt 84C is relaxed. As a result, the fan 81 rotates in the reverse direction, which is a counterclockwise direction, into the reverse rotation state in the axial view of the rotating shaft 83, and the air in the engine room 6 through the engine room cover 6A of the engine room 6 It can be discharged to the outside to remove deposits such as scraps adhering to the engine compartment cover 6A.

Reference Signs List 1 airframe frame 2 traveling device 2A crawler 3 reaper 4 threshing device 5 control unit 6 engine room 7 grain tank 7B right wall 7D back wall 7G right bottom wall 20 exhaust purification device 21 DPF
22 SCR catalyst 23 connecting pipe 24 injector 26 supply device 27A hose (first hose)
27B hose (second hose)
28 urea water tank 28A water supply port 28B drain port 55 mudguard cover 63 reinforcing plate (first reinforcing plate)
64 Reinforcement plate (2nd reinforcement plate)
67 Fixed cover (first cover)
68 Detachable cover (second cover)
70 container 71 pedestal 75 sensor 76 battery 80 radiator 81 fan 90 hanging member 91 front hanging part 91D left connecting part 91E right connecting part 92 rear side hanging part 92D left connecting part 92E right connecting part 93 connecting part 96 supporting member E engine

Claims (8)

A traveling device (2) is provided below the fuselage frame (1), and a harvesting device (3) for harvesting the grain is provided on the front side of the fuselage frame (1). There is provided a threshing device (4) for threshing the cocoons, a control unit (5) on which the operator boarding is provided on the rear right side of the reaper (3), and an engine (E) is built in the lower portion of the control unit (5). In the combine having an engine room (6) and a gren tank (7) for storing the threshed grains on the rear side of the operation section (5),
A mudguard cover (55) extending in the front-rear direction is provided above the crawler (2A) of the traveling device (2);
An exhaust gas purification device (20) for purifying exhaust gas of the engine (E) is provided between the threshing device (4) and the grain tank (7), and the exhaust gas purification device (20) comprises the engine (E) DPF (21) for removing particulate matter in exhaust gas discharged from exhaust gas, and SCR catalyst for reducing and purifying nitrogen oxides in exhaust gas after passing through the DPF (21) with ammonia generated from urea water With (22),
An injector (24) for injecting urea water is provided in a connecting pipe (23) connecting the outlet of the DPF (21) and the inlet of the SCR catalyst (22), and urea water is supplied to the injector (24) A supply device (26) for supplying water and a urea water tank (28) for storing urea water supplied by the supply device (26);
The urea water tank (28) is disposed in the space below the right bottom wall (7G) of the gren tank (7), and the water supply port (28A) of the urea water tank (28) The combine is disposed near the rear wall (7D) of the tank (7), and the outlet (28B) of the urea aqueous solution tank (28) is disposed above the outside of the mudguard cover (55).   The combine according to claim 1, wherein a pedestal (71) for mounting a container (70) storing urea aqueous solution for replenishment is provided on the front side of the urea aqueous solution tank (28).   The combine according to claim 1 or 2, wherein a battery (76) for supplying power to the supply device (26) is provided on the front side of the urea aqueous solution tank (28). A radiator (80) is provided outside the engine (E) in the engine room (6), and a fan (81) is provided between the engine (E) and the radiator (80).
The fan (81) is switched between a normal rotation state in which external air is sucked into the engine room (6), a rotation stop state, and a reverse rotation state in which the air in the engine room (6) is discharged to the outside. age,
When the temperature of urea water detected by the sensor (75) provided in the urea water tank (28) is lower than a predetermined temperature, the fan (81) is stopped rotating.
If the temperature of the aqueous urea solution detected by the sensor (75) is higher than a predetermined temperature, switching between the forward rotation state and the reverse rotation state of the fan (81) is repeated,
The first hose (27A) through which the urea water passes and the second hose (27B) through which the radiator water passes are disposed in parallel between the supply device (26) and the urea water tank (28). The combine according to any one of ~ 3. A first cover (67) extending downward from the lower side of the right wall (7B) of the glen tank (7);
The combine according to any one of claims 1 to 4, wherein the urea aqueous solution tank (28) is disposed between the right bottom wall (7G) of the glen tank (7) and the first cover (67). A second cover (68) is detachably provided under the first cover (67),
The second cover (68) has a first extension extending downward from the lower end of the first cover (67), and a second extension extending downward to the left from the lower end of the first extension. An extension portion and a third extension portion extending from the lower end portion of the second extension portion to the lower portion of the right bottom wall 7G,
The combine according to claim 5, wherein a right side wall and a bottom wall of the urea aqueous solution tank (28) are covered with the second cover (68). The urea aqueous solution tank (28) is supported via a hanging member (90) with respect to the right bottom wall (7G) and the first cover (67),
A substantially U-shaped front suspension portion (91) for supporting the front portion of the urea water tank (28) and a substantially U for supporting the rear portion of the urea water tank (28) And a connecting portion (93) for connecting the left portion of the front suspending portion (91) and the rear suspending portion (92).
An engagement member is provided at a site where the left connection portion (91D) of the front suspension portion (91) and the left connection portion (92D) of the rear suspension portion (92) of the right bottom wall (7G) are engaged. Provide a first reinforced plate (63)
An engagement member is provided at a portion where the right connection portion (91E) of the front suspension portion (91) and the right connection portion (92E) of the rear suspension portion (92) of the first cover (67) are engaged. The combine according to claim 5 or 6, further comprising a second reinforcing plate (64).   The combine according to claim 7, wherein a plurality of substantially hook-shaped support members (96) are provided on the connection portion (93) at intervals in the front-rear direction.

Images