JP2016188560A - Working machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a working machine capable of efficiently cooling an intercooler with outside air taken into an engine room while preventing rising dust from being sucked together with the outside air taken into the engine room during working and travelling.SOLUTION: A working machine includes: a machine body; a cabin mounted on the machine body; travel gears disposed at right and left sides of the machine body; a boom provided at a side of the cabin; a working tool attached to the boom; an engine mounted in a rear part of the machine body; an upper cover provided above the engine having an outside air inlet; and an intercooler provided above the engine and below the upper cover.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a working machine such as a compact truck loader and a skid steer loader.

Conventionally, the technique of patent document 1 is disclosed as a working machine provided with the intercooler for cooling the intake air to an engine.
In the working machine disclosed in Patent Literature 1, an intercooler that cools intake air to the engine is disposed in an engine room that houses the engine. More specifically, a radiator is disposed in front of the engine, and an intercooler is disposed in front of the radiator. And by the effect | action of the fan driven by an engine, outside air is attracted | sucked in an engine room from a front grill, and this outside air is sent toward an engine, being used for cooling of an intercooler.

JP 2012-201159 A

  However, since the working machine disclosed in Patent Document 1 is configured to suck outside air from the front grille into the engine room, dust or the like that has risen during work or traveling is sucked into the engine room. There was a problem. Further, since it is necessary to secure a space for installing the intercooler in front of the engine, there is a problem that the total length (front-rear length) of the work machine increases.

  The present invention has been made to solve such problems of the prior art, and while the intercooler is efficiently cooled by the outside air taken into the engine room, the outside air is brought up during work and traveling. It is an object of the present invention to provide a working machine capable of preventing dust and the like from being sucked into an engine room. It is another object of the present invention to provide a work machine that does not increase the overall length of the work machine due to the installation of an intercooler.

In order to solve the above problems, the present invention has taken the following technical means.
A work machine according to a first aspect of the present invention includes an airframe, a cabin mounted on the airframe, traveling devices disposed on the right and left sides of the airframe, a boom provided on a side of the cabin, A work tool mounted on the boom, an engine mounted on the rear part of the fuselage, an upper cover provided above the engine and having an outside air introduction part, and above the engine and below the upper cover And an intercooler provided.

A working machine according to a second aspect of the invention includes a purification device that purifies nitrogen oxides contained in exhaust from the engine, the purification device is provided above the engine, and the intercooler includes the purification device. It is provided above the device.
The working machine of the invention according to claim 3 includes a particle removing device capable of capturing particulates contained in exhaust from the engine, and the particle removing device is provided in front of the purification device and in front of the engine, The intercooler is provided behind and above the particle removing device.

According to a fourth aspect of the present invention, there is provided a work machine including a radiator provided behind the engine, and the intercooler is provided in front of and above the radiator.
A working machine according to a fifth aspect of the present invention includes a capacitor provided above the engine, and the intercooler is provided in front of the capacitor.

According to the present invention, the outside air taken in from the outside air introduction portion of the upper cover provided above the engine is used to cool the intercooler provided above the engine and below the upper cover, to the engine. Can send. Therefore, while the intercooler is efficiently cooled by the outside air taken into the engine room that houses the engine, it is possible to prevent the dust and the like that has risen during work and travel from being sucked into the engine room by taking in the outside air. Moreover, since the intercooler is provided above the engine and below the upper cover, the installation of the intercooler does not increase the overall length of the work implement.

It is a perspective view of an airframe. It is a side view inside an airframe. It is a top view inside an airframe. It is the perspective view which looked at the engine, the purification apparatus, and the particle removal apparatus from diagonally forward left. It is the perspective view which looked at an intercooler, a radiator, an engine, an air cooler, etc. from the diagonally left front lower part. It is a perspective view of a machine body rear part. It is a side view of the periphery of an intercooler. It is a block diagram which shows the flow of air. It is a side view of a working machine. It is a front view of a working machine. It is a top view of a working machine. It is a side view of a working machine provided with a wheel type traveling device.

Hereinafter, an embodiment of a working machine according to the present invention will be described with reference to the drawings.
FIG. 9 shows a side view of the working machine 1 according to the present invention. FIG. 10 shows a front view of the work machine 1. FIG. 11 is a plan view of the work machine 1.
9 to 11 show a compact truck loader as an example of a working machine. However, the working machine according to the present invention is not limited to a compact truck loader, and may be another type of loader working machine such as a skid steer loader. Moreover, a working machine other than the loader working machine may be used.

The work machine 1 includes a body (vehicle body) 2, a cabin 3, a work device 4, and a travel device 5.
A cabin 3 is mounted on the body 2. A driver's seat 6 is provided at the rear of the cabin 3. In the embodiment of the present invention, the front side (left side in FIG. 9) of the driver seated on the driver's seat 6 of the work machine 1 is front, the rear side (right side in FIG. 9) is rearward, and the left side of the driver (FIG. 9 on the left side and the right side of the driver (the back side in FIG. 9) as the right side. The horizontal direction, which is a direction orthogonal to the front-rear direction, will be described as the body width direction. As shown in FIG. 10, the direction from the center part of the airframe 2 toward the right part or the left part will be described as the outside of the airframe. In other words, the outward direction of the body is the direction of the body width and away from the body 2. The direction opposite to the outside of the aircraft will be described as the inside of the aircraft. In other words, the in-machine direction is the width direction of the machine body and the direction approaching the machine body 2.

As shown in FIG. 1, the airframe 2 includes a right side frame portion 8, a left side frame portion 9, a front frame portion 10, a bottom frame portion 11, and an upper frame portion 12.
The right side frame portion 8 constitutes the right portion of the airframe 2. The left side frame portion 9 constitutes the left portion of the airframe 2. The front frame portion 10 constitutes the front portion of the body 2 and connects the front portions of the right side frame portion 8 and the left side frame portion 9 to each other. The bottom frame portion 11 constitutes the bottom portion of the airframe 2 and connects the lower portions of the right side frame portion 8 and the left side frame portion 9 to each other. The upper frame portion 12 constitutes an upper portion near the rear portion of the machine body 2, and connects the upper portions near the rear portion of the right side frame portion 8 and the left side frame portion 9.

  The side frame portions 8 and 9 have a main frame 13, a track frame 14, a motor attachment portion 15, and a support frame 16. The track frame 14 is attached to the lower part of the outer surface of the main frame 13 via an attachment member 17. The motor mounting portion 15 is provided at an upper portion near the rear portion of the outer surface of the main frame 13. The support frame 16 is attached to the rear part of the main frame 13.

The support frame 16 includes an inner wall (first wall) 18, an outer wall (second wall) 19, and a front wall (fourth wall).
20 and a rear wall (third wall) 21. The inner wall 18 and the outer wall 19 are provided to face each other with an interval in the body width direction. The outer wall 19 is located outside the body of the inner wall 18. The front wall 20 is provided in the middle part of the main frame 13 in the body width direction, so that it protrudes not only inside the body of the main frame 13 but also outside the body. A portion of the front wall 20 protruding outward from the machine body constitutes a fender that covers the rear portion of the traveling device 5. The front wall 20 connects the front part of the inner wall 18 and the front part of the outer wall 19. The rear wall 21 connects the rear part of the inner wall 18 and the rear part of the outer wall 19.

The upper frame portion 12 has a first plate member 12A and a second plate member 12B. The first plate member 12A connects the upper part of the right inner wall 18 and the upper part of the left inner wall 18. The first plate member 12 </ b> A has an annular edge that forms the opening 12 </ b> C, and is provided behind the cabin 3. The annular edge forming the opening 12C has a substantially rectangular shape.
The second plate member 12B is a plate member extending rearward from the left rear end and the right rear end of the first plate member 12A. The left second plate member 12 </ b> B extends rearward along the left inner wall 18, and the outer side of the body is connected to the left inner wall 18. The right second plate member 12 </ b> B extends rearward along the right inner wall 18, and the outer side of the body is connected to the right inner wall 18. The second plate member 12B on the left side and the second plate member 12B on the right side are inclined downward so as to be lowered toward the rear.

As shown in FIGS. 2 and 10, the upper cover 201 is attached so as to cover the upper portion of the opening 12 </ b> C of the upper frame portion 12.
As shown in FIG. 3, the inner walls 18 of the right and left support frames 16 form a right side wall and a left side wall of the engine room 202. As shown in FIG. 2, an upper cover 201 and an upper rear cover 203 described later are provided above the inner wall 18.

As shown in FIGS. 8 to 10, the working device 4 is attached to the machine body 2. The work device 4 includes a boom 58 and a work tool 59. In the present embodiment, a bucket is provided as the work tool 59.
The boom 58 is provided on the side of the machine body 2 and on the side of the cabin 3 so as to be swingable up and down. Further, the booms 58 are provided on the right side and the left side of the cabin 3, respectively. For convenience of explanation, the boom 58 provided on the left side is referred to as a left boom 58L, and the boom 58 provided on the right side is referred to as a right boom 58R. The inner wall 18 is provided on the side of the boom 58 and on the side of the aircraft body. The outer wall 19 is provided on the side of the boom 62 and on the side opposite to the inner wall 18 (outside the fuselage). A bucket as the work tool 59 is attached to the boom 58. More specifically, the bucket 59 is provided so that the front end (front end) of the boom 58 can swing up and down.

The right boom 58R and the left boom 58L are connected to each other by connecting members 64 at the front and the rear. The rear portions (base portions) of the booms 58R and 58L are supported so as to be swingable up and down with respect to the upper portion of the body 2 near the rear portion. When the booms 58R and 58L swing up and down, the front ends of the booms 58R and 58L move up and down in front of the airframe 2.
Specifically, the rear portions of the booms 58 </ b> R and 58 </ b> L are connected to an upper portion near the rear portion of the machine body 2 via a lift link 60 and a control link 61. The lift link 60 is arranged vertically. The upper portion of the lift link 60 is connected to the rear portions of the booms 58R and 58L behind the rear connection member 64 via the first pivot shaft 66. The lower portion of the lift link 60 is inserted into the support frame 16 (between the inner wall 18 and the outer wall 19) and is pivotally supported via a second pivot shaft 67. Thereby, the lift link 60 can swing so as to move back and forth. The control link 61 is arranged in the front-rear direction. The front portion of the control link 61 is pivotally supported by a link attachment portion 41 provided between the inner wall 18 and the outer wall 19 of the support frame 16 via a fifth pivot shaft 71. The rear portion of the control link 61 is connected to the vicinity of the base end portions of the booms 58R and 58L via the sixth pivot shaft 72. Thereby, the control link 61 can swing from a substantially horizontal posture shown in FIG. 8 to a rising posture in which the rear part rises.

A boom cylinder 62 is provided between the bases of the booms 58 </ b> R and 58 </ b> L and the rear lower part of the body 2. The boom cylinder 62 is a double-acting hydraulic cylinder. By extending and retracting the boom cylinder 62, the booms 58R and 58L swing up and down.
The cylinder tube of the boom cylinder 62 is provided between the inner wall 18 and the outer wall 19. Therefore, the inner wall 18 is provided on the side of the boom cylinder 62 and on the side of the body. Further, the outer wall 19 is provided on the side of the boom cylinder 62 and on the side opposite to the inner wall 18 (outside of the body).

The lower part of the cylinder tube of the boom cylinder 62 is connected to the support frame 16 via the fourth pivot shaft 70. The tip of the cylinder rod of the boom cylinder 62 is connected to the booms 58R and 58L via the third pivot shaft 69.
The second pivot shaft 67 is located near the upper part of the rear end of the body 2. The third pivot shaft 69 is located on the opposite side of the first pivot shaft 66 with the connecting member 64 at the rear portion interposed therebetween. The fourth pivot shaft 70 is located near the lower part of the rear end of the body 2 and slightly forward of the second pivot shaft 67. When viewed from the side, the boom cylinder 62 intersects the control link 61.

  In the lowest position of the booms 58R and 58L to which the work tool 59 is grounded as shown in FIG. 8, the first pivot shaft 66 is above and slightly behind the second pivot shaft 67, and the lift link 60 is Inclined posture. Further, the sixth pivot shaft 72 is slightly higher than the fifth pivot shaft 71, and the control link 61 is in a tilted posture that rises rearward. Further, the third pivot shaft 69 is lower than the first pivot shaft 66 and higher than the sixth pivot shaft 72, and the booms 58R and 58L are inclined forward and downward. The boom cylinder 62 intersects the approximate center of the control link 61 in the front-rear direction.

  The booms 58R, 58L, the lift link 60, and the control link 61 have a four-joint link structure having the second pivot shaft 67, the first pivot shaft 66, the fifth pivot shaft 71, and the sixth pivot shaft 72 as nodes. It has become. By extending the boom cylinder 62, the booms 58R and 58L rotate upward with the first pivot shaft 66 as a fulcrum. The control link 61 rises from the forward tilt posture shown in FIG. 8 as the boom 58R, 58L pivots upward.

A mounting bracket 204 is pivotally supported at the distal ends of the booms 58R and 58L so as to be rotatable about a horizontal axis. A work tool 59 is mounted on the mounting bracket 204.
A bucket cylinder 63 is interposed between the mounting bracket 204 and a midway portion near the front portion of the boom 58. The work tool cylinder 63 is a double-acting hydraulic cylinder. By the expansion and contraction of the work tool cylinder 63, a bucket as one of the work tools 59 swings (squeeze / dump operation).

In addition to the bucket, the work tool 59 is a hydraulic crusher, a hydraulic breaker, an angle bloom, an earth auger, a pallet fork, a sweeper, a mower, a snow blower, or the like. The work tool 59 is detachable from the mounting bracket 204. When the work tool 59 is removed and another work tool 59 is attached to the mounting bracket 204, various work becomes possible.
The traveling device 5 is provided on the right side and the left side of the body 2.

  The traveling device 5 is a crawler traveling device, and includes a drive wheel 53, driven wheels 54 </ b> F and 54 </ b> R, a roller wheel 57, and a crawler belt 56. The driven wheel includes a front driven wheel 54F and a rear driven wheel 54R. The drive wheel 53 is disposed near the upper part and the rear part between the front driven wheel 54F and the rear driven wheel 54R. A plurality of rollers 57 are provided between the front driven wheel 54F and the rear driven wheel 54R. The crawler belt 56 has an endless belt shape and is wound around the driven wheels 54 </ b> F and 54 </ b> R, the driving wheel 53, and the wheel 57.

  The driven wheels 54F and 54R and the roller wheel 57 are attached to the track frame 14 so as to be rotatable around the horizontal axis. The drive wheels 53 are attached to a rotating drum of a hydraulically driven travel motor 55 attached to the track frame 14. The travel motor 55 is attached to the motor attachment portion 15. The drive wheel 53 can be rotated around the horizontal axis by driving the travel motor 55. Thereby, the crawler belt 56 is circulated in the circumferential direction, and the work machine 1 moves forward or backward. The traveling device 5 may be a wheel-type traveling device 5 as shown in FIG.

As shown in FIG. 3, a fuel tank 83 and a hydraulic oil tank 84 are mounted on the bottom frame portion 11 of the machine body 2. The fuel tank 83 is a tank that stores the fuel of the engine 73, and is disposed on the left side of the front part of the airframe 2. The hydraulic oil tank 84 is a tank that stores hydraulic oil that operates the hydraulic actuator, and is disposed on the right side of the front portion of the machine body 2. A control valve 205 is disposed behind the hydraulic oil tank 84.

An engine room 202 that houses the engine 73 is provided at the rear of the machine body 2. As shown in FIG. 2, the upper part of the engine room 202 is covered with an upper cover 201 and an upper rear cover 203. The upper cover 201 is provided above the engine 73. The rear of the engine room 202 is covered with a bonnet cover 77.
The upper cover 201 is attached to the upper surface of the first plate member 12A, and covers the opening 12C of the first plate member 12A (the annular edge forming the opening 12C). The upper cover 201 has a peripheral edge part 201A, a rising part 201B, and an upper surface part 201C. The peripheral edge 201A is formed in a substantially rectangular frame shape, and is fixed around the opening 12C of the first plate member 12A by bolts. The rising portion 201B rises upward from the inner periphery of the peripheral edge portion 201A, and is connected to the upper surface portion 201C at the upper end portion. As shown in FIG. 2, the upper surface portion 201C is disposed above the opening portion 12C of the first plate member 12A with a space from the opening portion 12C. As shown in FIG. 10, the upper surface portion 201 </ b> C has an annular edge portion that forms an opening that becomes the outside air introduction portion 206. The annular edge forming the opening is substantially rectangular. The outside air introduction unit 206 has a large number of small holes (not shown). As shown in FIG. 10, an exhaust pipe 93 </ b> A of the purification device 93 protrudes to the left of the outside air introduction part 206 of the upper cover 201. The exhaust pipe 93A extends upward and obliquely rearward to the left.

  As shown in FIGS. 2, 6, and 7, the upper rear cover 203 is provided at the upper part of the inner wall 18 of the machine body 2 and behind the first plate member 12 </ b> A. Specifically, an upper rear cover 203 is provided across the second plate member 12B on the left side and the second plate member 12B on the right side. That is, the upper rear cover 203 is disposed so as to close the space between the second plate member 12B on the left side and the second plate member 12B on the right side. The upper rear cover 203 is inclined downward so as to be lowered toward the rear. As a result, it is easy to ensure the rear view of the driver seated on the driver's seat 6 in the cabin 2. In FIG. 6, the booms 58R and 58L, the lift link 60, and the control link 61 are omitted.

  As shown in FIG. 7, a substantially J-shaped support body 203B is provided on the right and left sides of the front part of the lower surface of the upper rear cover 203 in a side view. The front end portion of the support body 203B is pivotally supported by a pair of pivot shafts 220 attached to the lower surface of the first plate member 12A. Accordingly, the upper rear cover 203 can rotate the rear portion upward with the pivot shaft 220 as a fulcrum. By rotating the rear part of the upper rear cover 203 upward, the upper part near the rear part of the engine room 202 can be opened. The upper rear cover 203 has an edge portion that forms the opening 203A. This edge is annular and has a rectangular shape in plan view.

  The bonnet cover 77 has an annular edge that forms the opening 77A. The opening 77A is a vent hole for discharging the air in the engine room 202 to the outside. The right end of the bonnet cover 77 is pivotally supported on the rear wall 21 on the right side of the support frame 16 via a hinge (not shown). By rotating the bonnet cover 77 backward with the hinge as a fulcrum, the rear portion of the engine room 202 can be opened.

As shown in FIGS. 2 to 5, the engine room 202 includes an engine 73, an oil cooler 208, a radiator 74, a condenser 207, a compressor 209, an intercooler 210, an air cleaner 211, a particle removal device 82, a purification device 93, a battery 75, and the like. Is housed.
In the present embodiment, the engine 73 uses a common rail type diesel engine. The engine 73 is placed vertically on the bottom frame portion 11 of the machine body 2 via a vibration isolating rubber (not shown). A flywheel 213 is attached to the front portion of the engine 73.

  As shown in FIG. 2, a plurality of hydraulic pumps 78, 79, 80, 81 are provided in front of and behind the flywheel 213. In this embodiment, the hydraulic pump 78 is a traveling pump, the hydraulic pump 79 is a main pump, the hydraulic pump 80 is a sub pump, and the hydraulic pump 81 is a pilot pump. These hydraulic pumps 78, 79, 80, 81 supply the hydraulic oil in the hydraulic oil tank 84 to a predetermined hydraulic device via the control valve 205.

The travel pump 78 is a hydraulic pump that drives the travel motor 55 shown in FIG. The travel pump 78 is a variable displacement hydraulic pump that forms part of the hydrostatic continuously variable transmission together with the travel motor 55.
The main pump 79, the sub pump 80, and the pilot pump 81 are constant capacity type gear pumps. The main pump 79 is a hydraulic pump that drives a hydraulic actuator provided in the work device 4. The sub pump 80 is a hydraulic pump used for increasing the amount of hydraulic oil supplied to the hydraulic actuator. The pilot pump 81 is mainly used for supplying a control signal pressure.

  A cooling fan 76 is provided at the rear of the engine 73. A substantially cylindrical shroud 212 is provided around the cooling fan 76. The cooling fan 76 is rotated by driving the engine 73. By the rotation of the cooling fan 76, the air (outside air) outside the work machine 1 is taken into the engine room 202 from the outside air introduction part 206 of the upper cover 201 and the opening 203 A of the upper rear cover 203. The outside air taken into the engine room 202 is discharged from an opening 77 </ b> A formed in the bonnet cover 77.

  As shown in FIGS. 2, 3, and 5, a radiator 74 and an oil cooler 208 are provided behind the engine 73 and the shroud 212 and in front of the bonnet cover 77. The radiator 74 and the oil cooler 208 are accommodated in the casing 214 side by side in the body width direction. In the present embodiment, the radiator 74 is disposed on the left side, and the oil cooler 208 is disposed on the right side. The radiator 74 cools the cooling water supplied to the engine 73. The oil cooler 208 cools the hydraulic oil.

As shown in FIG. 3, a reserve tank 215 for the radiator 74 is provided on the right side of the oil cooler 208. A battery 75 is provided below the reserve tank 215.
The condenser 207 is located near the rear part above the engine 73 and is provided in front of the radiator 74 and the oil cooler 208. The capacitor 207 is arranged horizontally (substantially horizontally). The condenser 207 (condenser main body 207B) condenses the refrigerant of the air conditioner (not shown) arranged in the cabin 3.

  As shown in FIGS. 5 and 7, the capacitor 207 includes a frame-shaped frame 207 </ b> A and a capacitor body 207 </ b> B attached to the frame-shaped frame 207 </ b> A. The frame 207 </ b> A has a rectangular shape and is disposed on the outer side or the inner side of the edge portion that forms the opening 203 </ b> A of the upper rear cover 203. In the present embodiment, the frame 207A is disposed on the inner side of the edge portion that forms the opening 203A in plan view.

  The upper end of the frame 207A is connected to the vicinity of the edge forming the opening 203A, and is integrated with the upper rear cover 203. The capacitor main body 207B is inserted into the frame 207A from above or below the frame 207A, for example, and is attached to the lower portion of the frame 207A with a fixture 207C. The condenser 207 is cooled by outside air taken from the opening 203 </ b> A of the upper rear cover 203 by driving the cooling fan 76.

A compressor 209 is provided below the capacitor 207. The compressor 209 compresses the refrigerant of the air conditioner. The compressed refrigerant is condensed by the condenser 207.
As shown in FIGS. 2 and 3, an air cleaner 211 is provided to the right and above the engine 73. As shown in FIG. 5, the air cleaner 211 includes an intake pipe 211A and an exhaust pipe 211B. The intake pipe 211A opens in the engine room 202 in a diagonally downward left direction. As shown in FIG. 8, the exhaust pipe 211 </ b> B is connected to the intake pipe 210 </ b> A of the intercooler 210 via the supercharger 219.

As shown in FIG. 8, air (outside air) taken into the engine room 202 from the outside air introduction unit 206 is taken into the air cleaner 211 through the intake pipe 211A and removed, and then passed through the exhaust pipe 211B. It is supplied to the supercharger 219, compressed, and sent to the intercooler 210.
The intercooler 210 is provided above the engine 73 and the purification device 93 and behind and above the particle removal device 82. Further, the intercooler 210 is located in front of and above the oil cooler 208 and the radiator 74 and in front of the condenser 207.

  As shown in FIGS. 2 and 5 to 7, the intercooler 210 is disposed immediately below the upper surface portion 201 </ b> C of the upper cover 201. The intercooler 210 is disposed in a space 201D surrounded by the upper surface portion 201C of the upper cover 201 and the four rising portions 201B. The intercooler 210 is disposed horizontally (substantially horizontally) in the space 201D. Thereby, the height of space 201D can be made low and the increase in the height of the working machine 1 by installation of the intercooler 210 can be suppressed.

  The space 201 </ b> D is formed above the upper edge of the inner wall 18 of the support frame 16. Therefore, the intercooler 210 disposed in the space 201 </ b> D is generally positioned above the upper edge of the inner wall 18. That is, the intercooler 210 is provided at a high position. Thereby, the space for installing the purification apparatus 93 can be ensured between the engine 73 and the intercooler 21.

The upper surface portion 201C of the upper cover 201 and the upper surface of the intercooler 210 are inclined downward so as to be lowered toward the rear. As a result, it is easy to ensure the rear view of the driver seated on the driver's seat 6 in the cabin 2.
As shown in FIG. 5, an intake pipe 210 </ b> A and an extraction pipe 210 </ b> B are connected to the intercooler 210. The intake pipe 210 </ b> A and the extraction pipe 210 </ b> B extend downward from the rear portion of the intercooler 210. The intake pipe 210A is connected to the exhaust pipe 211B of the air cleaner 211 via a supercharger. As shown in FIG. 7, the extraction pipe 210 </ b> B is connected to the intake port of the engine 73. The intake pipe 210 </ b> A and the extraction pipe 210 </ b> B are composed of highly rigid pipes, and support the intercooler 210 in the space 201 </ b> D above the engine 73.

As shown in FIG. 8, the air discharged from the exhaust pipe 211B of the air cleaner 211 and passing through the supercharger and intake pipe 210A and introduced into the intercooler 210 is cooled by the intercooler 210 and then taken out. It is supplied to the engine 73 through 210B.
The particle removing device 82 captures fine particles containing harmful substances in the exhaust (exhaust gas) from the engine 73. In this embodiment, the particle removal apparatus 82 is comprised from DPF (Diesel Particulate Filter).

  As shown in FIGS. 4 and 5, the particle removing device 82 is provided in front of and below the purification device 93. Further, the particle removing device 82 is provided at a position near the upper part in front of the engine 73, and is connected to an exhaust manifold of the engine 73. As shown in FIG. 8, the exhaust from the engine 73 is removed from the exhaust port 82 </ b> B after the particulates are removed through the particle removing device 82, passes through the connection pipe 96, and is passed from the intake port 93 </ b> C to the purification device 93. be introduced.

The purification device 93 purifies nitrogen oxides (NO _x ) contained in the exhaust from the engine 73. In the present embodiment, the purification device 93 is composed of a catalyst case containing a catalyst for SCR (Selective Catalytic Reduction) (hereinafter referred to as SCR catalyst). The purification device (catalyst case) 93 constitutes a urea SCR system together with a urea water tank 94 and an SCR pump 95 described later. The purification device 93 is provided at an upper position near the front portion of the engine 73 and above and behind the particle removal device 82. The purification device 93 is connected to the particle removal device 82 via the connection pipe 96.

The connection pipe 96 that connects the purification device 93 and the particle removal device 82 connects the exhaust port 82B provided in the upper part of the particle removal device 82 and the intake port 93C provided in the front portion of the purification device 93. Yes. The connecting pipe 96 is provided above the particle removing device 82 and in front of the purification device 93.
As shown in FIG. 3, the urea water tank 94 is a tank that stores urea water, and is provided on the side (left side) and rear of the engine 73. The urea water tank 94 is connected to the purification device 93 via an SCR pump 95 and a hose (not shown). The urea water in the urea water tank 94 is sent to the purification device 93 by the SCR pump 95 and injected into the connection pipe 96. The urea water injected into the connecting pipe 96 is hydrolyzed at a high temperature by the exhaust of the engine 73 that has passed through the particle removing device 82. As a result, ammonia gas is generated, and the nitrogen gas in the exhaust of the engine 73 is reduced to nitrogen gas and water vapor by the ammonia gas. This reduction reaction is promoted by the SCR catalyst in the purification device (catalyst case) 93. The exhaust gas from the engine 73 thus purified is exhausted to the outside through the exhaust pipe 93A of the purification device 93 as shown in FIG.

As shown in FIG. 4, the purification device 93 is supported above the engine 73 by a support frame. In FIG. 4, the engine 73 shows only the outline for the sake of simplicity.
The support frame has a first support frame 216 and a second support frame 217.
The first support frame 216 has an upper support portion 216A and a front support portion 216B. The upper support portion 216A is provided above the engine 73 and below the intercooler 210. The front support portion 216 </ b> B is provided in front of the engine 73 and in the vicinity of the engine 73. The front support portion 216B extends downward from the front end portion of the upper support portion 216A. The upper support portion 216A and the front support portion 216B are integrally formed of a rigid material such as a steel material.

A purification device 93 is placed on the upper surface of the upper support portion 216A. The lower part of the purification device 93 is supported by a support leg 93B. The support leg 93B is fixed to the upper surface of the upper support portion 216A with a bolt.
The front support portion 216B has an upper portion 216C and a lower portion 216D. The upper portion 216C is located behind the particle removing device 82. The lower portion 216D is located below the particle removing device 82. The upper portion 216C extends downward from the front end portion of the upper support portion 216A, and is curved forward as it goes downward. The lower portion 216D extends downward from the lower end portion of the upper support portion 216A. As a result, the upper part 216C is located rearward (closer to the engine 73) than the lower part 216D. The particle removing device 82 is arranged in front of the engine 73 and in the vicinity of the engine 73 by being arranged in front of the upper portion 216C and in the vicinity of the upper portion 216C.

The second support frame 217 is disposed below the first support frame 216 and behind the flywheel 213. The second support frame 217 integrally includes a cylindrical portion 217A, a flange portion 217B, a first upper plate portion 217C, and a second upper plate portion 217D.
The cylindrical portion 217A is disposed below the front support portion 216B of the first support frame 216. The flange portion 217B is formed in an annular shape at the front end portion of the cylindrical portion 217B. The flange portion 217B is fixed by a bolt B to a housing 218 (indicated by phantom lines in FIG. 4) that holds the periphery of the flywheel 213. The first upper plate portion 217C extends upward and forward from the upper portion of the cylindrical portion 217A. A support leg 82A that supports the particle removing device 82 from below is fixed to the upper surface of the first upper plate portion 217C by bolts (not shown). The second upper plate portion 217D extends rightward and leftward from the upper portion of the cylindrical portion 217A. Lower portions 216D of the first support frame 216 are fixed to the right side surface of the right second upper plate portion 217D and the left side surface of the left second upper plate portion 217D by bolts (not shown).

  As described above, the purification device 93 can be disposed above and near the engine 73 by the first support frame 216 and the second support frame 217. Further, the particle removing device 82 can be arranged in front of and in the vicinity of the engine 73. This makes it possible to reduce the space occupied by the engine 73, the particle removing device 82, and the purification device 93.

In the work machine having the configuration described above, the intercooler 210 is provided above the engine 73 and below the upper cover 201. The upper cover 201 is provided with an outside air introduction unit 206. Therefore, by driving the cooling fan 76, the outside air is taken into the engine room 202 that houses the engine 73 from the outside air introduction portion 206 of the upper cover 201 that covers the upper side of the engine 73, and the intercooler 210 is efficiently cooled by this outside air. can do. Further, it is not necessary to separately provide a cooling fan for cooling the intercooler 210.

In addition, since the outside air introduction part 206 is provided in the upper cover 201 above the engine 73, when outside air is taken into the engine room 202 that houses the engine 73, dust or the like that has risen during work or running is generated in the engine. The suction into the room 202 can be prevented.
Further, since the intercooler 210 is provided above the engine 73, the front and rear spaces due to the arrangement of the intercooler 210 can be omitted, so that the overall length (front-rear length) of the work implement 1 can be shortened.

An intercooler 210 is provided above the engine 73 and in front of and above the radiator 74. Therefore, the outside air introduced into the engine room 202 from the outside air introduction unit 206 and cooling the intercooler 210 can also be used for cooling the radiator 74.
Further, since the intercooler 210 is provided in front of the condenser 207, the flow of air that is taken in from the opening 203A of the upper rear cover 203 and cools the condenser 207 is not hindered by the intercooler 210.

  Although the present invention has been described above, it should be understood that the embodiments disclosed herein are illustrative and non-restrictive in every respect. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

DESCRIPTION OF SYMBOLS 1 Work machine 2 Machine body 3 Cabin 4 Work device 5 Traveling devices 58, 58R, 58L Boom 73 Engine 74 Radiator 82 Particle removal device 93 Purification device (catalyst case)
201 Upper cover 206 Outside air introduction part 207 Capacitor 210 Intercooler

Claims (5)

The aircraft,
A cabin mounted on the aircraft;
Traveling devices disposed on the right and left sides of the aircraft;
A boom provided on the side of the cabin;
A work implement mounted on the boom;
An engine mounted on the rear of the aircraft;
An upper cover provided above the engine and having an outside air introduction portion;
An intercooler provided above the engine and below the upper cover. A purification device for purifying nitrogen oxides contained in exhaust from the engine;
The purification device is provided above the engine,
The work machine according to claim 1, wherein the intercooler is provided above the purification device. Equipped with a particle removal device capable of capturing fine particles contained in exhaust from the engine;
The particle removing device is provided in front of the purification device and in front of the engine,
The work machine according to claim 1 or 2, wherein the intercooler is provided behind and above the particle removing device. A radiator provided behind the engine;
The work machine according to claim 1, wherein the intercooler is provided in front of and above the radiator. A capacitor provided above the engine;
The work machine according to claim 1, wherein the intercooler is provided in front of the capacitor.

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