JP7495869B2 - Construction Machinery - Google Patents

Description

This disclosure relates to construction machinery such as hydraulic excavators, hydraulic cranes, and wheel loaders.

Generally, a hydraulic excavator, a typical example of construction machinery, is equipped with a vehicle body capable of travelling, an engine mounted on the vehicle body, and an exhaust gas purification device that purifies the exhaust gas from the engine. For example, the exhaust gas purification device uses a urea SCR system (SCR: Selective Catalytic Reduction) that purifies nitrogen oxides (NOx) in the exhaust gas of a diesel engine.

In this case, as described in Patent Document 1, for example, the exhaust gas purification device includes a urea selective reduction catalyst connected to the exhaust pipe of the engine to remove nitrogen oxides from the exhaust gas, a urea water injection valve that injects urea water, which is a liquid reducing agent, upstream of the urea selective reduction catalyst, and a urea water tank that stores the urea water to be supplied to the urea water injection valve. The urea water tank is provided with a water supply port for supplying urea water from the outside.

JP 2015-121102 A (Patent No. 5965892 A)

According to the conventional technology described in Patent Document 1, when supplying (feeding, replenishing) urea water to a urea water tank, the worker performing this task needs to continue to hold the replenishing tank that stores the urea water. The capacity of the urea water replenishing tank, also known as a BIB (bag-in-box), is, for example, about 20 L, and since it is heavy, the task can be a burden for the worker performing the task of replenishing the urea water.

The objective of one embodiment of the present invention is to provide a construction machine that can reduce the burden on the worker who supplies (replenishes) urea water from the supply tank (BIB) to the urea water tank.

One embodiment of the present invention is a construction machine equipped with a urea water tank arranged on a vehicle body for storing urea water, which is a reducing agent for a urea selective reduction catalyst that removes nitrogen oxides from exhaust gas, and a tank housing case arranged on the vehicle body for housing the urea water tank. The tank housing case is arranged above the urea water tank housed in the tank housing case and has an upper surface portion that covers the urea water tank from above, a recessed portion arranged on the upper surface portion that is recessed downward from the upper surface of the upper surface portion, and a refill port arranged on the bottom of the recess portion for refilling the urea water tank with urea water.

According to one embodiment of the present invention, the burden on the worker who supplies (replenishes) urea water from the supply tank to the urea water tank can be reduced.

FIG. 1 is a right side view showing a hydraulic excavator according to an embodiment. FIG. 2 is a plan view showing the state in which an engine, a fuel tank, a hydraulic oil tank, a tank storage case, a tool storage case, etc. are mounted on a rotating frame of a hydraulic excavator. 1 is a perspective view of the right front portion of the revolving frame, the tank storage case, the tool storage case, etc., as viewed from the right front side. FIG. 4 is a perspective view of the tank housing case with the cover open, taken from the same position as in FIG. 3 . 3 is a cross-sectional view taken along the direction of arrows VV in FIG. 2. FIG. 4 is an explanatory diagram showing a procedure for replenishing (supplying) urea water from the replenishing tank to the urea water tank. 6 is a cross-sectional view taken in the same position as FIG. 5 , illustrating a state in which the urea water tank is being refilled with the urea water from the refill tank. 8 is a plan view of the bottom of the recess as viewed from the direction of arrows VIII-VIII in FIG. 6. FIG. 2 is a cross-sectional view of the water supply cap (lid body). FIG. 6 is a cross-sectional view taken in the same position as in FIG. 5, showing a modified example.

The following describes in detail an embodiment of the present invention as applied to a construction machine in a hydraulic excavator, with reference to the accompanying drawings.

Figures 1 to 9 show an embodiment. In Figure 1, a hydraulic excavator 1, which is a representative example of a construction machine, is configured as a crawler-type hydraulic excavator. That is, the hydraulic excavator 1 as a construction machine is equipped with a crawler-type lower traveling body 2 capable of traveling, a swivel device 3 provided on the lower traveling body 2, an upper rotating body 4 mounted on the lower traveling body 2 so as to be rotatable via the swivel device 3, and a front working device 5 (hereinafter referred to as working device 5) of a multi-joint structure that is provided in front of the upper rotating body 4 and performs excavation work and the like. In this case, the lower traveling body 2 and the upper rotating body 4 form the vehicle body (hydraulic excavator main body) of the hydraulic excavator 1.

The lower traveling body 2 is equipped with left and right traveling hydraulic motors (not shown) that rotate the left and right tracks 2A. The upper rotating body 4 is mounted on the lower traveling body 2 via a rotating device 3 that includes a rotating bearing, a rotating hydraulic motor, a reduction mechanism, etc. The working device 5 is equipped with, for example, a boom 5A, an arm 5B, and a bucket 5C as a working tool. The working device 5 is equipped with a boom cylinder 5D that drives the boom 5A, an arm cylinder 5E that drives the arm 5B, and a bucket cylinder 5F that drives the bucket 5C as a working tool cylinder.

The upper rotating body 4 is configured to include a rotating frame 6 that forms a support structure, a counterweight 7 that is provided on the rear side of the rotating frame 6 and balances the weight with the work device 5, a cab 8 that is provided on the front left side of the rotating frame 6 and in which the operator sits, and a building cover 9 that is provided on the front side of the counterweight 7 and houses the engine 10, the heat exchanger 12, and the exhaust gas aftertreatment device 17 that constitutes the exhaust gas purification device 16. In the embodiment, the upper rotating body 4 is equipped with the engine 10, the exhaust gas purification device 16 (urea selective reduction catalyst 17B, urea water tank 18, etc.), and a tank housing case 21.

The revolving frame 6 is also called the vehicle body frame, and constitutes a support structure for the upper revolving body 4. As shown in FIG. 2, the revolving frame 6 includes a thick bottom plate 6A extending in the front and rear directions, a left vertical plate 6B and a right vertical plate 6C standing on the bottom plate 6A and extending in the front and rear directions at a predetermined interval in the left and right directions, a plurality of overhanging beams 6D extending outward in the left and right directions from the bottom plate 6A or each vertical plate 6B, 6C and arranged at intervals in the front and rear directions, and a left side frame 6E and a right side frame 6F located on the outside in the left and right directions, attached to the tip of each overhanging beam 6D, and extending in the front and rear directions.

As shown in Figures 3 and 4, the front right side of the revolving frame 6 is provided with a front beam 6G extending leftward from the front end of the right side frame 6F, and an undercover (not shown) that covers the space between the right edge of the bottom plate 6A and the right side frame 6F. The front right side of the revolving frame 6 forms the bottom side of the tank storage case 21, which will be described later. A rectangular footrest plate 6H is provided on the front beam 6G and protrudes forward. The footrest plate 6H constitutes the first step on which a worker performing maintenance on the engine 10, etc., places his or her feet when climbing from the lower running body 2 onto the upper revolving body 4.

Inside the cab 8, there is a driver's seat where the operator sits, and a travel lever/pedal operation device and a work lever operation device (neither of which are shown), which are operation devices for operating the hydraulic excavator 1. By operating the travel lever/pedal operation device and the work lever operation device, the operator can perform travel operations using the lower traveling body 2, rotation operations using the upper rotating body 4, excavation work using the work device 5, and the like.

As shown in FIG. 2, the engine 10 is mounted on the rear side of the revolving frame 6. In this case, the engine 10 is located in front of the counterweight 7 and is installed horizontally on the revolving frame 6, extending left and right. The engine 10 constitutes the prime mover (drive source) of the hydraulic excavator 1, and is composed of a diesel engine (internal combustion engine). A cooling fan 10A is provided on the left side of the engine 10 to supply cooling air to the heat exchanger 12. Meanwhile, a hydraulic pump 13 is provided on the right side of the engine 10.

An exhaust pipe 11 for discharging exhaust gas is connected to the engine 10. The exhaust pipe 11 is formed as a metallic exhaust pipe line that extends left and right along the front side of the engine 10. The exhaust pipe 11 guides the high-temperature exhaust gas discharged from the engine 10 to the exhaust gas aftertreatment device 17.

The heat exchanger 12 is disposed on the left side of the engine 10. The heat exchanger 12 faces the cooling fan 10A of the engine 10. The heat exchanger 12 is composed of, for example, a radiator that cools the engine coolant, an oil cooler that cools the hydraulic oil, and an intercooler that cools the air drawn into the engine 10.

The hydraulic pump 13 is provided on the right side of the engine 10. Driven by the engine 10, the hydraulic pump 13 discharges hydraulic oil stored in the hydraulic oil tank 14 as pressurized oil. The pressurized oil discharged from the hydraulic pump 13 is supplied to hydraulic actuators (e.g., boom cylinder 5D, arm cylinder 5E, bucket cylinder 5F, swing hydraulic motor, and traveling hydraulic motor) via a control valve device (not shown).

The hydraulic oil tank 14 is located in front of the hydraulic pump 13 and is provided on the right side of the revolving frame 6. The hydraulic oil tank 14 stores hydraulic oil for driving the hydraulic actuator. Meanwhile, the fuel tank 15 is located in front of the hydraulic oil tank 14 and is provided on the revolving frame 6.

The control valve device is a group of control valves consisting of multiple directional control valves. The control valve device distributes the pressurized oil discharged from the hydraulic pump 13 to the hydraulic actuators in response to the operation of the travel lever/pedal operation device and the work lever operation device in the cab 8. In other words, the control valve device supplies or discharges the pressurized oil discharged from the hydraulic pump 13 to the hydraulic actuators in response to the lever and pedal operation of the travel lever/pedal operation device and the work lever operation device by the operator.

The exhaust gas purification device 16 purifies the exhaust gas from the engine 10. The exhaust gas purification device 16 removes harmful substances in the exhaust gas discharged from the engine 10. The exhaust gas purification device 16 is equipped with a soundproofing mechanism for reducing the noise of the exhaust gas. The exhaust gas purification device 16 is equipped with an exhaust gas post-treatment device 17 having a urea selective reduction catalyst 17B and a urea water injection valve (not shown), a urea water tank 18 described later, a urea water supply line (not shown) connecting the urea water injection valve (not shown) of the exhaust gas post-treatment device 17 and the urea water tank 18, and a urea water supply device (not shown) provided in the urea water supply line for supplying the urea water from the urea water tank 18 to the urea water injection valve.

The exhaust gas aftertreatment device 17 is connected to the outlet side of the exhaust pipe 11. The exhaust gas aftertreatment device 17 is also called a NOx purification device, and purifies nitrogen oxides (NOx) in the exhaust gas using urea water (urea aqueous solution) as a reducing agent. The exhaust gas aftertreatment device 17 is composed of a storage cylinder 17A connected to the exhaust pipe 11, a urea selective reduction catalyst 17B stored on the upstream side within the storage cylinder 17A, an oxidation catalyst 17C arranged on the downstream side of the urea selective reduction catalyst 17B, and a urea aqueous solution injection valve provided on the upstream side of the urea selective reduction catalyst 17B.

The urea selective reduction catalyst 17B removes nitrogen oxides (NOx) from the exhaust gas. That is, the urea selective reduction catalyst 17B selectively reduces the nitrogen oxides contained in the exhaust gas discharged from the engine 10 with ammonia generated from urea water (urea aqueous solution), and breaks them down into nitrogen and water. The urea water injection valve is connected to the urea water tank 18 via a urea water supply line or the like. The exhaust gas post-treatment device 17 injects urea water into the exhaust gas using the urea water injection valve, and reduces the NOx in the exhaust gas using the ammonia generated from the urea water by the urea selective reduction catalyst 17B, breaking it down into water and nitrogen. The oxidation catalyst 17C reduces the ammonia in the exhaust gas.

The urea water tank 18 stores urea water, which is a reducing agent (liquid reducing agent) for the urea selective reduction catalyst 17B. As shown in Figures 2 to 7, the urea water tank 18 is provided on the revolving frame 6, located forward of the fuel tank 15, as an example of an installation location. That is, the urea water tank 18 is disposed on the vehicle body (upper revolving body 4), specifically, in front of the revolving frame 6, and on the opposite side of the vehicle body (vehicle) from the cab 8 in the left-right direction across the work implement 5. The urea water tank 18 is connected to the urea water injection valve via a urea water supply pipe and a urea water supply device. The urea water in the urea water tank 18 flows through the urea water supply pipe by driving the urea water supply device and is supplied to the urea water injection valve.

However, according to the conventional technology described above, when supplying (feeding, replenishing) urea water to a urea water tank, the worker performing this task needs to continue to hold the replenishing tank that stores the urea water. The capacity of the urea water replenishing tank, also known as a BIB (bag-in-box), is, for example, about 20 L, and since it is heavy, this task can be a burden for the worker performing the task of replenishing the urea water.

In this embodiment, the following configuration is adopted to reduce the burden on the worker who supplies (replenishes) urea water from the refill tank (BIB) to the urea water tank. That is, in this embodiment, a refill port 28 is provided on the tank housing case 21 that covers the urea water tank 18. This refill port 28 is provided on a surface that is one step lower than the top surface 23, which is the outermost surface (top surface) of the tank housing case 21, i.e., on the bottom 27A of a recess 27 provided on the top surface 23 of the tank housing case 21.

The supply port 28 of the tank housing case 21 and the water supply port 18A of the urea water tank 18 are connected via a urea water supply pipe 34. Therefore, as shown in FIG. 7, the work of replenishing urea water from a supply tank 51, also called a BIB (bag-in-box), to the urea water tank 18 can be performed with the supply tank 51 placed on the tank housing case 21 (on the upper surface 23). As a result, the worker performing the replenishing work does not need to continue holding the supply tank 51 during the water supply work, reducing the burden on the worker.

The following describes the structure of the right front side of the upper rotating body 4, including the tank housing case 21, the urea water tank 18, etc., in accordance with the embodiment, with reference to Figures 3 to 9.

As shown in FIG. 3, on the right front side of the vehicle body (upper rotating body 4), i.e., on the right front side opposite the cab 8 at the front position of the rotating frame 6, there are provided a tank housing case 21 that houses the urea water tank 18 inside, and a tool housing case 41 that is disposed above the tank housing case 21 and houses tools inside. In other words, on the front right side of the rotating frame 6, the tank housing case 21 and the tool housing case 41 are provided, positioned in front of the fuel tank 15.

The tank storage case 21 is a hollow rectangular parallelepiped structure made up of a front portion 22 that rises from the front edge of the front beam 6G of the revolving frame 6, an upper portion 23 that extends rearward from the upper edge of the front portion 22, a rear portion (not shown) that extends downward from the rear edge of the upper portion 23 while facing the front surface of the fuel tank 15, and a left side portion 24 (see FIG. 5, etc.) and a right side portion 25 that are erected to sandwich the front portion 22 and the rear portion.

The rear surface of the tank storage case 21 can be omitted if the front surface of the fuel tank 15 closes the rear of the tank storage case 21 instead. The top surface 23 of the tank storage case 21, together with the opening and closing cover 26, forms the second step leading to the footrest 6H of the swivel frame 6.

The tool storage case 41 is provided at the upper position of the tank storage case 21. The front-to-rear length of the tool storage case 41 is set to be approximately half the front-to-rear length of the tank storage case 21. The tool storage case 41 is attached to the rear half of the top surface 23 of the tank storage case 21.

The interior of the tool storage case 41 can store tools such as wrenches, drivers, and bolts required for maintenance work. The tool storage case 41 is equipped with an opening/closing cover 42 that is opened and closed when inserting and removing tools. The opening/closing cover 42 forms the third step following the top surface 23 (opening/closing cover 26) of the tank storage case 21.

The tank storage case 21 has a large storage space inside by utilizing the space above the undercover of the revolving frame 6, which is surrounded by the "right vertical plate 6C of the revolving frame 6," the "extension beam located at the front right side (not shown)," the "front portion of the right side frame 6F," and the "front beam 6G." The urea water tank 18 is placed in the storage space inside the tank storage case 21.

The urea water tank 18 is located inside the tank housing case 21 and is attached to the undercover of the revolving frame 6. The urea water tank 18 has a water supply port 18A that supplies urea water to the inside. The water supply port 18A is provided on the upper side of the urea water tank 18. The water supply port 18A is provided in a position that faces the supply port 28 of the tank housing case 21 in the upward and downward directions when the urea water tank 18 is housed inside the tank housing case 21. The water supply port 18A of the urea water tank 18 and the supply port 28 of the tank housing case 21 are connected by a urea water supply pipe 34.

Next, we will explain the tank housing case 21 in detail.

The tank housing case 21 has an upper surface 23, a recess 27, and a refill port 28. The tank housing case 21 has a urea water refill pipe 34 and a water supply cap 36 as a lid. The upper surface 23 is provided above the urea water tank 18 housed in the tank housing case 21, and covers the urea water tank 18 from above. As shown in FIG. 7, a refill tank 51 is placed on the upper surface 23 when refilling urea water.

The recess 27 is provided in the upper surface portion 23 and is recessed downward from the upper surface 23A of the upper surface portion 23 in a bottomed shape. That is, as shown in FIG. 4, the recess 27 is recessed downward from the upper surface 23A of the upper surface portion 23 in a rectangular shape. The recess 27 has a rectangular bottom portion 27A and a side wall portion 27B that rises upward from the bottom portion 27A and connects the bottom portion 27A to the upper surface portion 23.

The opening of the recess 27 is covered by an openable cover 26. That is, the openable cover 26 is attached to the upper surface 23 by a hinge 26A. When the hydraulic excavator 1 is in operation (in other words, when urea water refilling work is not being performed), the recess 27 can be closed by the openable cover 26 as shown in FIG. 3. On the other hand, when urea water is to be refilled into the urea water tank 18 from the refill tank 51, the openable cover 26 can be opened upward to expose the recess 27 as shown in FIG. 4.

As shown in Figures 5 to 8, the refill port 28 is provided at the bottom 27A of the recess 27. The refill port 28 is an opening for refilling the urea water tank 18 with urea water. The refill port 28 is provided with a connector 29 to which a water supply cap 36 is detachably attached. The water supply port 18A of the urea water tank 18 is disposed below the refill port 28. The refill port 28 is connected to the water supply port 18A of the urea water tank 18 via a urea water refill pipe 34.

One end of the urea water supply pipe 34 is connected to the supply port 28, and the other end is connected to the water supply port 18A of the urea water tank 18. The urea water supply pipe 34 guides the urea water supplied from the supply port 28 to the water supply port 18A of the urea water tank 18. The urea water supply pipe 34 has a large diameter portion 34A connected to the supply port 28 of the recess 27, a small diameter portion 34B connected to the water supply port 18A of the urea water tank 18, and a reduced diameter portion 34C connecting the large diameter portion 34A and the small diameter portion 34B. The reduced diameter portion 34C has a smaller radial dimension as it moves from the large diameter portion 34A to the small diameter portion 34B (as it moves downward). The large diameter portion 34A has a larger inner diameter dimension than the small diameter portion 34B. A connector 29 is attached to the large diameter portion 34A, located inside the supply port 28. That is, the connector 29 is attached to the inside of the large diameter portion 34A. The connector 29 fits into the large diameter portion 34A while being supported by the connection between the large diameter portion 34A and the reduced diameter portion 34C.

The connector 29 is provided at the supply port 28. In this embodiment, the connector 29 is provided at the supply port 28 via the large diameter portion 34A of the urea water supply pipe 34. The connector 29 includes a bottom plate portion 30, a tubular portion 31, a side plate portion 32 (FIG. 8), and a pin member 33. The bottom plate portion 30 is formed in a disk shape with an outer diameter dimension larger than that of the tubular portion 31. In this case, the bottom plate portion 30 has an outer diameter dimension approximately the same as the inner diameter of the large diameter portion 34A of the urea water supply pipe 34, and is disposed within the large diameter portion 34A.

Through holes 30A through which urea water passes are provided on the outer diameter side of the bottom plate portion 30 relative to the tubular portion 31. As shown in FIG. 8, the through holes 30A are formed as through holes that are opened parallel to the axial direction of the tubular portion 31 at, for example, four positions, i.e., positions corresponding to between the side plate portions 32 adjacent in the circumferential direction. The portions of the bottom plate portion 30 that correspond to the inside (inner space) of the tubular portion 31 are closed. A pin member 33 is provided in the center portion of the bottom plate portion 30.

The tubular portion 31 is formed as a cylinder extending vertically from the bottom plate portion 30. The tubular portion 31 is provided with through holes 31A through which the urea water passes. As shown in FIG. 8, the through holes 31A are formed as through holes opened in the radial direction of the tubular portion 31 at, for example, four positions of the tubular portion 31, i.e., positions corresponding to between the side plate portions 32 adjacent in the circumferential direction. A water supply cap 36 is removably attached to one end side of the tubular portion 31 (the upper end side opposite the bottom plate portion 30).

In this case, as shown in FIG. 5, when the hydraulic excavator 1 is in operation (other than when urea water is being refilled), the engagement hole 37A of the water supply cap 36 is engaged with one end of the tubular portion 31. For example, the outer periphery of one end of the tubular portion 31 is male-threaded, and the engagement hole 37A, which has a female thread, is screwed into the radially outer side of the male-threaded tubular portion 31.

On the other hand, as shown in FIG. 7, when refilling with urea water, the connection hole 37B of the water supply cap 36 is connected to one end of the tubular portion 31. For example, the inner circumference of one end of the tubular portion 31 is a smooth surface, and the outer circumferential surface (smooth surface) of the tubular body 37C that constitutes the connection hole 37B is fitted into the radially inner side of the smooth tubular portion 31.

The side plate portions 32 are provided on the bottom plate portion 30 at intervals in the circumferential direction. For example, the side plate portions 32 are provided at four positions spaced at equal intervals (90°) in the circumferential direction. The portions between adjacent side plate portions 32 in the circumferential direction form filter attachment portions, and filters 35 are attached to each of them. As a result, the filter 35 is provided at the supply port 28 of the tank storage case 21. The filter 35 separates foreign matter from the urea water flowing from the supply port 28 toward the urea water tank 18.

The pin member 33 is provided at the center of the bottom plate portion 30. The pin member 33 extends from the bottom plate portion 30 inside the tubular portion 31 in parallel with the axial direction of the tubular portion 31. As a result, the pin member 33 is provided inside the supply port 28 of the tank storage case 21, and extends axially inside the supply port 28 by the bottom plate portion 30. The pin member 33 is larger than the axial dimension of the tubular portion 31, and protrudes upward beyond the opening edge of the tubular portion 31.

7, when the tubular body 37C of the water supply cap 36 is connected to one end of the tubular portion 31 of the connector 29, the pin member 33 abuts against the valve member 39 of the water supply cap 36 and pushes the valve member 39 upward. That is, when refilling with urea water, the connection hole 37B of the water supply cap 36 (more specifically, the tubular body 37C constituting the connection hole 37B) is connected to the supply port 28 of the tank housing case 21 (more specifically, the tubular portion 31 of the connector 29 provided at the supply port 28). At this time, the pin member 33 moves the valve member 39 of the water supply cap 36 to a position where the urea water passage 38 is connected. This allows urea water to be supplied from the refill tank 51 to the urea water tank 18 through the water supply cap 36.

As shown in Figs. 5 to 7, the water supply cap 36 can be attached and detached to both the supply port 28 of the tank housing case 21 and the water inlet 51A of the supply tank 51. The supply tank 51 is also called a BIB (back-in-box) and stores the urea water to be supplied to the urea water tank 18. The water supply cap 36 is attached to the supply port 28 of the tank housing case 21, more specifically, to the connector 29 provided on the supply port 28, while the hydraulic excavator 1 is in operation, in other words, when the urea water supply work is not being performed. On the other hand, when the urea water supply work is performed using the supply tank 51, the water supply cap 36 is removed from the supply port 28 (connector 29) of the tank housing case 21 and attached to the water inlet 51A of the supply tank 51, as shown in Fig. 6.

9 and other figures, the water supply cap 36 has a cap body 37 as a lid body, a urea water passage 38, and a valve member 39. The water supply cap 36 has a spring 40 as an elastic member. The cap body 37 is formed in a cylindrical shape and has an engagement hole 37A and a connection hole 37B provided separately from the engagement hole 37A. That is, on one axial side of the cap body 37 (the lower side in FIG. 9), an engagement hole 37A is provided that can engage with both the supply port 28 of the tank storage case 21 (more specifically, the connector 29 of the supply port 28) and the water inlet 51A of the supply tank 51.

The engagement hole 37A is formed, for example, as a female threaded hole. The supply port 28 of the tank storage case 21 and the water inlet 51A of the supply tank 51 are formed, for example, as a cylinder with a male thread on the outer periphery. As shown in Figures 5 to 7, the engagement hole 37A (female threaded hole) of the water supply cap 36 can be attached and detached by screwing it into the supply port 28, and can also be attached and detached by screwing it into the water inlet 51A.

The other axial side (upper side in FIG. 9) of the cap body 37 is provided with a connection hole 37B that can be connected to the supply port 28 (more specifically, the connector 29 of the supply port 28) of the tank housing case 21. The connection hole 37B is, for example, formed of a cylindrical body 37C provided on the other axial side of the cap body 37, and the outer periphery of the cylindrical body 37C has a smooth surface. As shown in FIG. 7, the cylindrical body 37C is inserted into the connector 29 of the supply port 28, more specifically, into the cylindrical portion 31 of the connector 29. The inner periphery of the cylindrical portion 31 has a smooth surface. The connection hole 37B of the water supply cap 36 is connected to the supply port 28 by inserting (fitting) the cylindrical body 37C into the cylindrical portion 31 of the connector 29.

The urea water passage 38 is provided in the cap body 37, and connects between the engagement hole 37A and the connection hole 37B to allow the passage of urea water. The cap body 37 has a hollow structure with a hollow interior, and the urea water passage 38 is formed by the hollow structure of the cap body 37. The valve member 39 is provided in the urea water passage 38. As shown in FIG. 5, the valve member 39 closes the urea water passage 38 when the engagement hole 37A of the water supply cap 36 is engaged with the refill port 28 (connector 29) of the tank storage case 21.

As shown in FIG. 7, the valve member 39 communicates with the urea water passage 38 when the connection hole 37B of the water supply cap 36 is connected to the refill port 28 of the tank housing case 21. The spring 40 presses the valve member 39 toward a position where the urea water passage 38 is blocked. During the urea water refill operation, the valve member 39 is pressed (pushed up) by the pin member 33 and moves against the elastic force of the spring 40 to a position where the urea water passage 38 is connected. That is, the valve member 39 is provided so as to be movable between a blocking position where the urea water passage 38 is blocked and a communicating position where the urea water passage 38 is connected within the hollow cap body 37. The valve member 39 is moved to the communicating position by contacting the pin member 33.

The valve member 39 is formed in a stepped disk shape and has a small diameter portion 39A and a large diameter portion 39B. The small diameter portion 39A fits into the connection hole 37B to close the urea water passage 38. The valve member 39 is pressed by a spring 40 in the direction in which the small diameter portion 39A fits into the connection hole 37B. The large diameter portion 39B divides the inside of the urea water passage 38 into a space on the connection hole 37B side and a space on the engagement hole 37A side.

The large diameter portion 39B has a through hole 39C that penetrates in the axial direction. The large diameter portion 39B is pressed toward the connection hole 37B by the spring 40. When the large diameter portion 39B is moved toward the engagement hole 37A by the pin member 33, urea water flows from the connection hole 37B side toward the engagement hole 37A side through the through hole 39C of the large diameter portion 39B.

When replenishing the urea water using the replenishing tank 51, as shown in FIG. 6, with the opening/closing cover 26 open, the water supply cap 36 is removed from the replenishing port 28 (connector 29) of the tank housing case 21, and the removed water supply cap 36 is attached to the water inlet 51A of the replenishing tank 51. In this case, the side of the water supply cap 36 that was attached to the replenishing port 28 (connector 29) of the tank housing case 21 is attached to the water inlet 51A of the replenishing tank 51. Next, as shown by arrow A in FIG. 6, the replenishing tank 51 is rotated so that the water inlet 51A of the replenishing tank 51 faces downward, and the water inlet 51A (water supply cap 36) of the replenishing tank 51 is brought closer to the replenishing port 28 (connector 29) of the tank housing case 21, as shown by arrow B in FIG. 6.

As shown in FIG. 7, the water inlet 51A (water supply cap 36) of the supply tank 51 is connected (fitted) to the supply port 28 (connector 29) of the tank housing case 21, and the supply tank 51 is placed on the upper surface 23 of the tank housing case 21. At this time, the valve member 39 is moved by the pin member 33 to a position where the urea water passage 38 is connected. As a result, the urea water in the supply tank 51 is supplied (supplied) from the water inlet 51A through the water supply cap 36 (more specifically, the urea water passage 38, the through hole 39C of the large diameter portion 39B of the valve member 39, and the connection hole 37B), the supply port 28 (more specifically, the inside of the tube portion 31 of the connector 29, the through hole 31A of the tube portion 31, the filter 35, and the through hole 30A of the bottom plate portion 30), and the urea water supply pipe 34 to the urea water tank 18.

In this manner, in this embodiment, the refill port 28 is provided in the recess 27 of the tank housing case 21, and the filter 35 is attached to the refill port 28 by the connector 29. The refill port 28 is provided with a pin member 33 by the connector 29. The refill port 28 and the urea water tank 18 are connected via a urea water refill pipe 34. The inner diameter of the large diameter portion 34A of the urea water refill pipe 34 is the same dimension as the outer diameter of the filter 35.

The water supply cap 36 is composed of a cap body 37 and a valve member 39. The valve member 39 is pressed by a spring 40 to a position where it closes the urea water passage 38. Therefore, when water supply work is not being performed, the water supply cap 36 can prevent urea water from leaking from the refill port 28.

Figure 7 shows the state when urea water is being supplied. With the water supply cap 36 attached to the water inlet 51A of the supply tank 51, the supply tank 51 is connected to the urea water tank 18 via the supply port 28 and the urea water supply pipe 34. At this time, the valve member 39 of the water supply cap 36 is moved by the pin member 33 to a position where it communicates with the urea water passage 38. This allows the urea water to be supplied (supplied) through the water supply cap 36.

During the water supply operation, the supply tank 51 can be placed on the upper surface 23 of the tank housing case 21. Therefore, once the supply tank 51 is set in a state in which water can be supplied, the worker does not need to hold the supply tank 51. Therefore, the worker does not need to hold the supply tank 51 until water supply is completed. Even if urea water leaks from between the water supply cap 36 and the supply port 28 during the water supply operation, the leaked urea water will collect in the recess 27 and flow from the recess 27 through the filter 35 of the supply port 28 to the urea water tank 18.

The hydraulic excavator 1 according to the embodiment has the configuration described above, and its operation will be explained next.

The operator sits in the cab 8 and starts (starts) the engine 10. When the engine 10 starts, the engine 10 drives the hydraulic pump 13. Pressurized oil discharged from the hydraulic pump 13 is discharged toward the traveling hydraulic motor, the swing hydraulic motor, the boom cylinder 5D, the arm cylinder 5E, the bucket cylinder 5F, etc., in response to the lever and pedal operations of the traveling lever/pedal operation device and the working lever operation device arranged in the cab 8. This allows the hydraulic excavator 1 to perform traveling operations using the lower traveling body 2, swinging operations using the upper swing body 4, excavation work using the working device 5, etc.

When the engine 10 is operating, exhaust gas emitted from the engine 10 passes through the exhaust pipe 11 and the exhaust gas aftertreatment device 17 before being discharged into the atmosphere. At this time, the urea water in the urea water tank 18 is supplied to the urea water injection valve of the exhaust gas aftertreatment device 17 and is injected from the urea water injection valve toward the exhaust gas. As a result, the urea selective reduction catalyst 17B breaks down the nitrogen oxides in the exhaust gas into nitrogen and water. Furthermore, the oxidation catalyst 17C oxidizes the residual ammonia and separates it into nitrogen and water. This makes it possible to reduce the amount of nitrogen oxide emissions.

When the amount of urea water in the urea water tank 18 is low, the urea water is replenished. In this case, as shown in FIG. 6, with the opening and closing cover 26 open, the water supply cap 36 is removed from the supply port 28 (connector 29) of the tank housing case 21, and the removed water supply cap 36 is attached to the water filling port 51A of the supply tank 51. Next, as shown by arrow A in FIG. 6, the supply tank 51 is rotated so that the water filling port 51A of the supply tank 51 faces downward, and the water filling port 51A (water supply cap 36) of the supply tank 51 is brought closer to the supply port 28 (connector 29) of the tank housing case 21, as shown by arrow B in FIG. 6.

As shown in FIG. 7, the water inlet 51A (water supply cap 36) of the supply tank 51 is connected to the supply port 28 (connector 29) of the tank housing case 21, and the supply tank 51 is placed on the top surface 23 of the tank housing case 21. At this time, the valve member 39 is moved by the pin member 33 to a position where the urea water passage 38 is connected, and the urea water in the supply tank 51 is supplied (replenished) to the urea water tank 18 through the water supply cap 36, the supply port 28, and the urea water supply pipe 34.

As described above, according to the embodiment, a bottomed recess 27 is provided on the top surface 23 of the tank housing case 21, and a refill port 28 for refilling urea water into the urea water tank 18 is provided on the bottom 27A of this recess 27. Therefore, an operator who supplies (refills) urea water to the urea water tank 18 can supply (refill) urea water from the refill tank 51 to the urea water tank 18 while the urea water refill tank 51 is placed on the top surface 23 of the tank housing case 21.

That is, the worker faces the supply tank 51 downward so that the water inlet 51A of the supply tank 51 is located in the recess 27 of the tank housing case 21, and places the supply tank 51 on the upper surface 23 of the tank housing case 21. This allows the urea water in the supply tank 51 to be supplied (replenished) to the urea water tank 18 from the water inlet 51A of the supply tank 51 through the supply port 28 of the recess 27 while the supply tank 51 is placed on the upper surface 23 of the tank housing case 21. This eliminates the need for the worker to continue holding the supply tank 51 during supply (replenishment), reducing the burden on the worker.

According to the embodiment, the tank housing case 21 is provided with a urea water supply pipe 34 that connects the supply port 28 of the recess 27 and the water supply port 18A of the urea water tank 18. Therefore, even if the position of the supply port 28 of the tank housing case 21 and the position of the water supply port 18A of the urea water tank 18 are separated due to restrictions on the shape of the tank housing case 21, the shape of the urea water tank 18, restrictions on the installation space, etc., it is possible to prevent the urea water from spilling between the supply port 28 and the water supply port 18A. In other words, even if the supply port at the bottom of the recess and the water supply port of the urea water tank cannot be integrally formed, or even if the supply port at the bottom of the recess and the water supply port of the urea water tank cannot be directly connected, it is possible to prevent the urea water from spilling between the supply port 28 at the bottom 27A of the recess 27 and the water supply port 18A of the urea water tank 18.

According to the embodiment, the tank housing case 21 is provided with a water supply cap 36 as a lid that can be attached and detached to both the supply port 28 of the tank housing case 21 and the water filling port 51A of the supply tank 51. The water supply cap 36 has a valve member 39 that closes or communicates with the urea water passage 38. The valve member 39 closes the urea water passage 38 when the engagement hole 37A of the water supply cap 36 is engaged with the supply port 28 of the tank housing case 21, and communicates with the urea water passage 38 when the connection hole 37B of the water supply cap 36 is connected to the supply port 28 of the tank housing case 21.

Therefore, when the hydraulic excavator 1 is operating, the water supply cap 36 is attached to the supply port 28 so that the engagement hole 37A of the water supply cap 36 engages with the supply port 28 of the tank housing case 21. This allows the supply port 28 to be blocked. On the other hand, when supplying (replenishing) urea water from the supply tank 51, the connection hole 37B of the water supply cap 36 is connected to the supply port 28 of the tank housing case 21 in a state where the water supply cap 36 is attached to the water fill port 51A so that the engagement hole 37A of the water supply cap 36 engages with the water fill port 51A of the supply tank 51. This allows the urea water of the supply tank 51 to be supplied (replenished) to the urea water tank 18 through the water supply cap 36. Therefore, the supply port 28 can be blocked by the water supply cap 36, and urea water can be supplied (replenished) from the supply tank 51 to the urea water tank 18 through the water supply cap 36.

According to the embodiment, when the connection hole 37B of the water supply cap 36 is connected to the supply port 28 of the tank housing case 21, the valve member 39 of the water supply cap 36 is moved by the pin member 33 provided at the supply port 28 of the tank housing case 21 to a position where the urea water passage 38 is connected. Therefore, in order to supply (replenish) urea water from the supply tank 51 to the urea water tank 18, the urea water passage 38 can be connected only when the connection hole 37B of the water supply cap 36 attached to the supply tank 51 is connected to the supply port 28 of the tank housing case 21. This makes it possible to prevent the urea water from spilling through the water supply cap 36 before the water inlet 51A of the supply tank 51 is connected to the supply port 28 of the tank housing case 21.

According to the embodiment, the spring 40 serves as an elastic member that presses the valve member 39 toward a position where the urea water passage 38 is blocked. Therefore, the spring 40 can prevent the valve member 39 from moving unnecessarily to a position where the urea water passage 38 is in communication. This also prevents the urea water from spilling.

According to the embodiment, a filter 35 that separates foreign matter from the urea water is provided at the supply port 28 of the tank housing case 21. This allows clean urea water to be supplied from the supply tank 51 to the urea water tank 18.

In the embodiment, the refill port 28 of the tank housing case 21 and the water supply port 18A of the urea water tank 18 are connected via the urea water supply pipe 34. However, the present invention is not limited to this. For example, as shown in FIG. 10, the refill port 61 of the tank housing case 21 and the water supply port 18A of the urea water tank 18 may be directly connected. That is, the urea water supply pipe may be omitted. In this case, the connector 62 can be provided directly to the refill port 61 (without the urea water supply pipe). The connector 62 includes, for example, a bottom plate portion 63, a tube portion 64, and a pin member 65. The outer diameter of the bottom plate portion 63 is the same as the outer diameter of the tube portion 64. The bottom plate portion 63 and the tube portion 64 are supported by the refill port 61. The bottom plate portion 63 is provided with a through hole 63A. The refill port 61 and the water supply port 18A of the urea water tank 18 can be connected, for example, by fitting. In this modified example, the filter is omitted, but it may be provided, for example, inside the tubular portion 64 of the connector 62.

In the embodiment, a configuration in which a spring 40 is used as the elastic member that presses the valve member 39 has been described as an example. However, this is not limiting, and an elastic member other than a spring, such as a rubber member, may be used. The elastic member may be omitted.

In the embodiment, an example has been described in which the cap body 37 is made hollow, thereby providing a urea water passage 38 within the water supply cap 36. However, this is not limiting, and for example, a tube body serving as the urea water passage may be provided within the lid body. Also, for example, a passage hole serving as the urea water passage may be formed in the lid body. In other words, a tube body or a passage hole may be used to connect between the engagement hole and the connection hole to allow the passage of urea water.

In the embodiment, the urea water tank 18 is placed forward of the fuel tank 15, i.e., in front of the revolving frame 6. However, this is not limiting, and the urea water tank may be placed in a location other than the front of the revolving frame, for example, in front of the counterweight or in front of the engine. In this case, the urea water tank is housed in a tank housing case equipped with a refill port.

In the embodiment, an example has been described in which the vehicle body is formed from a lower running body 2 and an upper rotating body 4. However, the present invention is not limited to this, and the vehicle body may not have a rotating body (for example, an articulated vehicle body in which a front body having front wheels and a rear body having rear wheels are flexibly connected via a connecting shaft).

In the embodiment, a crawler-type hydraulic excavator 1 has been described as an example of a construction machine. However, the present invention is not limited to this, and can be widely applied to various types of construction machines, such as wheel-type hydraulic excavators, hydraulic cranes, wheel loaders, bulldozers, dump trucks, etc.

1. Hydraulic excavator (construction machinery)
2. Undercarriage (car body)
4. Upper rotating body (car body)
REFERENCE SIGNS LIST 17 Exhaust gas aftertreatment device 17B Urea selective reduction catalyst 18 Urea water tank 18A Water supply port 21 Tank housing case 23 Top surface 23A Top surface 27 Recess 27A Bottom 28 Supply port 33 Pin member 34 Urea water supply pipe 35 Filter 36 Water supply cap (lid)
37 Cap body (lid body)
37A Engagement hole 37B Connection hole 38 Urea water passage 39 Valve member 40 Spring (elastic member)
51 Supply tank 51A Water inlet

Claims (7)

a urea water tank disposed in the vehicle body and storing the urea water;
a tank housing case provided on the vehicle body and housing the urea water tank,
The tank housing case includes:
an upper surface portion provided above the urea water tank housed in the tank housing case and covering the urea water tank from above;
a recess provided in the upper surface portion and recessed downward from an upper surface of the upper surface portion into a bottomed shape;
a refill port provided at a bottom of the recess for refilling the urea water tank with urea water. The urea water tank has a water supply port for supplying urea water therein,
The tank housing case includes:
2. The construction machine according to claim 1, further comprising a urea water supply pipe having one end connected to the supply port and the other end connected to the water supply port of the urea water tank, the urea water supply pipe guiding the urea water supplied from the supply port to the water supply port of the urea water tank. The tank housing case includes:
a cover body that can be attached and detached to both the supply port of the tank housing case and a water inlet of a supply tank that stores the urea water to be supplied to the urea water tank,
The lid body is
a lid body having an engagement hole capable of engaging with both the supply port of the tank housing case and the water filling port of the supply tank, and a connection hole provided separately from the engagement hole and connectable to the supply port;
a urea water passage provided in the lid body and connecting the engagement hole and the connection hole to allow the passage of urea water;
2. The construction machine according to claim 1, further comprising a valve member which closes the urea water passage when the engagement hole is engaged with the supply port of the tank storage case, and opens the urea water passage when the connection hole is connected to the supply port of the tank storage case. The refill port of the tank housing case is provided with a pin member extending through the refill port,
4. The construction machine according to claim 3, wherein the pin member moves the valve member of the cover body to a position where the urea water passage is connected when the connection hole of the cover body is connected to the supply port of the tank storage case. The lid body has a hollow structure with a hollow interior,
The urea water passage is formed by a hollow structure of the lid body,
the valve member is provided in the hollow cover body so as to be movable between a closing position at which the urea water passage is closed and a communicating position at which the urea water passage is communicated,
5. The construction machine according to claim 4, wherein the valve member is moved to the communicating position by abutment with the pin member. The lid body is
4. The construction machine according to claim 3, further comprising an elastic member for urging the valve member toward a position where the urea water passage is closed. The construction machine according to claim 1, characterized in that the supply port of the tank housing case is provided with a filter for separating foreign matter from the urea water flowing from the supply port toward the urea water tank.

Images