JP7443273B2 - work equipment - Google Patents

Description

The present invention relates to a working machine such as a backhoe.

Conventionally, a working machine disclosed in Patent Document 1 has been known.
The work machine disclosed in Patent Document 1 includes an air conditioner body for air conditioning the interior of a cabin mounted on the machine body. The air conditioner itself is located below the driver's seat.

JP2020-2720A

If the air conditioner body is placed below the driver's seat as in the past, there is a problem in that the leg space for the operator is narrowed.
SUMMARY OF THE INVENTION In view of the above-mentioned problems, an object of the present invention is to provide a work machine that can increase the space under the feet of an operator.

A work machine according to one aspect of the present invention includes a machine body, a cabin mounted on the machine body, an air conditioner main body for air-conditioning the interior of the cabin, and a prime mover room accommodating a prime mover mounted on the machine body. The cabin protrudes rearward from the back of the cabin and is arranged above a wall part forming the prime mover room and covering an upper part of the prime mover with a space therebetween. The working machine has a plate member, and the air conditioner main body is installed on the upper surface side of the plate member, so that the air conditioner main body is disposed above the prime mover chamber and spaced apart from the prime mover chamber .

According to the above-mentioned working machine, by arranging the air conditioner body above the prime mover room, the space under the operator's feet can be made wider than when the air conditioner body is arranged below the driver's seat.

FIG. 2 is a schematic side view showing the overall configuration of the work machine. FIG. 3 is a schematic plan view of the working machine. FIG. 3 is a perspective view of the rotating frame. FIG. 3 is a perspective view of the fuselage. FIG. 3 is a perspective view of the fuselage. FIG. 3 is a perspective view of the fuselage. It is a right side view of the fuselage and cabin. It is a perspective view of the fuselage and cabin seen from the right rear. It is a perspective view of the fuselage and cabin seen from the left rear. It is a perspective view of the fuselage and cabin seen from the right rear. FIG. 3 is a front sectional view showing the arrangement of a fuel tank and a swing motor. It is a perspective view of a cabin and a pivot frame. FIG. 3 is a perspective view showing the arrangement of a fuel tank and a swing motor. It is a perspective view of a support base, an attachment frame, and a support frame. It is a perspective view showing the structure of a support stand. It is a perspective view showing the structure of a support stand. It is a right view of a fuel tank and a support stand. FIG. 3 is a front view showing how the swing motor is taken out. FIG. 2 is a perspective view showing a support structure for a fuel tank. FIG. 3 is a rear view showing the relationship between the fuel tank and the hose. It is a side sectional view of a cabin and a motor room. FIG. 3 is a perspective view of an installation part of the air conditioner main body. It is a perspective view of a duct structure, a compressor, a capacitor, etc. seen from behind. It is a perspective view of a duct structure, a capacitor, etc. seen from behind. It is a perspective view of a partition. It is a perspective view of a partition. It is a perspective view of a partition. FIG. 3 is a perspective view of the partition wall with the cover wall removed. FIG. 3 is a perspective view of the cover wall. It is a sectional view showing the structure of a duct structure. FIG. 2 is a perspective view showing the arrangement of refrigerant pipes. FIG. 2 is a perspective view showing the arrangement of refrigerant pipes. It is a perspective view showing the wiring of a refrigerant pipe line and a heat medium pipe line. FIG. 2 is a perspective view of the cabin, compressor, condenser, and receiver. FIG. 3 is a perspective view showing an intake structure and an exhaust structure. FIG. 3 is a diagram showing an intake structure and an exhaust structure. FIG. 3 is a plan sectional view of the intake structure.

An embodiment of the present invention will be described below with appropriate reference to the drawings.
FIG. 1 is a schematic side view showing the overall configuration of a working machine 1 according to the present embodiment. FIG. 2 is a schematic plan view of the working machine 1. In this embodiment, a backhoe, which is a swinging work machine, is exemplified as the work machine 1.
As shown in FIGS. 1 and 2, the work machine 1 includes a machine body (swivel base) 2, a traveling device 3, and a work device 4. Cabin 5 is mounted on fuselage 2. Inside the cabin 5, a driver's seat 6 is provided where an operator (driver) is seated. That is, the driver's seat 6 is surrounded by the cabin 5. The driver's seat 6 has a seat portion 6A where the operator sits (seated), and a backrest portion 6B where the operator's back is supported.

In this embodiment, the direction toward the front of the operator seated in the driver's seat 6 of the work equipment 1 (direction of arrow A1 in FIGS. 1 and 2) is the front (front of the machine), and the direction toward the rear of the operator (in FIG. , arrow A2 direction in FIG. 2) is the rear (rear of the fuselage), and arrow K1 direction in FIGS. 1 and 2 is the front-rear direction. Also, the direction toward the left side of the operator (back side in Figure 1, direction of arrow B1 in Figure 2) is defined as left, and the direction toward the right side of the operator (front side in Figure 1, direction of arrow B2 in Figure 2) is defined as right. explain.

Further, the horizontal direction, which is a direction orthogonal to the longitudinal direction (body longitudinal direction) K1, will be described as the body width direction K2 (see FIG. 2). The direction from the central part in the width direction of the fuselage 2 toward the right or left part will be described as outward in the width direction of the fuselage. That is, the outward direction in the machine body width direction is a direction away from the center of the machine body 2 in the width direction in the machine body width direction K2. The direction opposite to the outward direction in the machine body width direction will be described as the inward direction in the machine body width direction. That is, the inward direction in the machine body width direction is a direction that approaches the widthwise center of the machine body 2 in the machine body width direction K2.

In this embodiment, a configuration in which the driver's seat 6 is arranged inside the cabin 5 (cabin specification) will be described, but the invention is not limited to this, and the driver's seat 6 may be opened in the front-rear direction K1 and the fuselage width direction K2 to the outside. The driver's seat 6 may have a structure in which the upper part is covered with a roof (canopy) (canopy specification), or a structure in which the driver's seat 6 is opened to the outside in the longitudinal direction K1, the body width direction K2, and the upper part.

As shown in FIGS. 1 and 2, the traveling device 3 is a crawler type traveling device that supports the aircraft body 2 so that it can travel, and includes a traveling frame 3A and a first traveling device provided on the left side of the traveling frame 3A. 3L, and a second traveling device 3R provided on the right side of the traveling frame 3A. The first traveling device 3L and the second traveling device 3R are driven by a traveling motor M1 configured by a hydraulic motor (hydraulic actuator). In this embodiment, a crawler-type traveling device 3 is used, but the present invention is not limited to this, and a wheel-type traveling device or the like may be used. A dozer device 7 is attached to the front of the traveling device 3.

As shown in FIG. 1, the fuselage 2 is supported on a traveling device 3 via a swing bearing 8 so as to be able to turn around a swing axis X1, which is an axis extending in the vertical direction. As shown in FIG. 2, a cabin 5 is mounted on the left side of the fuselage 2 and near the front.
As shown in FIG. 1, the machine body 2 has a support bracket 9 and a swing bracket 10 for supporting the working device 4 at the front part. The support bracket 9 is provided to project forward from the body 2. The swing bracket 10 is attached to the front part of the support bracket 9 so as to be swingable around a vertical axis (an axis extending in the vertical direction).

As shown in FIG. 1, the working device 4 includes a boom 11, an arm 12, and a bucket 13. The base of the boom 11 is pivotally attached to the upper part of the swing bracket 10 so as to be rotatable around a horizontal axis (an axis extending in the body width direction K2). The arm 12 is pivotally attached to the distal end side of the boom 11 so as to be rotatable around a horizontal axis. The bucket 13 is provided on the tip side of the arm 12 so as to be capable of scooping and dumping operations. The scooping operation is an operation of swinging the bucket 13 in a direction closer to the boom 11, and is, for example, an operation when scooping earth and sand. Further, the dumping operation is an operation of swinging the bucket 13 in a direction away from the boom 11, and is an operation for dropping (discharging) scooped earth and sand, for example.

In place of or in addition to the bucket 13, the work machine 1 can be equipped with another work tool (hydraulic attachment) that can be driven by a hydraulic actuator. Examples of other working tools include a hydraulic breaker, a hydraulic crusher, an angle broom, an earth auger, a pallet fork, a sweeper, a mower, and a snow blower.
The swing bracket 10 is swingable by the expansion and contraction of the swing cylinder C1. The boom 11 can be rocked by expanding and contracting a boom cylinder C2. The arm 12 can swing by expanding and contracting the arm cylinder C3. The bucket 13 is capable of scooping and dumping operations by expanding and contracting the bucket cylinder C4. The swing cylinder C1, boom cylinder C2, arm cylinder C3, and bucket cylinder C4 are constituted by hydraulic cylinders (hydraulic actuators).

Next, with reference to FIG. 2 and the like, the arrangement and configuration of the main equipment mounted on the work machine 1 will be schematically described.
As shown in FIG. 2, a prime mover E1 is mounted at the rear of the aircraft body 2 (see FIG. 5). The prime mover E1 is a diesel engine. Note that the prime mover E1 may be a gasoline engine or an electric motor, or may be a hybrid type having an engine and an electric motor. A cooling fan 14 is attached to the right side of the prime mover E1. The cooling fan 14 is driven by the prime mover E1 and generates cooling air that flows from the right to the left, that is, from the outside of the aircraft body 2 toward the prime mover E1. Specifically, the cooling fan 14 is a suction type fan that sucks air (outside air) from the right side of the aircraft body 2 and flows it toward the prime mover E1 side.

A radiator 15, an oil cooler 16, and a fuel cooler 17 are arranged to the right of the cooling fan 14. The radiator 15 is a cooler that cools a coolant that cools the prime mover E1. The oil cooler 16 is a cooler that cools return hydraulic oil from a hydraulic actuator such as a hydraulic cylinder or a hydraulic motor. The fuel cooler 17 is a cooler that cools fuel. These coolers are cooled by cooling air drawn by the cooling fan 14.

A compressor 18 driven by the prime mover E1 is arranged in front of the right portion of the prime mover E1. The compressor 18 is a device that constitutes a part of the air conditioning system (air conditioner) installed in the working machine 1, and compresses the refrigerant (air conditioner gas) into a semi-liquid state.
A fuel tank (tank) 19 is arranged in front of the compressor 18, radiator 15, and oil cooler 16. The fuel tank 19 is a tank that stores fuel for the prime mover E1. A swing motor 20 is arranged below the left part of the fuel tank 19 (see FIG. 5). The swing motor 20 is configured by a hydraulic motor (hydraulic actuator). The turning motor 20 is a motor that turns (rotates) the aircraft body 2 around the turning axis X1. A swivel joint 21 is arranged at the position of the pivot axis X1. The swivel joint 21 is a rotary joint that allows hydraulic oil to be supplied and discharged between the hydraulic actuator on the traveling device 3 side and the control valve V1 on the aircraft body 2 side. The left side of the fuel tank 19, the swing motor 20, and the swivel joint 21 are arranged below the cabin 5.

A battery 22 is arranged in front of the fuel tank 19. The battery 22 is a storage battery that supplies power to electrical components installed in the working machine 1. A condenser 23 and a receiver 24, which form part of the air conditioning system, are arranged in front of the battery 22. The condenser 23 is a device that radiates heat from the refrigerant from the compressor 18 and liquefies it. Specifically, it is a cooler that cools the refrigerant that has been made into a semi-liquid state by the compressor 18 to further liquefy the refrigerant. In this embodiment, the capacitor 23 is an electric capacitor cooled by an electric fan. The receiver 24 is a device that stores the refrigerant liquefied by the condenser 23, separates the refrigerant that could not be liquefied by the condenser 23 from the liquefied refrigerant, and removes moisture and impurities.

A hydraulic pump 25 is attached to one side (left side) of the prime mover E1. The hydraulic pump 25 is driven by the power of the prime mover E1. This hydraulic pump 25 discharges hydraulic oil (pressure oil) that drives hydraulic actuators such as a hydraulic motor and a hydraulic cylinder that are installed in the working machine 1 . Further, the hydraulic pump 25 discharges pilot pressure for operating a hydraulic valve and hydraulic pressure for signals.

An exhaust gas purification device 26, an air cleaner 27, and a hydraulic oil tank 28 are arranged on the left side of the prime mover E1. The exhaust gas purification device 26 is a device that purifies exhaust gas discharged from the prime mover E1, and is, for example, a DPF (Diesel Particulate Filter). The air cleaner 27 is a device that cleans the air supplied to the prime mover E1. The hydraulic oil tank 28 is a tank that stores hydraulic oil. The exhaust gas purification device 26 and the air cleaner 27 are arranged above the hydraulic pump 25, and the air cleaner 27 is arranged to the left of the exhaust gas purification device 26. The hydraulic oil tank 28 is arranged below the driver's seat 6. Hydraulic oil is sent from the hydraulic oil tank 28 to the hydraulic pump 25.

A control valve V1 is arranged in front of the hydraulic oil tank 28. The control valve V1 controls the flow rate of hydraulic oil supplied from the hydraulic pump 25 to a hydraulic actuator that is equipped on the work machine 1 and is driven by the hydraulic oil. Specifically, the control valve V1 is a valve unit that integrates control valves that control the flow rate of hydraulic oil supplied to each hydraulic actuator installed in the work machine 1. The control valve V1 is arranged below a step portion 84a, which will be described later.

The hydraulic oil tank 28 and the control valve V1 are arranged on the same side of the body 2 as the hydraulic pump 25. By arranging the hydraulic pump 25, the hydraulic oil tank 28, and the control valve V1 on one side (left side) of the aircraft body 2, the arrangement of the hydraulic hose routed between the hydraulic pump 25, the hydraulic oil tank 28, and the control valve V1 is simplified. It is possible to simplify the policy route, etc.

An air conditioner body 29 that air-conditions the interior of the cabin 5 is arranged above the prime mover E1, the hydraulic pump 25, and the exhaust gas purification device 26 (see FIG. 5). The air conditioner main body 29 is a device that constitutes the main body of the air conditioning system, and includes a case, an expansion valve, an evaporator, a blower fan, etc. housed in the case. In the air conditioner body 29, the refrigerant from the receiver 24 is injected into the evaporator from the expansion valve and vaporized, the vaporized refrigerant cools the evaporator, and the air from the blower fan passes through the evaporator to generate cold air. The refrigerant leaving the evaporator returns to the compressor 18. Note that the heating system of the air conditioning system utilizes the heat of the prime mover E1.

As shown in FIG. 3, the fuselage 2 has a rotating frame 30 serving as a skeleton. The swing frame 30 includes a swing board (board) 31 that forms the bottom of the aircraft body 2, a reinforcing rib 32 that reinforces the swing board 31, the above-mentioned support bracket 9, and a weight 33. Further, the swing frame 30 has brackets, stays, etc. for attaching equipment, tanks, and other parts mounted on the aircraft body 2. The rotating board 31 is formed of a thick steel plate or the like. Brackets, stays, etc. installed on the rotating frame 30 are fixed onto the rotating base plate 31 by welding. The swing base plate 31 is supported on the traveling device 3 via the swing bearing 8 so as to be rotatable about the swing axis X1.

The reinforcing rib 32 is provided on the rotating base plate 31 from the front to the rear. The reinforcing ribs 32 are formed of a plate material, are oriented vertically (with the plate thickness direction aligned with the horizontal direction), are erected on the rotating base plate 31, and are fixed to the rotating base plate 31 by welding. Specifically, the reinforcing rib 32 includes a first vertical rib 32R that is provided on one side (right side) in the aircraft width direction K2 of the swivel board 31 and extends from the front to the rear of the swivel board 31; A second vertical rib 32L is provided on the other side (left side) in the width direction K2 and extends from the front to the rear of the rotating base plate 31.

As shown in FIGS. 4A, 4B, and 4C, the hydraulic oil tank 28 is disposed on the other side (left side) of the second vertical rib 32L in the body width direction K2. The control valve V1 is disposed on the other side (left side) of the second vertical rib 32L in the body width direction K2 and further forward than the hydraulic oil tank 28. Hydraulic pump 25 is arranged on the rear side of the fuselage rather than the front end of hydraulic oil tank 28 . Further, a delivery hose (hydraulic hose) 114 connecting the hydraulic pump 25 and the control valve V1 is routed between the second vertical rib 32L and the hydraulic oil tank 28.

Thereby, it is possible to improve the maintainability of the suction filter (not shown) and return filter 115 provided in the hydraulic oil tank 28, and to avoid noise generation due to interference between the delivery hose (hydraulic hose) 114 and the exterior.
A return filter 115 is provided at the front of the hydraulic oil tank 28, and the return filter 115 and the control valve V1 are connected by a return hose (hydraulic hose) 116.

The support bracket 9 is composed of a pair of upper and lower plates, and is fixed to the front part of the reinforcing rib 32. The weight 33 is attached to the rear of the rotating base plate 31.
A partition plate 34 is fixed to a midway portion of the rotating base plate 31 in the front-rear direction. The partition plate 34 is arranged vertically and extends in the body width direction K2, and crosses the first vertical rib 32R and the second vertical rib 32L. A prime mover E1 is mounted between the partition plate 34 and the weight 33. The front end side of the hydraulic oil tank 28 is arranged on the left side of the partition plate 34. The rear part of the hydraulic oil tank 28 and the hydraulic pump 25 are arranged behind the partition plate 34.

A reinforcing plate 35 extending rearward from the upper plate 9A forming the upper part of the support bracket 9 is fixed in front of the partition plate 34 and on the first vertical rib 32R and the second vertical rib 32L.
As shown in FIGS. 3, 4B, and 4C, a mount attachment portion 36 is provided on the front left side of the turning board 31 and the front portion of the reinforcing plate 35. As shown in FIGS. A pair of left and right support portions 37 are provided on the left side of the weight 33 in an upwardly projecting manner.

As shown in FIG. 4A, a mount member 38 is attached to the mount attachment part 36 to provide anti-vibration support for the front part of the cabin 5. A shielding plate 40 is attached to the left and right support parts 37 of the weight 33 via a thick plate member 39 (see FIG. 19), and a mount member is mounted on the shielding plate 40 to provide vibration-proof support for the rear part of the cabin 5. 41 is attached.
As shown in FIG. 4A, the left and right sides and front surface of the swing frame 30 are covered by a swing cover 42. As shown in FIG. The control valve V1 is housed within the fuselage 2, and can be inspected and maintained by removing the swing cover 42.

As shown in FIGS. 2 and 5 to 7, the fuselage 2 includes a cover device 43 that covers equipment, parts, members, etc. mounted on the swing frame 30. The cover device 43 includes a plurality of covers. The plurality of covers include a first cover 43A to a ninth cover 43I and a duct structure 45. The first cover 43A is arranged on the front right side of the body 2 and covers the capacitor 23 and the receiver 24. The first cover 43A is removable, and by removing it, the condenser 23 and receiver 24 can be inspected and maintained. The second cover 43B is arranged behind the first cover 43A and covers the upper part of the fuel tank 19 and battery 22. As shown in FIG. 5, the second cover 43B is pivoted at the rear by a hinge and can be opened upward. By opening the second cover 43B, the fuel tank 19 can be refueled, and the fuel tank 19 and The battery 22 can be inspected and maintained. The third cover 43C covers the right side of the fuel tank 19 and battery 22. As shown in FIG. 2, the third cover 43C is pivoted at the rear by a hinge and can be opened to the rear. By opening the third cover 43C, inspection and maintenance of the fuel tank 19 and battery 22 can be performed. can be done. Note that the third cover 43C is not limited to a configuration in which it is pivoted by a hinge, but may be configured to be detachably attached by, for example, a bolt. The fourth cover 43D covers the radiator 15, oil cooler 16, and fuel cooler 17 from above and from the right side to the rear. The fourth cover 43D has an opening 44 through which the cooling fan 14 takes in outside air. As shown in FIG. 8, the fourth cover 43D has a front portion pivoted by a hinge and opens forward. By opening the second cover 43D, the radiator 15, oil cooler 16, and fuel cooler 17 can be inspected and maintained. The fifth cover 43E covers the upper part of the cooling fan 14. The sixth cover 43F and the seventh cover 43G cover the rear of the prime mover E1. The sixth cover 43F has an upper first part 43Fa located above the seventh cover 43G, and a second part 43Fb located to the left of the seventh cover 43G. As shown in FIG. 8, the seventh cover 43G has an upper portion pivoted by a hinge and opens upward. Note that the seventh cover 43G may have a configuration in which the left side portion or the right side portion is pivoted by a hinge and opens to the left side or the right side. The eighth cover 43H covers the upper part of the hydraulic oil tank 28 and the left side of the air cleaner 27. As shown in FIG. 7, the eighth cover 43H has a rear portion pivoted by a hinge and opens rearward. By opening the eighth cover 43H, the hydraulic oil tank 28, air cleaner 27, and hydraulic pump 25 can be inspected and maintained. The ninth cover 43I is arranged below the eighth cover 43H and covers the lower part of the hydraulic oil tank 28. The duct structure 45 is provided on the left side of the fifth cover 43E, covers the upper part of the prime mover E1, and discharges hot air above the prime mover E1 to the outside of the cover device 43.

As shown in FIG. 7, an opening/closing cover 42A is provided on the left side surface of the swing cover 42. The opening/closing cover 42A has an upper portion pivoted by a hinge and opens upward. By opening the opening/closing cover 42A, the control valve V1 can be accessed.
As shown in FIGS. 4A and 9, the swing motor 20 is disposed in front of the partition plate 34 and near the first vertical rib 32R between the first vertical rib 32R and the second vertical rib 32L. The fuel tank 19 is arranged above the first vertical rib 32R (reinforcing rib 32) and extends above the first vertical rib 32R from the right end side of the fuselage 2 (the right side of the first vertical rib 32R) in the fuselage width direction K2. It is arranged so as to extend across and above the swing motor 20.

As shown in FIG. 9, the swing motor 20 is mounted on a swing board 31. The swing motor 20 is arranged below the cabin 5. A swing pinion 47 that is driven around a vertical axis by the power of the swing motor 20 is attached to the lower part of the swing motor 20 . The swing pinion 47 is arranged below the swing base plate 31 and engages with the swing bearing 8 . Specifically, the swing bearing 8 includes an outer ring attached to the body 2, and an inner ring that is rotatably provided on the inner circumference of the outer ring around the rotation axis X1 and has an internal gear formed on the inner circumference. A rotating pinion 47 meshes with the internal gear. Then, the swing pinion 47 is rotationally driven by the swing motor 20 and moves along the internal gear, so that the body 2 swings around the swing axis X1.

As shown in FIG. 9, the fuel tank 19 is placed near the swing motor 20. Specifically, it is arranged on the right side of the swing motor 20. The fuel tank 19 includes a tank main body 19A disposed on the right side of the swing motor 20, a projecting portion 19B extending leftward from the tank main body 19A and projecting above the swing motor 20, and a projecting portion 19B extending downward from the tank main body 19A. It has a protruding portion 19C that protrudes from. The protrusion 19C is formed at the center of the tank body 19A in the longitudinal direction so as to extend in the body width direction K2 (see FIG. 15). The lower surface of the tank body 19A, in front and behind the protruding portion 19C, is a lower mounting surface 48 that is placed on a mounting portion 55c, which will be described later. The pair of lower mounting surfaces 48 are formed as flat surfaces across the machine body width direction K2.

In the fuel tank 19 of this embodiment, the capacity of the fuel tank 19 can be increased by providing the overhang portion 19B and the protrusion portion 19C.
As shown in FIGS. 9 and 10, the cabin 5 has a lower side plate 49 at the lower part. The lower side plate 49 is provided at the lower left side and the lower right side of the cabin 5. The left and right lower side plates 49 are members that constitute a cabin frame that forms the skeleton of the cabin 5 together with the front pillar 50 and the rear pillar 51. A notch 49a is formed on the lower side of the lower side plate 49 to avoid interference with the protrusion 19B of the fuel tank 19.

As shown in FIG. 11, the projecting portion 19B is inserted into the lower side of the cabin 5 via the notch portion 49a. The fuel tank 19 is supported by a support stand 52 attached to the revolving frame 30. Further, the fuel tank 19 is movably supported by a support base 52 in order to retract the projecting portion 19B from above the swing motor 20. In this embodiment, the fuel tank 19 is movable outward (to the right) in the machine width direction K2 from the installation position shown in FIG.

As shown in FIG. 12, the support stand 52 includes a first side plate 53, a second side plate 54, and an upper plate 55.
As shown in FIGS. 12 and 13, the first side plate 53 includes a front upper edge 53a, a vertical edge 53b extending downward from the front upper edge 53a, and a rearward extending from the lower end of the vertical edge 53b. It has a rear upper edge 53c. Further, the first side plate 53 has a mounting piece 53d formed at the lower part of the front part. As shown in FIG. 13, the mounting piece 53d is attached to a nut member 56 fixed on the reinforcing plate 35 with a bolt.

As shown in FIGS. 14 and 15, the second side plate 54 includes a front upper edge 54a, a vertical edge 54b extending downward from the front upper edge 54a, and a rear rear edge 54b extending rearward from the vertical edge 54b. 1 upper edge 54c, a rear second upper edge 54d located at a distance behind the rear first upper edge 54c, and the rear first upper edge 54c and the rear second upper edge 54d. It has a concave edge portion 54e that is concave downward. The concave edge 54e includes a first edge 54e1 extending downward from the rear end of the rear first upper edge 54c, a second edge 54e2 extending downward from the front end of the rear second upper edge 54d, and a first edge 54e1. and a third edge 54e3 that connects the lower ends of the second edge 54e2 and the third edge 54e3. The second side plate 54 has a mounting piece 54f at the lower front portion. The attachment piece 54f is attached to the rotating board 31 with bolts.

As shown in FIGS. 12 to 15, the upper plate 55 is fixed to the first side plate 53 and the second side plate 54. As shown in FIGS. The upper plate 55 has a battery mounting wall 55a, a hanging wall 55b, a pair of mounting parts 55c, and a connecting wall 55d.
The battery mounting wall 55a is provided between the front upper edges 53a and 54a of the first side plate 53 and the second side plate 54. The battery 22 is placed and attached to the battery mounting wall 55a (see FIG. 4A).

The hanging wall 55b extends downward from the rear edge of the battery mounting wall 55a and is provided between the vertical edges 53b and 54b of the first side plate 53 and the second side plate 54.
One (front side) of the pair of mounting parts 55c extends rearward from the lower edge of the hanging wall 55b, and extends between the rear upper edge 53c of the first side plate 53 and the second side. It is provided across the rear first upper edge 54c of the plate 54. The other (rear) mounting section 55c is arranged at a distance behind the one mounting section 55c, and is located between the rear upper edge 53c of the first side plate 53 and the rear part of the second side plate 54. It is provided across the second upper edge 54d. A mounting piece 55e is formed on the rear right side of the other mounting portion 55c. The mounting piece 55e is fixed to a support plate 57 provided on the rotating frame 30 with bolts. Furthermore, an extending piece 55f extending rearward is formed on the left side of the mounting piece 55e on the other mounting portion 55c. The pair of placement parts 55c protrude rightward from the second side plate 54.

As shown in FIG. 15, the mounting lower surface 48 of the fuel tank 19 is mounted on the pair of mounting portions 55c so as to be movable (slidable) in the body width direction K2. That is, the support stand 52 has a pair of mounting parts 55c that slidably support the fuel tank 19 in a tank movement direction 58, which is a direction in which the fuel tank 19 is moved. are arranged side by side at intervals in the horizontal direction perpendicular to the tank movement direction 58. In this embodiment, the lower mounting surface 48 is mounted on the mounting portion 55c via an underlay member 59 provided on the upper surface of the mounting portion 55c. The underlay member 59 is formed of, for example, a member with low frictional resistance or a member with cushioning properties. Further, the underlay member 59 may be formed of a member with low frictional resistance and cushioning properties.

As shown in FIG. 15, the protrusion 19C protrudes between the pair of placement parts 55c and is located within the concave edge 54e.
As shown in FIG. 13, the connecting wall 55d connects the left end sides of the pair of placement parts 55c. The protruding portion 19C is arranged on the right side of the connecting wall 55d. The rear part of the connecting wall 55d is placed on and supported by a block member 60 fixed on the reinforcing plate 35.

As shown in FIG. 16, the fuel tank 19 is movable on the support stand 52 in a tank movement direction 58 (aircraft width direction K2), and the fuel tank 19 can be moved to the right from the installation position shown in FIG. Then, the projecting portion 19B is retracted from above the swing motor 20. This makes it possible to access the swing motor 20 and to perform maintenance on the swing motor 20. Furthermore, a motor removal path 61 is provided between the cabin 5 and the support base 52, which is a path for removing the swing motor 20. Therefore, by moving the fuel tank 19 and retracting the overhanging portion 19B from above the swing motor 20, the overhanging portion 19B is retracted from the motor removal path 61. By retracting the projecting portion 19B from the motor removal path 61, the swing motor 20 can be removed upwardly via the motor removal path 61. That is, the overhanging portion 19B overhangs the swing motor 20 by blocking the motor removal path 61, which is a path through which the swing motor 20 is removed upward from the aircraft body 2. In other words, the motor removal path 61 for removing the swing motor 20 is used for arranging the fuel tank 19.

As described above, in this embodiment, maintenance, removal, etc. of the swing motor 20 can be ensured by moving the fuel tank 19 and retracting the overhanging portion 19B from the upper side of the swing motor 20. 19 is provided with an overhanging portion 19B that extends above the swing motor 20, capacity can be increased, and the space above the swing motor 20 can be effectively utilized.

Furthermore, since the motor removal path 61 for removing the swing motor 20 is formed between the cabin 5 and the support base 52, the swing motor 20 can be removed without removing (lowering) the cabin 5 from the aircraft body 2. I can do it. Further, since the cabin 5 does not have to be lowered from the aircraft body 2 to remove the swing motor 20, the cabin 5 can be securely mounted on the aircraft body 2.

Note that in this embodiment, the support stand 52 is formed by combining a tank support stand that supports the fuel tank 19 and a battery support stand that supports the battery 22, but the tank support stand and the battery support stand are different from each other. , may be formed separately.
As shown in FIG. 17, the fuel tank 19 has an attachment stay 63 attached to an attachment frame 62 erected on the support stand 52. As shown in FIG. By attaching this attachment stay 63 to the attachment frame 62, movement of the fuel tank 19 in the tank movement direction 58 can be restricted.

As shown in FIGS. 12 and 17, the attachment stay 63 has a lower wall 63a and a vertical wall 63b extending upward from the rear of the lower wall 63a. The lower wall 63a is fixed to a mounting tool 64, and the mounting tool 64 is mounted to a mounting portion 65 provided at the upper part of the fuel tank 19.
As shown in FIGS. 12 and 17, the mounting frame 62 includes a support member 62A erected on the extension piece 55f of the mounting portion 55c, a stay mounting portion 62B fixed to the upper part of the support member 62A, and a frame mounting portion 62B. 62C. The stay attachment part 62B is fixed to the front side of the upper part of the support member 62A. By removably attaching the attachment stay 63 to the stay attachment portion 62B with bolts or the like, movement of the fuel tank 19 in the tank movement direction 58 can be restricted. Further, by releasing the fixation of the mounting stay 63 to the stay mounting portion 62B, movement of the fuel tank 19 in the tank movement direction 58 can be allowed. The frame attachment portion 62C is fixed to the upper end of the column member 62A on the rear side of the stay attachment portion 62B. By opening the second cover 43B, the attachment stay 63 can be released from being fixed to the stay attachment portion 62B. Further, by opening (or removing) the second cover 43B and the third cover 43C, the fuel tank 19 can be moved to the right.

As shown in FIGS. 4A and 17, the mounting frame 62 is attached to a support frame 66 that supports equipment mounted on the aircraft body 2. As a result, the mounting frame 62 can be sufficiently supported, and in turn, the movement of the fuel tank 19 can be sufficiently restricted and supported.
The support frame 66 includes a gate-shaped main frame 67 and a subframe 68 that reinforces the main frame 67. For example, the radiator 15, a fan shroud surrounding the cooling fan 14, and the like are attached to and supported by the main frame 67. The main frame 67 has a lower part attached to an attachment part 69 provided on the weight 33 and a rear support part 67A standing upright on the attachment part 69, and a lower part attached to an attachment part 70 fixed to the partition plate 34. It has a front support section 67B that is erected on the mounting section 70, and a connecting section 67C that connects the rear support section 67A and the front support section 67B. An attachment piece 71 to which a frame attachment part 62C is attached is fixed to the upper part of the front column part 67B.

The sub-frame 68 is formed of a bar or a plate, and has a support plate 57 whose lower part is fixed to the partition plate 34, and a support plate 68A that stands upright on the support plate 57, and a support plate 68A extending from the upper end of the support plate 68A to the left. It has a cross member part 68B which extends toward the front and whose left end side is fixed to the upper part of the front support part 67B. The mounting piece 71 is also fixed to the cross member portion 68B.
As shown in FIG. 18, the hose 73 connected to the fuel tank 19 has enough hose to allow the movement of the fuel tank 19 in the tank movement direction 58, as shown by the imaginary line. formed in length. The hoses 73 connected to the fuel tank 19 include a delivery hose 73A that sends fuel from the fuel pump 72 to the fuel tank 19, a fuel tube 73B that connects the fuel filter 100 and the fuel tank 19, and a fuel tube 73B that connects the fuel filter 100 and the fuel tank 19. Examples include a return hose 73C through which fuel flows, a drain tube 73D through which fuel in the fuel tank 19 is drained, and the like.

As shown in FIGS. 5 and 19, the air conditioner main body 29 is mounted at the rear of the cabin 5. Further, the air conditioner body 29 is disposed behind the driver's seat 6, specifically, behind the backrest portion 6B of the driver's seat 6. The air conditioner main body 29 has a front part located inside the cabin 5 and a rear part protruding rearward from the back surface of the cabin 5. A portion of the air conditioner main body 29 that protrudes from the cabin 5 is covered by an air conditioner cover 46. By making the air conditioner body 29 protrude from the cabin 5, it is possible to suppress the air conditioner body 29 from narrowing the indoor space of the cabin 5.

As shown in FIG. 8, the air conditioner cover 46 has an openable/closeable cover 46A. The opening/closing cover 46A has an upper front side pivoted to the cabin 5 via a hinge and opens upward. By opening the opening/closing cover 46A, maintenance of the air conditioner main body 29 and the like can be performed.
As shown in FIG. 19, the air conditioner main body 29 is arranged above a prime mover room (engine room) E2 that accommodates a prime mover E1. By arranging the air conditioner body 29, which was conventionally installed below the driver's seat 6, above the prime mover compartment E2, the space under the operator's feet can be increased.

As shown in FIGS. 2, 19, 27, etc., the engine room E2 includes a partition wall 74 that separates the engine E1 from the driver's seat 6 side, a partition plate 34, a rotating base plate 31, a weight 33, and a sixth cover 43F to a ninth cover 43F. It is composed of a cover 43I, a shielding plate 40, and the like.
As shown in FIG. 19, the cabin 5 includes a plate member 75 provided behind the driver's seat 6. As shown in FIG. Specifically, the plate member 75 is provided at the rear of the lower part of the backrest portion 6B of the driver's seat 6. The front part of the plate member 75 is disposed inside the cabin 5, and the rear part projects rearward from the back surface of the cabin 5. The plate member 75 is connected to the rear portions of the left and right lower side plates 49. The plate member 75 is connected to the rear part of a floor sheet (outer wall of the cabin 5) 84 that forms the bottom side of the interior of the cabin 5. The floor seat 84 includes a step part 84a on which the operator's feet are placed, a seat base part 84b located behind the step part 84a and to which the driver's seat 6 is attached, and a seat base part 84b that moves upward as it goes rearward. It has an inclined wall portion 84c having an inclined shape, and a connecting wall portion 84d extending rearward from the rear upper part of the inclined wall portion 84c and connected to the plate member 75.

As shown in FIG. 19, the floor sheet 84 and the partition wall 74 are spaced apart from each other. That is, the engine room E1 and the inside of the cabin 5 are separated by a double structure of a partition wall 74 that partitions the engine room E1 and the outside of the engine room E1, and an outer wall (floor sheet 84) of the cabin 5. Further, the plate member 75 is arranged above the engine room E2 with a space therebetween, and is supported on the fuselage 2 via the mount member 41 in a vibration-proof manner. The air conditioner main body 29 is installed on this plate member 75. The plate member 75 is formed of a thick plate material, and is arranged at a distance from the prime mover chamber E2 so that an air layer (insulation layer) is formed between the plate member 75 and the prime mover chamber E2 (the prime mover E1). ) can be significantly suppressed from being transmitted to the air conditioner main body 29.

Furthermore, by installing the air conditioner main body 29 on the plate member 75 to which the mount member 41 that supports the rear part of the cabin 5 in vibration isolation is attached, the member can be used for multiple purposes, and the installation structure of the air conditioner main body 29 can be made compact. be able to.
As shown in FIG. 20, a filter device 77 is installed at the rear of the air conditioner main body 29. An intake section 29A for sucking in air is provided on the left side of the air conditioner main body 29, and an exhaust section 29B for discharging conditioned air is provided on the right side of the air conditioner main body 29.

As shown in FIG. 19, the filter device 77 and the intake section 29A are connected by an intake duct 78, and outside air is sucked into the air conditioner main body 29 via the filter device 77. A supply duct 79 is connected to the discharge portion 29B, and conditioned air is supplied into the cabin 5 from the supply duct.
As shown in FIG. 2, a duct structure 45 for discharging hot air from the engine room E2 to the outside is provided on the right side of the engine room E2 (on the right side of the engine E1).

As shown in FIGS. 23A and 24, the duct structure 45 constitutes a part of the partition wall 74 that constitutes the engine room E2. Specifically, the partition wall 74 includes a main wall part 80 forming the left part of the partition wall 74, a fan cover wall part 81 forming the right part of the partition wall 74, and a wall between the main wall part 80 and the fan cover wall part 81. The duct structure 45 provided in It has a second connecting wall portion 83 that connects.

As shown in FIG. 19, the main wall portion 80 includes an upper wall 80A that covers the upper side of the prime mover E1, and a front wall 80B that covers the front of the prime mover E1. As shown in FIG. 19, the upper wall 80A is connected to the shielding plate 40.
As shown in FIGS. 23A and 24, a notch 117 is formed on the left side of the front wall 80B. The cutout portion 117 is formed in a cutout shape that opens leftward and downward from an upper edge 117a extending in the body width direction K2 and a vertical edge 117b extending downward from the right end of the upper edge 117a. As shown in FIG. 23B, the front part of the hydraulic oil tank 28 is arranged in the notch 117 so as to close the notch 117. A sealing member 118 is attached across the upper edge 117a and the vertical edge 117b of the notch 117, and this sealing member 118 contacts the hydraulic oil tank 28 and seals the gap between the hydraulic oil tank 28 and the notch 117. It is sealed. Therefore, the hydraulic oil tank 28 constitutes a part of the partition wall 74 that partitions the engine room E2 from the outside (driver's seat 6 side) of the engine room E2.

As shown in FIGS. 21 and 22, the fan cover wall portion 81 includes an upper wall 81A that covers the upper side of the cooling fan 14, and a front wall 81B that covers the front side of the cooling fan 14. As shown in FIGS. 23A and 24, the first connecting wall 82 connects the lower portions of the front wall 80B of the main wall 80 and the front wall 81B of the fan cover wall 81. As shown in FIG. 24, the second connecting wall portion 83 connects the rear portions of the upper wall 80A of the main wall portion 80 and the upper wall 81A of the fan cover wall portion 81. As shown in FIG. 27, the lower part of the front wall 80B of the main wall part 80, the lower part of the front wall 81B of the fan cover wall part 81, and the first connecting wall part 82 are attached to the partition plate 34. As shown in FIGS. 23A and 27, a positioning member contacts the upper end of the partition plate 34 over the lower part of the front wall of the main wall part 80, the first connecting wall part 82, and the lower part of the front wall 81B of the fan cover wall part 81. A contact plate 85 is provided.

As shown in FIGS. 23A, 24, and 25, the duct structure 45 includes a pair of side walls 86, a bottom wall 87, and a cover wall 88. The pair of side walls 86 are arranged to face each other with an interval in the body width direction K2. One side wall 86L is connected to the right end side of the main wall portion 80. The other side wall 86R is connected to the left end side of the fan cover wall portion 81. The space between the pair of side walls 86 is open rearward, forward, upward and downward. As shown in FIG. 27, the bottom wall 87 is located above the prime mover E1. Further, the bottom wall 87 extends rearward from the second connecting wall portion 83 and is provided across the rear lower ends of the pair of side walls 86 to close the rear lower ends of the pair of side walls 86 . Therefore, between the lower ends of the pair of side walls 86, the front side is open and the rear side is closed by the bottom wall 87. The front side between the lower ends of the pair of side walls 86, that is, the front end of the bottom wall 87 and the cover wall 88 located in front of the front end of the bottom wall 87 communicates with the upper part of the engine room E2. It serves as an inlet 89 for introducing hot air.

As shown in FIG. 23A, the cover wall 88 closes between the upper ends and the front ends of the pair of side walls 86. Specifically, the cover wall 88 includes an upper wall 88a that extends from the rear end to the lower front end between the pair of side walls 86, and a wall that extends from the left end of the upper wall 88a and is removably attached to one side wall 86L. It has a side wall 88b and another side wall 88c that extends from the right end of the upper wall 88a and is detachably attached to the other side wall 86R. Further, as shown in FIGS. 26 and 27, a closing wall 90 and a discharge port 91 are provided on the rear end side of the cover wall 88. The closing wall 90 closes the lower part of the rear end opening between the pair of side walls 86. The exhaust port 91 is a portion that communicates with the outside of the engine room E2 and discharges the hot air introduced from the inlet 89, and is provided above the closing wall 90.

The air taken into the engine room E2 by the cooling fan 14 is introduced into the duct structure 45 from the inlet 89 together with the hot air in the upper part of the engine room E2, as shown by the arrow in FIG. 27, and the introduced hot air is It flows rearward within the duct structure 45 and is discharged from the discharge port 91 to the outside of the engine room E2.
As shown in FIG. 27, the compressor 18 is disposed in front of the upper right side of the prime mover E1 and below the inlet 89. As shown in FIG. 21, the compressor 18 is driven by the power of the prime mover E1 being transmitted via a transmission belt 92, and is driven by a first stay 93 and a second stay attached to the prime mover E1, as shown in FIG. The tension of the transmission belt 92 is attached to the stay 94 so that the tension thereof can be adjusted.

As shown in FIG. 27, a compressor placement portion 95 in which the compressor 18 is placed is provided on the lower side of the front portion of the duct structure 45. The compressor arrangement portion 95 is arranged on the right side (one side) of the cabin 5 in the body width direction K2. Further, the compressor arrangement portion 95 is provided below the inlet 89 and in communication with the inlet 89 .
As shown in FIGS. 23A and 25, the compressor placement portion 95 includes a main body portion 95A having an inspection opening 95a, and an open/close cover 95B that closes the inspection opening 95a.

As shown in FIG. 25, the main body portion 95A is formed by recessing a plate material forming the partition wall 74 from the rear toward the front. The inspection opening 95a opens forward and communicates between the pair of side walls 86.
As shown in FIG. 23A, the open/close cover 95B is integrally formed at the front lower part of the cover wall 88 of the duct structure 45. As shown in FIG. That is, the open/close cover 95B can be attached to and detached from the cover wall 88 integrally.

As shown in FIG. 28, by removing the open/close cover 95B together with the cover wall 88, the compressor 18 can be accessed through the inspection opening 95a and between the pair of side walls 86. Therefore, when the cover wall 88 is removed together with the opening/closing cover 95B, the tension of the transmission belt 92 that transmits power to the compressor 18 can be adjusted. Moreover, the compressor 18 can also be taken out. Further, the compressor 18 is accessible from inside the cabin 5. Specifically, as shown in FIG. 1, an opening/closing window 5A is provided on the right side (one side) of the cabin 5, and a compressor placement section 95 is placed on the right side (one side) of the cabin 5. . Therefore, by opening the second cover 43B, removing the opening/closing cover 95B and the cover wall 88, and opening the opening/closing window 5A, the compressor 18 can be accessed from inside the cabin 5. This makes it possible to improve the ease of maintenance such as servicing the compressor 18 and adjusting the transmission belt 92.

As shown in FIG. 27, within the duct structure 45, a refrigerant pipe line 96 connected to the compressor 18 and a heating medium pipe line 97 for heating the air conditioning system routed from the prime mover E1 to the air conditioner body 29 are arranged. will be planned. That is, the inside of the duct structure 45 is a routing path 98 in which the refrigerant pipeline 96 and the heat medium pipeline 97 are routed. In other words, the duct structure 45 forms the route 98, and the route 98 is used to exhaust the hot air above the engine room E2. Therefore, the route 98 communicates with the upper part of the engine room E2 to introduce the hot air from the engine room E2, and the outside of the engine room E2 to exhaust the hot air introduced from the inlet 89. It has a discharge port 91.

In this embodiment, the duct structure 45 forms a route 98 for the refrigerant pipe line 96 and the heat medium pipe line 97, and an exhaust route for exhausting hot air from the engine room E2. The structure can be simplified and members can be used interchangeably.
As shown in FIGS. 27 to 30, the refrigerant pipe line 96 includes a hose 96a, a pipe (steel pipe) 96b, a joint 96c, and the like. The refrigerant pipe line 96 is inserted into the routing path 98 from the compressor 18 via the inlet 89, and is clamped by a clamp portion 99 at a midway portion of the routing path 98. A pair of refrigerant pipes 96 are provided. One refrigerant pipe line 96A is routed from the clamp 99 portion to the air conditioner main body 29 through one (left) side wall 86L. After passing through one side wall 86L, the other refrigerant pipe 96B is routed forward and connected to the condenser 23, and from the condenser 23 to the receiver 24, and from the receiver 24, routed rearward to the air conditioner main body 29. It is connected. One refrigerant pipe 96A and the other refrigerant pipe 96B are removable from one side wall 86L.

As shown in FIG. 27, the heat medium conduit 97 includes a hose 97a, piping (steel pipe) 97b, a joint, and the like. A pair of heat medium pipes 97 are provided. The pair of heat medium pipes 97 are inserted into the routing path 98 from the prime mover E1 via the inlet 89, and are connected to the air conditioner main body 29 after passing through one side wall 86L.
FIG. 31 shows a state in which the compressor 18 has been removed from the prime mover E1, the condenser 23 and the receiver 24 have been removed from the airframe 2, and the refrigerant pipe line 96 has been removed from one side wall 86L. When the cabin 5 is removed from the aircraft body 2, the compressor 18, condenser 23, and receiver 24 can be left in the cabin 5 with the refrigerant pipe line 96 connected to the compressor 18, condenser 23, receiver 24, and air conditioner main body 29. That is, the cabin 5 can be lowered from the aircraft body 2 without removing the refrigerant pipe line 96 from the compressor 18, condenser 23, receiver 24, etc. (without removing the refrigerant).

Note that since the capacitor 23 and the receiver 24 are arranged on the front side of the cabin 5, in the case of a work machine 1 that is not designed for a cabin, the capacitor 23 and the receiver 24 are not mounted on the machine body 2, so the capacitor 23 and the receiver 24 are You can walk through the location of the.
32 and 33 show an intake structure 101 that takes air into the prime mover E1, and an exhaust structure 102 that exhausts exhaust gas discharged from the prime mover E1 to the outside of the prime mover room E2.

As shown in FIGS. 32 and 33, the intake structure 101 includes an air introduction box 103 that takes in air, a noise reduction box 104 that reduces intake noise, a connection box 105 that connects the air introduction box 103 and the noise reduction box 104, and an air cleaner 27. including. The exhaust structure 102 includes an exhaust gas purification device 26 and an exhaust duct 106. The intake structure 101 is provided on the side (left side) of the exhaust gas purification device 26. Further, the intake structure 101 is provided on the other side (left side) of the fuselage 2 in the fuselage width direction K2.

As shown in FIGS. 32 and 33, the air introduction box 103 has a front wall 103a, an upper wall 103b, a lower wall 103c, a first side wall 103d on the left side, and a second side wall 103e on the right side, and is open to the rear. It is said that Further, as shown in FIG. 34, an outside air intake port 109 for taking in air (outside air) into the rear opening 107 of the air introduction box 103 is formed in the second portion 43Fb of the sixth cover 43F. The outside air intake port 109 is formed by, for example, a louver or a large number of holes.

The air introduction box 103 partitions the exhaust gas purification device 26 side and the gap 108 side, and the intake air of the prime mover E1 is sucked in from the opening 107 provided on the rear side of the air introduction box 103. This prevents hot air from being taken in from the exhaust gas purification device 26 located at the exhaust gas purification device 26 side.
Further, the exhaust port 91 of the duct structure 45 is provided on the right side (one side) in the machine width direction K2, and the intake structure 101 introduces outside air from the left side (other side) in the machine width direction K2, so the prime mover room E1 It is possible to prevent the hot air discharged from the engine from being taken in as intake air to the prime mover E1.

As shown in FIG. 34, the air taken into the air introduction box 103 flows to the silencing box 104 via the connection box 105, and from the silencing box 104 to the air cleaner 27. Air flows from the air cleaner 27 to the prime mover E1 via the intake hose 110 and the like.
As shown in FIGS. 32 and 33, the exhaust duct 106 is provided vertically between the exhaust gas purification device 26 and the rotating base plate 31. As shown in FIGS. The exhaust duct 106 has an inlet opening 106a opening to the right at the top, and an outlet opening 106b opening rearward at the bottom. As shown in FIG. 33, an exhaust pipe 111 is connected to the exhaust gas discharge side 26a of the exhaust gas purification device 26. The exhaust pipe 111 is bent toward the inlet opening 106a of the exhaust duct 106. Exhaust gas discharged from the prime mover E1 passes through the exhaust gas purification device 26, is blown out from the exhaust pipe 111 toward the inlet opening 106a, and is also discharged from the outlet opening 106b.

On the other hand, as shown in FIG. 7, a discharge portion 112 is cut out at the lower right end of the weight 33. The exhaust gas discharged from the outlet opening 106b of the exhaust duct 106 is discharged to the outside from the discharge section 112.
The work equipment 1 described above includes a traveling device 3, a machine body 2 rotatably supported on the traveling device 3, a swing motor 20 for rotating the machine body 2, and a tank (fuel tank) disposed near the swing motor 20. 19) and a support stand 52 that supports the tank 19, the tank 19 has a tank main body 19A, an overhanging portion 19B overhanging the swing motor 20 from the tank main body 19A, and an overhanging portion 19B is movably supported by a support stand 52 so as to be retracted from above the swing motor 20.

According to this configuration, maintenance of the swing motor 20 can be ensured by moving the tank 19 and retracting the projecting portion 19B from the upper side of the swing motor 20. By providing an overhanging portion 19B, the capacity can be increased, and the space above the swing motor 20 can be effectively utilized.
Further, the projecting portion 19B projects upward from the swing motor 20 by blocking a motor removal path 61, which is a path through which the swing motor 20 is removed upward from the body 2.

According to this configuration, even if the overhanging portion 19B is provided that overhangs the swing motor 20 from the tank body 19A, the overhang portion 19B can be retracted from above the swing motor 20, so that the swing motor 20 can be removed from the motor. It can be taken out from path 61.
The aircraft also includes a cabin 5 mounted on the fuselage 2 , a swing motor 20 is disposed below the cabin 5 , and a motor removal path 61 is formed between the cabin 5 and the support base 52 .

According to this configuration, the swing motor 20 can be removed without removing the cabin 5 from the aircraft body 2.
Further, the support stand 52 has a pair of mounting parts 55c that slidably support the tank 19 in a tank movement direction 58, which is a direction in which the tank 19 is moved. The tank 19 has a protruding part 19C that protrudes from the tank body 19A between the pair of mounting parts 55c.

According to this configuration, the protrusion 19C can be provided on the tank 19 without hindering the movement of the tank 19, and the capacity can be increased by providing the protrusion 19C.
The mounting frame 62 also includes a mounting frame 62 erected on the support base 52 and a mounting stay 63 provided on the upper part of the tank 19, and the mounting frame 62 has a stay mounting portion 62B to which the mounting stay 63 is removably mounted. have.

According to this configuration, movement of the tank 19 can be restricted.
Further, a support frame 66 that supports equipment mounted on the fuselage 2 is provided, and the attachment frame 62 has a frame attachment portion 62C that is attached to the support frame 66.
The movement of the tank 19 can be strictly regulated.
Alternatively, the aircraft body 2 may include the prime mover E1, and the tank 19 may be a fuel tank 19 that stores fuel for the prime mover E1.

The work equipment 1 also includes a fuselage 2, a cabin 5 mounted on the fuselage 2, an air conditioner body 29 for indoor air conditioning of the cabin 5, and a prime mover room E2 that accommodates the prime mover E1 mounted on the fuselage 2. The air conditioner main body 29 is arranged above the prime mover room E2.
According to this configuration, by arranging the air conditioner main body 29 above the prime mover room E2, the space under the operator's feet can be made wider than when the air conditioner main body 29 is arranged below the driver's seat 6.

The cabin 5 also includes a driver's seat 6 disposed inside the cabin 5, and the cabin 5 has a plate member 75 disposed behind the driver's seat 6 and on which the air conditioner main body 29 is installed, and the plate member 75 is connected to the prime mover. It is arranged above the chamber E2 at a distance from the prime mover chamber E2, and is supported by the fuselage body 2 via a mount member 41 in a vibration-proof manner.
According to this configuration, it is possible to suppress the heat in the engine room E2 from being transmitted to the air conditioner main body 29, and it is also possible to simplify the structure and use multiple members.

Further, the front part of the plate member 75 is disposed inside the cabin 5, and the rear part projects rearward from the back surface of the cabin 5.
According to this configuration, it is possible to suppress the air conditioner main body 29 from narrowing the indoor space of the cabin 5.
Also, the arrangement of a cooling fan 14 that introduces air outside the prime mover room E2 into the prime mover room E2, a compressor 18 that is driven by the power of the prime mover E1 to compress refrigerant, and a refrigerant pipe line 96 that is connected to the compressor 18 is provided. A path 98 includes an inlet 89 that communicates with the upper part of the engine room E2 and introduces hot air from the engine room E2, and an exhaust port 91 that communicates with the outside of the engine room E2 and discharges the hot air introduced from the inlet 89. and a route path 98 having the following.

According to this configuration, the routing path 98 of the refrigerant pipe line 96 can be used as an exhaust path for exhausting hot air from the engine room E2, and the configuration can be simplified and members can be used for multiple purposes.
It also includes a compressor placement section 95 in which the compressor 18 is placed, and the routing path 98 closes between a pair of side walls 86 that are arranged opposite to each other with an interval in the body width direction K2 and a rear lower end of the pair of side walls 86. It has a bottom wall 87 and a cover wall 88 that closes between the upper ends and front ends of the pair of side walls 86, the inlet 89 is formed between the bottom wall 87 and the cover wall 88, and the outlet 91 is formed between the cover wall 87 and the cover wall 88. The compressor placement portion 95 is formed at the rear of the wall 88 and is provided below the inlet 89 in communication with the inlet 89 .

According to this configuration, the refrigerant pipe line 96 can be easily arranged.
The compressor placement portion 95 also includes a main body portion 95A having an inspection opening 95a that opens forward and communicates between the pair of side walls 86, and an opening/closing cover 95B that closes the inspection opening 95a. It can be attached and detached integrally with the wall 88.
According to this configuration, the capacitor 23 can be accessed by simply removing the opening/closing cover 95B together with the cover wall 88.

Further, a condenser 23 that radiates heat of the refrigerant from the compressor 18 to liquefy it, and a receiver 24 that stores the refrigerant liquefied by the condenser 23 are arranged on the side of the front part of the cabin 5 and in front of the compressor 18. The compressor 18, the condenser 23, and the receiver 24 are removable from the fuselage 2 together with the cabin 5.
According to this configuration, the cabin 5 can be lowered from the aircraft body 2 without removing the refrigerant pipe line 96 from the compressor 18, condenser 23, and receiver 24.

The aircraft also includes a compressor placement part 95 in which the compressor 18 is placed, and the compressor placement part 95 is placed on one side of the cabin 5 in the aircraft width direction K2, so that the compressor 18 can be accessed from inside the cabin 5. .
According to this configuration, maintainability of the compressor 18 and adjustment of the transmission belt 92 that transmits power to the compressor 18 can be improved.

The fuselage 2 also includes a base plate (swivel base plate 31), a first vertical rib 32R provided on one side of the base plate 31 in the fuselage width direction K2 and extending from the front of the base plate 31 toward the rear, and A second vertical rib 32L provided on the other side in the width direction K2 and extending from the front to the rear of the substrate 31, a hydraulic actuator driven by hydraulic oil, and a hydraulic oil tank 28 that stores the hydraulic oil. , a hydraulic pump 25 that delivers hydraulic oil from the hydraulic oil tank 28, a control valve V1 that controls the flow rate of hydraulic oil supplied from the hydraulic pump 25 to the hydraulic actuator, and the hydraulic pump 25 and the control valve V1 are connected. A hydraulic hose (delivery hose 114), the hydraulic oil tank 28 is arranged on the other side of the body width direction K2 than the second vertical rib 32L, and the control valve V1 is arranged on the other side of the body width direction K2 than the second vertical rib 32L. The hydraulic pump 25 is disposed on the other side in the direction K2 and in front of the hydraulic oil tank 28, and the hydraulic pump 25 is disposed on the rear side of the fuselage rather than the front end of the hydraulic oil tank 28, and the hydraulic hose 25 is connected to the second vertical rib. 32L and the hydraulic oil tank 28.

According to this configuration, it is possible to improve the maintainability of the suction filter and return filter 115 provided in the hydraulic oil tank 28, and to avoid noise generation due to interference between the hydraulic hose (delivery hose 114) and the exterior.
The interior of the engine room E2 and the cabin 5 are separated by a double structure consisting of a partition wall 74 that partitions the engine room E2 and the outside of the engine room E2, and an outer wall (floor sheet 84) of the cabin 5. The tank 28 constitutes a part of the partition wall 74.

According to this configuration, it is possible to suppress the heat in the engine room E2 from being transmitted into the cabin 5, and it is also possible to use a member for multiple purposes.
Further, a fuel tank 19 for storing fuel for the prime mover E1 is provided, and the fuel tank 19 is disposed above the first vertical rib 32R and across the first vertical rib 32R in the body width direction K2.
According to this configuration, the cabin 5 can be placed closer to the rear of the aircraft than when the fuel tank 19 is placed behind the cabin 5, and the stability of the aircraft can be improved.

Further, the exhaust port 91 is provided on one side in the machine width direction K2, and includes an intake structure 101 that introduces air into the prime mover E1, and the intake structure 101 introduces outside air from the other side in the machine body width direction K2.
According to this configuration, it is possible to prevent hot air discharged from the prime mover chamber E1 from being taken in as intake air to the prime mover E1.

Although one embodiment of the present invention has been described above, the embodiment disclosed this time should be considered to be illustrative in all respects and not restrictive. The scope of the present invention is indicated by the claims rather than the above description, and it is intended that all changes within the meaning and range equivalent to the claims are included.

2 Aircraft body 5 Cabin 6 Driver's seat 14 Cooling fan 18 Compressor 19 Fuel tank 23 Condenser 24 Receiver 25 Hydraulic pump 28 Hydraulic oil tank 29 Air conditioner body 31 Board (swivel board)
32R First vertical rib 32L Second vertical rib 41 Mount member 74 Partition wall 75 Plate member 84 Outer wall (floor sheet)
86 Side wall 88 Cover wall 89 Inlet 91 Discharge port 95 Compressor arrangement part 95A Main body part 95B Opening/closing cover 95a Inspection opening 96 Refrigerant pipe line 98 Routing route 101 Intake structure 114 Hydraulic hose (delivery hose)
E1 Prime mover E2 Prime mover room K2 Aircraft width direction V1 Control valve

Claims (12)

The aircraft and
a cabin mounted on the aircraft;
an air conditioner body for indoor air conditioning of the cabin;
a prime mover room that accommodates a prime mover mounted on the aircraft;
Equipped with
The cabin includes a plate member that protrudes rearward from the back surface of the cabin and that is a wall that forms the prime mover room and that is disposed above a wall that covers above the prime mover and is spaced apart from the wall. has
The air conditioner main body is installed on the upper surface side of the plate member, so that the air conditioner main body is disposed above the prime mover chamber and spaced apart from the prime mover chamber. The aircraft and
a cabin mounted on the aircraft;
an air conditioner body for indoor air conditioning of the cabin;
a prime mover room that accommodates a prime mover mounted on the aircraft;
a driver's seat located inside the cabin ;
Equipped with
The air conditioner main body is arranged above the prime mover room,
The cabin includes a plate member located behind the driver's seat and on which the air conditioner main body is installed,
The plate member is arranged above the engine room at a distance from the engine room, and is vibration-proofly supported by the machine body via a mount member. The working machine according to claim 1 or 2, wherein the plate member has a front portion disposed inside the cabin and a rear portion protruding rearward from the back surface of the cabin. The aircraft and
a cabin mounted on the aircraft;
an air conditioner body for indoor air conditioning of the cabin;
a prime mover room that accommodates a prime mover mounted on the aircraft;
a cooling fan that introduces air outside the prime mover room into the prime mover room;
a compressor that is driven by the power of the prime mover to compress refrigerant;
A route for a refrigerant pipe connected to the compressor, the introduction port communicating with the upper part of the engine room to introduce hot air from the engine room, and the introduction port communicating with the outside of the engine room. a distribution route having an outlet for discharging the hot air introduced from the
Equipped with
The air conditioner main body is a working machine disposed above the prime mover room . comprising a compressor arrangement section in which the compressor is arranged,
The routing path includes a pair of side walls that are spaced apart from each other in the width direction of the aircraft, a bottom wall that closes between the rear lower ends of the pair of side walls, and a cover that closes between the upper ends and front ends of the pair of side walls. having a wall;
the introduction port is formed between the bottom wall and the cover wall,
the outlet is formed at a rear part of the cover wall;
The working machine according to claim 4, wherein the compressor arrangement portion is provided below the inlet and communicates with the inlet. The compressor placement section has a main body portion having an inspection opening that opens forward and communicates between the pair of side walls, and an opening/closing cover that closes the inspection opening,
6. The working machine according to claim 5, wherein the opening/closing cover is removable integrally with the cover wall. A condenser that radiates and liquefies the heat of the refrigerant from the compressor and a receiver that stores the refrigerant liquefied by the condenser are disposed on the side of the front part of the cabin and in front of the compressor,
The working machine according to claim 4, wherein the compressor, the condenser, and the receiver are removable from the fuselage together with the cabin. comprising a compressor arrangement section in which the compressor is arranged,
The working machine according to any one of claims 4 to 7, wherein the compressor arrangement section is arranged on one side of the cabin in the width direction of the machine body, and the compressor is accessible from inside the cabin. The fuselage includes a base plate, a first vertical rib provided on the one side of the base plate in the width direction of the fuselage body and extending from the front to the rear of the base plate, and a first vertical rib provided on the other side of the base plate in the width direction of the fuselage body. and a second vertical rib extending from the front to the rear of the substrate,
a hydraulic actuator driven by hydraulic fluid;
a hydraulic oil tank that stores the hydraulic oil;
a hydraulic pump that delivers the hydraulic oil from the hydraulic oil tank;
a control valve that controls the flow rate of the hydraulic oil supplied from the hydraulic pump to the hydraulic actuator;
a hydraulic hose connecting the hydraulic pump and the control valve,
The hydraulic oil tank is arranged on the other side in the width direction of the fuselage than the second vertical rib,
The control valve is disposed on the other side in the width direction of the machine body than the second vertical rib and further forward than the hydraulic oil tank,
The hydraulic pump is disposed on the rear side of the aircraft body relative to the front end of the hydraulic oil tank,
The working machine according to claim 8, wherein the hydraulic hose is routed between the second vertical rib and the hydraulic oil tank. The engine room and the inside of the cabin are separated by a double structure of a partition wall that partitions the engine room and the outside of the engine room and an outer wall of the cabin,
The working machine according to claim 9, wherein the hydraulic oil tank constitutes a part of the partition wall. comprising a fuel tank for storing fuel for the prime mover;
The working machine according to claim 9 or 10, wherein the fuel tank is arranged above the first vertical rib and across the first vertical rib in the width direction of the machine body. The discharge port is provided on one side in the width direction of the aircraft,
an intake structure for introducing air into the prime mover;
The working machine according to claim 4, wherein the intake structure introduces outside air from the other side in the width direction of the machine body.

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