Patent Application
20250207363
The present invention relates to construction machines such as hydraulic excavators.
A hydraulic excavator as a representative example of construction machines is generally provided with an automotive lower traveling structure and an upper revolving structure mounted via a revolving device on the lower traveling structure to be capable of revolving thereto. A working mechanism is rotatably provided on the front side of the upper revolving structure to perform an excavating operation of earth and sand or the like.
In addition, the upper revolving structure is provided
with an engine as a prime mover, an operating oil tank for storing operating oil, a hydraulic pump that is driven by the engine to deliver the operating oil stored in the operating oil tank, and a control valve for travel motor to control the flow of the operating oil that is delivered from the hydraulic pump and is supplied to a hydraulic motor for travel. A hydraulic pipe is arranged in the upper revolving structure and in the lower traveling structure to feed the operating oil to or be discharged from the hydraulic motor for travel, via the hydraulic pump and the like from the operating oil tank.
In recent years, energy saving is desired to hydraulic excavators. In this case, the hydraulic excavator is provided thereon with instrumentation for the energy saving. As a result, the hydraulic excavator is not only limited in space for the instrumentation on the upper revolving structure but also is worsened in the workability on the maintenance and the like of the instrumentation for the energy saving and the existing instrumentation.
Therefore, there are some hydraulic excavators in which an engine, a hydraulic pump, a fuel tank, and an operating oil tank that are generally installed on an upper revolving structure are relocated on a lower traveling structure (Patent Document 1). Because of this configuration, the hydraulic excavator according to Patent Document 1 secures an installation space and an operation space on the upper revolving structure.
Patent Document 1: Japanese Utility Model Laid-Open No. 1-150653 A
The hydraulic excavator according to Patent Document 1 is configured of a small or middle-sized device in which the engine, the hydraulic pump, the fuel tank, the operating oil tank and the like are sized to correspond to the automobile rank. Because of this configuration, the engine, the hydraulic pump, the fuel tank, the operating oil tank and the like are formed in such a size as to be capable of being installed in the lower traveling structure. However, in a large-sized hydraulic excavator to be used in open-pit mining, an engine, a hydraulic pump, a fuel tank, and an operating oil tank and the like are sized to become large according to the automobile rank. Therefore, it is difficult to install the engine, the hydraulic pump, the fuel tank, the operating oil tank and the like in the lower traveling structure. As a result, the large-sized hydraulic excavator is difficult to perform energy saving, and further poses a problem that the workability on the maintenance and the like is worsened due to the installation space in the upper revolving structure being limited. In addition, a hydraulic pipe for connection of the operating oil tank and the hydraulic motor for travel can preferably be arranged as easily as possible and with a high degree of freedom while securing a strength to the extent of withstanding pressure of the operating oil flowing in the hydraulic pipe in consideration of maintainability or the like.
The present invention is made in consideration of the above-mentioned problems of the conventional technology and an object of the present invention is to provide a construction machine that can secure a space for mounting various kinds of equipment devices in an upper revolving structure and facilitate the arrangement of a hydraulic pipe for connection of hydraulic equipment devices to improve the workability of the maintenance and the like.
An aspect of the present invention is provided with a construction machine comprising: an automotive lower traveling structure by a hydraulic motor for travel; and an upper revolving structure mounted via a revolving device on the lower traveling structure to be capable of revolving thereto, the upper revolving structure including: a prime mover; an operating oil tank; a hydraulic pump that is driven by the prime mover to deliver operating oil stored in the operating oil tank, characterized by including: a control valve for travel motor provided in the lower traveling structure to control the flow of the operating oil that is delivered from the hydraulic pump to the hydraulic motor for travel; and a hydraulic pipe that establishes connection between the operating oil tank and the hydraulic motor for travel, wherein the hydraulic pipe includes: a supply pipe part that establishes connection between the operating oil tank, the hydraulic pump and the control valve for travel motor for supply of the operating oil; a high-pressure pipe part that is provided in the lower traveling structure to establish connection between the control valve for travel motor and the hydraulic motor for travel and in which high-pressure operating oil that is delivered from the hydraulic pump and is supplied to the hydraulic motor for travel flows; and a low-pressure pipe part that is provided across from the lower traveling structure to the upper revolving structure to establish connection between the control valve for travel motor and the operating oil tank and in which low-pressure operating oil that is discharged from the hydraulic motor for travel and is returned back from the control valve for travel motor to the operating oil tank flows.
According to the aspect of the present invention, the installation space for the equipment devices can be secured in the upper revolving structure and, for example, the equipment device for energy saving can be mounted therein. In addition, a ratio of the low-pressure pipe parts, which are easy to arrange, of the hydraulic pipe can be made large to secure the working space for the maintenance and the like and improve the workability.
Hereinafter, a hydraulic excavator that is taken as a representative example of a construction machine according to an embodiment of the present invention will in detail be explained referring to
In
the upper revolving structure 3 on the lower traveling structure 15. The revolving device 2 is provided with a revolving wheel 2A composed of a ring-shaped bearing provided between a truck frame 16 of the lower traveling structure 15 and a revolving frame 5 of the upper revolving structure 3, and a revolving motor (not shown) that engages with an inner ring of the revolving wheel 2A to revolve the upper revolving structure 3.
The upper revolving structure 3 is provided with the revolving frame 5 formed as a support structure on the front side of which the working mechanism 4 is provided, a cab 6 that is mounted on the left front side of the revolving frame 5 to form an operator's room inside, a counterweight 7 that is attached to the rear part of the revolving frame 5 to act as a weight balance to the working mechanism 4, and a housing 8 that is positioned between the cab 6 and the counterweight 7 to accommodate an after-mentioned engine 9 mounted on the revolving frame 5, and the like therein. An operator's seat on which an operator sits and control devices that are positioned respectively on the front side, on the left side and on the right side of the operator's seat to control the hydraulic excavator 1 (any one of them is not shown) are provided inside the cab 6.
The engine 9 as a prime mover is provided on the revolving frame 5 to be positioned in front of the counterweight 7. The engine 9 is configured as a diesel engine, for example. The engine 9 is singularly provided in a horizontal state to extend in a left-right direction on the rear side of the revolving frame 5. For example, after-mentioned hydraulic pumps 10 are attached on the right side to the engine 9. In addition, a heat exchange device composed of a radiator, an oil cooler, a capacitor and the like (any one of them is not shown) is arranged on the left side to the engine 9.
It should be noted that a hybrid prime mover composed of a combination of a diesel engine and an electric motor or an electric motor unit may be used as the prime mover. On the other hand, the prime mover may be provided in a longitudinal state to extend in a front-back direction of the upper revolving structure 3. In addition, two prime movers may be mounted to line up in the left-right direction.
The hydraulic pumps 10 are attached to the right side to the engine 9. The hydraulic pumps 10 include a main pump that delivers operating oil (pressurized oil) for operating a hydraulic actuator of the working mechanism 4, a revolving motor of the revolving device 2, a hydraulic motor 20 for travel of the lower traveling structure 15 and the like, and a pilot pump that delivers operating oil (pressurized oil) for operating control valves (including a control valve 23 for travel motor) that control these hydraulic actuators. The plurality of hydraulic pumps 10 are configured of a swash plate hydraulic pump of variable displacement type, a bent axis hydraulic pump, an axial piston type hydraulic pump, or the like.
A center joint 11 is provided between the lower traveling structure 15 and the upper revolving structure 3 to be positioned in a center of the revolving wheel 2A (a cylindrical part 17A of an after-mentioned center frame 17) of the revolving device 2 serving as a revolving center. The center joint 11, even in a case where the upper revolving structure 3 revolves relative to the lower traveling structure 15, can make circulation of operating oil for operating the hydraulic actuators, pilot operating oil for operating the control valve 23 for travel motor and the like, and electricity (signals) between the lower traveling structure 15 and the upper revolving structure 3.
The center joint 11 includes a body to be attached to the revolving frame 5 of the upper revolving structure 3 and a spindle that is rotatably provided inside the body in a state of projecting to the lower side from the body and is attached to the truck frame 16 of the lower traveling structure 15. In addition, the center joint 11 is provided with a plurality of circular oil paths extending in a circumferential direction between the body and the spindle and a plurality of oil paths that open to an outer surface of the body and an outer surface of the spindle in a state of being communicated individually with the plurality of circular oil paths (any one of them is not shown).
In addition, a high-pressure pipe part 25B on the pump side to be described later, a low-pressure pipe part 25G on the tank side, a harness on the pump side (any one of them is not shown) and the like are connected to the body. On the other hand, a high-pressure pipe part 25C on the valve side, a low-pressure pipe part 25F on the valve side, a pilot pipe part on the valve side, a harness on the valve side (any one of them is not shown) and the like are connected to the spindle.
As schematically shown in
A control valve device 13 is provided on the revolving frame 5 to be positioned in front of the engine 9. The control valve device 13 includes, for example, a manifold composed of a block-shaped structure and a plurality of control valves attached to the manifold. The control valve device 13 (control valve) controls the flow of operating oil that is delivered to the hydraulic actuator of the working mechanism 4 and the revolving motor of the revolving device 2 from the hydraulic pump 10.
Here, the control valve device 13, as the after-mentioned control valves 23 for travel motor are relocated to the lower traveling structure 15-side, can be downsized by a size of the control valves 23 for travel motor. In addition, for installing the control valves 23 for travel motor, spaces for performing the maintenance to pipes of the control valves 23 for travel motor, connection parts of hoses, and between surrounding valves and structures are required. On the other hand, relocating the control valves 23 for travel motor enables these spaces to be omitted, thereby downsizing the control valve device 13 furthermore.
A control valve device 14 for pilot is provided on the revolving frame 5 to be positioned, for example, in back of the control valve device 13. The control valve device 14 for pilot includes, as similar to the control valve device 13, a manifold and a plurality of control valves. The control valve device 14 for pilot controls the flow of operating oil for pilot to be supplied to the control valves of the control valve device 13 and the after-mentioned control valves 23 for travel motor. It should be noted that the control valve device 14 for pilot may be installed to the lower traveling structure 15.
The lower traveling structure 15 travels due to rotation of driving wheels 19 caused by the after-mentioned hydraulic motors 20 for travel. The lower traveling structure 15 is provided with the after-mentioned truck frame 16, the driving wheels 19, the hydraulic motors 20 for travel, idler wheels 21, crawler tracks 22, the control valves 23 for travel motor, brake valves 24, and a hydraulic pipe 25.
The truck frame 16 is provided with the center frame 17 positioned in the center and the side frames 18 provided on the center frame 17 in both of the left and right sides (refer to
Further, as shown in
The side frames 18 are provided on both of the left and right sides of the center frame 17, specifically tip end parts of the front leg part 17B and the rear leg part 17C on the left side and tip leg parts of the front leg part 17B and the rear leg part 17C on the right side to extend in the front-back direction.
As shown in
As shown in
The idler wheel 21 is rotatably provided in the front part of the side frame 18 at the opposite side to the driving wheel 19 in the front-back direction (only the right side in
Here, in the lower traveling structure 15 the driving wheel 19 is located on the rear side so that the ground side of the crawler track 22 is tensed in the forward travel to be used heavily. The front-back direction of the lower traveling structure 15 is determined based upon this configuration. It should be noted that the front-back direction of the lower traveling structure 15 corresponds to the forward direction and the rearward direction of the lower traveling structure 15. On the other hand, in a state where the upper revolving structure 3 is revolved by 180 degrees on the lower traveling structure 15, the front-back direction becomes the opposite as viewed from the upper revolving structure 3.
The control valves 23 for travel motor are attached to the lower traveling structure 15. The control valves 23 for travel motor correspond to the two hydraulic motors 20 for travel provided in the left driving wheel 19 to comprise two control valves for travel motor attached to the left valve attaching surface 17D and correspond to the two hydraulic motors 20 for travel provided in the right driving wheel 19 to comprise two control valves for travel motor attached to the right valve attaching surface 17D. The control valve 23 for travel motor is composed of a pilot type switching valve that controls the flow of operating oil to be delivered to the hydraulic motor 20 for travel from the hydraulic pump 10. That is, the control valve 23 for travel motor can switch the rotating direction (forward direction and reverse direction) of the hydraulic motor 20 for travel.
Here, as shown in
In addition, by utilizing the rear surface of the center frame 17 to install the control valves 23 for travel motor, the control valves 23 for travel motor can be arranged in the intermediate position between the center joint 11 and the hydraulic motors 20 for travel. According to this configuration, the hydraulic pipe 25 can be shortened and orderly be arranged, therefore improving the workability on the assembling work, the maintenance and the like. In addition, it is possible to facilitate the maintenance of the control valves 23 for travel motor arranged on the rear surface of the center frame 17.
The brake valves 24 are attached via the control valves 23 for travel motor to the lower traveling structure 15. The brake valves 24 correspond to, as similar to the control valves 23 for travel motor, the two hydraulic motors 20 for travel provided in the left driving wheel 19 to comprise two brake valves 24 attached to overlap with the left the control valves 23 for travel motor. In addition, the brake valves 24 correspond to the two hydraulic motors 20 for travel provided in the right driving wheel 19 to comprise two brake valves 24 attached to overlap with the right the control valves 23 for travel motor. The brake valve 24 limits the flow of operating oil to apply a brake to the hydraulic motors 20 for travel.
Further, as to the brake valves 24, as similar to the control valves 23 for travel motor, the brake valve 24 positioned on the inner side is located to shift to a position higher than the brake valve 24 positioned on the outer side. Because of this configuration, even in a case where the two brake valves 24 are arranged to line up, the working space can be secured to facilitate the maintenance of inspection, repair, replacement and the like. In addition, since the brake valve 24 is attached to overlap with the control valve 23 for travel motor, an attaching space is not required on the valve attaching surface 17D, and furthermore, the pipe for connection of the control valve 23 for travel motor and the brake valve 24 can be omitted.
As schematically shown in
The configuration of the hydraulic pipe 25 will specifically be explained along a flow direction of operating oil. The hydraulic pipe 25 is configured of the supply low-pressure pipe part (supply pipe part) 25A for connection between the operating oil tank 12 and the hydraulic pump 10, the pump-side high-pressure pipe part (supply pipe part) 25B for connection between the hydraulic pump 10 and the center joint 11, the valve-side high-pressure pipe part (supply pipe part) 25C for connection between the center joint 11 and the control valve 23 for travel, the two switching high-pressure pipe parts (high-pressure pipe parts) 25D, 25E for connection between the brake valve 24 and the hydraulic motor 20 for travel, the valve-side low-pressure pipe part (low-pressure pipe part) 25F for connection between the control valve 23 for travel motor and the center joint 11, and the tank-side low-pressure pipe part (low-pressure pipe part) 25G for connection between the center joint 11 and the operating oil tank 12. The high-pressure operating oil flows into one, which acts as the supply side, of the two switching high-pressure pipe parts 25D, 25E and the low-pressure operating oil flows into the other which acts as the return side.
The high-pressure pipe parts composed of the pump-side high-pressure pipe part 25B, the valve-side high-pressure pipe part 25C and the two switching high-pressure pipe parts 25D, 25E are formed with materials and structures that are high in durability to be capable of withstanding the pressure of the operating oil delivered from the hydraulic pump 10. The pipe to be used in the high-pressure pipe part includes a metallic pipe and a hose. In a case where the high-pressure pipe part is composed of a metallic pipe, a thick metallic pipe, a metallic pipe high in strength of a material or the like is used. In addition, in a case where the high-pressure pipe part is composed of a hose, there is used a thick pressure-resistant hose composed of a plurality of layers composed of radially overlayed materials with strength. Therefore, the high-pressure pipe part, as compared to the low-pressure pipe part, requires a larger arrangement space, is more expensive and is more difficult in processing and maneuverability.
The low-pressure pipe parts composed of the supply low-pressure pipe part 25A, the valve-side low-pressure pipe part 25F and the tank-side low-pressure pipe part 25G only require durability to the extent of being capable of withstanding the pressure when the operating oil returned back to the operating oil tank 12 in an atmospheric air state flows therein. The pipe to be used in the low-pressure pipe part includes, as similar to the high-pressure pipe part, a metallic pipe and a hose. In a case where the low-pressure pipe part is composed of a metallic pipe, a metallic pipe that is thin and is low in strength or the like is used. In addition, in a case where the low-pressure pipe part is composed of a hose, there may be used a hose low in strength. Therefore, the low-pressure pipe part, as compared to the high-pressure pipe part, can make the arrangement space smaller by using a narrow pipe and hose and besides, is higher in a freedom degree of bending at the arrangement, is less expensive and is easier in processing and maneuverability.
The valve-side high-pressure pipe part 25C and the valve-side low-pressure pipe part 25F, which are arranged in the center frame 17, of the hydraulic pipe 25 extend upwards along the valve attaching surface 17D from the control valve 23 for travel motor, thereafter bend in a position of an upper surface of the rear leg part 17C to extend to the front side, bend to the cylindrical part 17A-side in the lateral portion position of the cylindrical part 17A, and is connected through the lateral portion of the cylindrical part 17A to the center joint 11.
Here, as shown in
Because of this configuration, even when stones or the concrete pieces bounce on the crawl track 22 to fly to the center frame 17-side, since the valve-side high-pressure pipe part 25C having high strength is located in a position close to the crawler track 22, the valve-side low-pressure pipe part 25F can be protected from stones, the concrete pieces and the like.
In this case, a path in which high-pressure operating oil flows is switched following the switching of the forward rotation and the reverse rotation of the hydraulic motor 20 for travel between the control valve 101 for travel motor and the hydraulic motor 20 for travel. Therefore, all pipe parts of a pipe between the control valve 101 for travel motor and the hydraulic motor 20 for travel are composed of high-pressure pipe parts. That is, the low-pressure pipe parts in the comparative example in
On the other hand, in the present embodiment shown in
For example, in the present embodiment the tank-side low-pressure pipe part 25G, that is, the pipe for connection of the center joint 11 and the operating oil tank 12 can be arranged directly (without via the control valve 23 for travel motor) within the upper revolving structure 3. Therefore, for example, the tank-side low-pressure pipe part 25G can be made shorter than the pipe length of the tank-side high-pressure pipe part 102H and the tank-side low-pressure pipe part 102J in the comparative.
The hydraulic excavator 1 according to the present embodiment has the configuration as described above, and hereinafter, an explanation will be made of the operation of the hydraulic excavator 1.
An operator who has boarded on the cab 6 starts up the engine 9 to drive the hydraulic pump 10. In this state, the operator operates the control device for travel, thus making it possible to move the lower traveling structure 15 forward or backward. In addition, the operator operates the control device for working, thus making it possible to rotate the working mechanism 4 to perform an excavating operation of earth and sand or the like.
Here, the flow of the operating oil at the time of causing the lower traveling structure 15 to travel will be described. When the hydraulic pump 10 is driven by the engine 9 and the operating oil is supplied to the hydraulic pump 10 through the supply low-pressure pipe part 25A from the operating oil tank 12, the high-pressure operating oil is delivered from the hydraulic pump 10. In addition, the operating oil is supplied through the supply pipe parts composed of the pump-side high-pressure pipe part 25B and the valve-side high-pressure pipe part 25C to the control valve 23 for travel motor. The control valve 23 for travel motor is switched based upon a control signal to be supplied through a pilot pipe part, and for example, the operating oil is supplied to the hydraulic motor 20 for travel from the switching high-pressure pipe part 25D (high-pressure pipe part). On the other hand, the operating oil that has driven the hydraulic motor 20 for travel is returned back through the switching high-pressure pipe part 25E to the control valve 23 for travel motor, and further, is returned back through the low-pressure pipe parts composed of the valve-side low-pressure pipe part 25F and the tank-side low-pressure pipe part 25G to the operating oil tank 12.
Thus, in the present embodiment the hydraulic excavator 1 includes: the automotive lower traveling structure 15 by the hydraulic motor 20 for travel; and the upper revolving structure 3 mounted via the revolving device 2 on the lower traveling structure 15 to be capable of revolving thereto. On top of that, there is provided the control valve 23 for travel motor to control the flow of the operating oil that is delivered from the hydraulic pump 10 to the hydraulic motor 20 for travel, and the control valve 23 for travel motor is attached to the lower traveling structure 15.
As a result, since the control valve device 13 mounted on the upper revolving structure 3 can be downsized by a size of the control valves 23 for travel motor, the installation space can be secured in the upper revolving structure 3 by a size to the extent that the control valve device 13 is downsized. In addition, the space for inspection, repair, replacement and the like of the equipment devices composed of the engine 9, the hydraulic pump 10, the control valve device 13 and the like mounted on the upper revolving structure 3 can be secured thereon. As a result, the space for installing the equipment devices necessary for the energy saving of the hydraulic excavator 1 can be secured and the workability at the time of performing the maintenance of the equipment devices including the equipment devices for energy saving can improve.
Also, in the present embodiment the hydraulic pipe 25 establishes the connection between the operating oil tank 12 and the hydraulic motor 20 for travel. The hydraulic pipe 25 is configured of the supply low-pressure pipe part 25A, the pump-side high-pressure pipe part 25B and the valve-side high-pressure pipe part 25C as the supply pipe parts that establish the connection between the operating oil tank 12, the hydraulic pump 10 and the control valve 23 for travel motor to supply the operating oil thereto, the two switching high-pressure pipe parts 25D, 25E as the high-pressure pipe parts that are provided on the lower traveling structure 15 to establish the connection between the control valve 23 for travel motor and the hydraulic motor 20 for travel, wherein the high-pressure operating oil that is delivered from the hydraulic pump 10 and is supplied to the hydraulic motor 20 for travel flows in the high-pressure pipe parts, and the valve-side low-pressure pipe part 25F and the tank-side low-pressure pipe part 25G as the low-pressure pipe parts that are provided across from the lower traveling structure 15 to the upper revolving structure 3 to establish the connection between the control valve 23 for travel motor and the operating oil tank 12, wherein the low-pressure operating oil that is discharged from the hydraulic motor 20 for travel and is returned back to the operating oil tank 12 from the control valve 23 for travel motor flows in the low-pressure pipe parts.
Therefore, in the present embodiment a ratio of the low-pressure pipe parts relative to the entire length of the hydraulic pipe 25 is high (a ratio of the high-pressure pipe parts is small), and the freedom degree and the easiness of the arrangement of the hydraulic pipe 25 and the easiness of the removal thereof improve as a whole. Besides, the improvement effect of the maintenance and the reduction effect of costs on the hydraulic pipe 25 can be obtained.
The lower traveling structure 15 is provided with the truck frame 16 having the center frame 17 and the side frames 18 extending in the front-back direction on both of the left and right sides of the center frame 17, the driving wheels 19 that are provided on the rear parts of the side frames 18 and rotated by the hydraulic motors 20 for travel, the idler wheels 21 provided on the front parts of the side frames 18, and the crawler tracks 22 each of which is wound around between the driving wheel 19 and the idler wheel 21. The center frame 17 is provided with the valve attaching surface 17D on the rear surface facing the hydraulic motor 20 for travel in the front-back direction. On top of that, the control valve 23 for travel motor is attached on the valve attaching surface 17D of the center frame 17.
Therefore, the control valve 23 for travel motor is installed by utilizing the rear surface of the center frame 17, thereby making it possible to be located in the intermediate position between the center joint 11 and the hydraulic motor 20 for travel. Because of this configuration, the hydraulic pipe 25 can be arranged shortly and orderly to improve the workability of the assembly work, the maintenance and the like. In addition, the control valve 23 for travel motor provided on the rear surface of the center frame 17 is easy to reach, thereby making it possible to be easily subject to maintenance.
The center joint 11 is provided in the revolving center position of the revolving device 2 to cause the operating oil to flow between the lower traveling structure 15 and the upper revolving structure 3. The brake valve 24 for giving a brake to the hydraulic motor 20 for travel is provided in the lower traveling structure 15. The hydraulic pipe 25 is provided for connection of the operating oil tank 12 and the hydraulic motor 20 for travel via the hydraulic pump 10, the center joint 11, the control valve 23 for travel motor and the brake valve 24. In addition, the valve-side low-pressure pipe part 25F and the tank-side low-pressure pipe part 25G as the low-pressure pipe parts are provided via the center joint 11 across the upper revolving structure 3 and the lower traveling structure 15. On top of this, the valve-side low-pressure pipe part 25F of the low-pressure pipe part between the center joint 11 and the control valve 23 for travel motor is arranged through a position more separate from the crawler track 22 than the valve-side high-pressure pipe part 25C as the high-pressure pipe part.
Because of this configuration, even when stones or concrete pieces are bounced by the crawler track 22 to fly to the center frame 17-side, the valve-side high-pressure pipe part 25C composed of a pipe with high strength is located in a position close to the crawler track 22. As a result, since the valve-side low-pressure pipe part 25F is far from a place where stones or concrete pieces are caused to fly and the valve-side high-pressure pipe part 25C acts as a wall against the flying stones or concrete pieces, the valve-side low-pressure pipe part 25F can be protected from stones, concrete pieces or the like.
The control valve 23 for travel motor comprises a plurality of control valves that are provided in positions lining up in the left-right direction and in positions shifting in the upper-lower direction, and, for example, two control valves are provided in the left and right positions respectively. Therefore, even when two control valves 23 for travel motor are located to line up in positions close from each other, the working space for hanging up tools and the like can be secured by changing the height position, thus facilitating the maintenance of inspection, repair, replacement and the like.
It should be noted that there is shown as an example a case where the embodiment is configured so that the valve-side high-pressure pipe part 25C and the valve-side low-pressure pipe part 25F of the hydraulic pipe 25 pass through the lateral portion (side frame 18-side) of the cylindrical part 17A in the center r frame 17. However, the present invention is not limited to this configuration but, for example, may be configured so that a valve-side high-pressure pipe part and a valve-side low-pressure pipe part of a hydraulic pipe pass through a rear portion of a cylindrical part in a center frame.
There is shown as an example a case where the embodiment is configured so that the control valve 23 for travel motor is attached to the valve attaching surface 17D of the center frame 17 and the brake valve 24 is attached to overlap with the control valve 23 for travel motor. However, the present invention is not limited to this configuration but, for example, may be configured so that a brake valve is attached directly to a valve attaching surface of a center frame. In this case, the connection between a control valve for travel motor and a brake valve is established by a high-pressure pipe part.
It should be noted that the embodiment is explained by taking as an example a case of the hydraulic excavator 1 provided with the working mechanism 4 of a backhoe type as the construction machine. However, the present invention is not limited thereto, but may be applied widely also to other construction machines including a hydraulic excavator provided with a working mechanism of a loading excavator type.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2022-066149 | Apr 2022 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2023/013560 | 3/31/2023 | WO |
