JP6857110B2 - Construction machinery - Google Patents

Description

The present invention relates to construction machinery such as hydraulic excavators used at sites such as civil engineering, forestry, demolition, and underground construction.

For example, Patent Document 1 describes a hydraulic excavator having a guard structure for protecting an exterior cover on an upper swing body. According to the technique of Patent Document 1, the exterior cover can be protected from surrounding obstacles by the guard structure. In addition, since the guard structure opens and closes like a door, maintainability can be improved.

Japanese Unexamined Patent Publication No. 2015-158506

By the way, among the hydraulic excavators used at the sites of civil engineering, forestry, demolition, underground construction, etc., for example, the hydraulic excavators (forestry machines) used at the sites of forestry such as forest road construction work, logging work, lumber collection work, etc. Work is often done in the mountains. For this reason, it may be necessary to manually refuel fuel or hydraulic oil using a carrying tank (for example, a plastic tank). On the other hand, the fuel filler port of the oil storage tank (fuel tank, hydraulic oil tank) of the hydraulic excavator is on the upper surface of the upper swing body. Therefore, depending on the size of the hydraulic excavator, a person may stand on the track (shoe) of the lower traveling body to refuel the oil storage tank.

However, even if you stand on the track, for example, you may not be able to reach the refueling port sufficiently, which may make the refueling work to the oil storage tank troublesome. Further, if the height position of the upper surface of the track is higher than the position of the knee of the person performing the refueling work, for example, the movement of standing on the track may be troublesome. Therefore, the refueling work may be troublesome from this aspect as well.

An object of the present invention is to provide a construction machine capable of protecting an upper swing body from surrounding obstacles and easily performing a refueling operation to an oil storage tank.

The construction machine of the present invention includes a lower traveling body capable of self-propelling by a cuff, and an upper rotating body rotatably mounted on the lower traveling body, and the upper rotating body is swiveled with a front device attached to the front side. The frame is provided on the swivel frame on one side in the left and right directions with the front device in between, and is provided with an oil storage tank for storing hydraulic oil or fuel. The swivel frame is provided in the left and right directions. A construction including a center frame having a bottom plate located in the middle of the center frame and left and right side frames arranged on both sides of the center frame in the left and right directions and extending in the front and rear directions, respectively. a machine, the left, the outside position of one of the side frame of the right side frame, the oil storage tank and has a guard member is attached taken a corresponding position, said guard member, said pair a pair of posts The guard member is provided with a frame body composed of a plurality of connecting members provided between the pair of columns at predetermined intervals while connecting the columns, and the guard member is rotated so that the entire lower portion is formed. upper in than the running body, and, prior to the longitudinal direction of the frame body of the side frame, it is disposed along the rear direction, and guard position protecting the oil storage tank, the lower traveling and the upper rotating body over between the body and, on the longitudinal direction of the frame body of the upper rotating body, is arranged along the downward direction, it is switched to the step position of the lifting step to the upper rotating body on It is possible , and in a state where the guard member is switched to the step position, the first-stage connecting member from the bottom among the plurality of connecting members of the guard member is more than the upper surface of the cuff band of the lower traveling body. Ru is located lower.

According to the present invention, the upper swing body can be protected from surrounding obstacles, and the oil storage tank can be easily refueled. That is, when the guard member is fixed at the guard position, the upper swivel body can be protected from surrounding obstacles (for example, trees) by the guard member. On the other hand, when the guard member is fixed at the step position, the guard member can be used as an elevating step to approach the oil supply port of the oil storage tank. As a result, the oil supply work to the oil storage tank can be easily performed.

It is a front view which shows the hydraulic excavator by embodiment in the state of the guard member in a guard position. It is an enlarged perspective view of part (II) in FIG. It is a front view which shows the hydraulic excavator by embodiment in the state of the guard member in a step position. It is an enlarged perspective view of the part (IV) in FIG. In order to explain the state in which the guard member is used as a step, it is explanatory drawing which saw the hydraulic excavator from the rear with the guard member in a step position. It is a top view which shows the hydraulic excavator in FIG. It is a top view which shows a swivel frame and a guard member. It is an exploded perspective view which shows the swivel frame, the guard support shaft part, guard fixing shaft part, rotation regulation member, guard member and the like. It is a perspective view for demonstrating the positional relationship of a guard support shaft part, a guard fixing shaft part, a rotation regulation member, a rotation fitting cylinder part, a guard position fixing cylinder part, and the like. It is a perspective view which looked at the guard member and the like by the 1st modification from the same position as FIG. It is a perspective view which looked at the guard member and the like by the 2nd modification from the same position as FIG.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings, taking as an example a case where the embodiment of the present invention is applied to a hydraulic excavator as a typical example of a construction machine.

1 to 9 show embodiments. In FIG. 1, the hydraulic excavator 1 as a construction machine is widely used in civil engineering, forestry, demolition, underground construction, and the like. Of these, the hydraulic excavator 1 of the embodiment is a medium-sized (for example, a machine weight of about 7 to 15 tons) hydraulic excavator (medium-sized forestry machine) used in forestry sites such as forest road construction work and lumber collection work. ). In this case, in the hydraulic excavator 1, the counterweight 8 attached to the rear is formed in an arc shape, and the rear side of the upper turning body 4 can turn within 120% to 130% of the vehicle width of the lower traveling body 2. It is configured as a rear ultra-small swivel or a rear small swivel.

The hydraulic excavator 1 is configured as a cab-type hydraulic excavator. The hydraulic excavator 1 includes a self-propelled crawler-type lower traveling body 2, an earth removal device (not shown) provided on the lower traveling body 2 so as to swing upward and downward, and the lower traveling body 2. It is configured to include an upper swivel body 4 mounted so as to be swivelable via a swivel device 3 and a front device 5 provided on the upper swivel body 4 so as to be able to move up and down. In this case, the lower traveling body 2 and the upper turning body 4 constitute the vehicle body of the hydraulic excavator 1.

The lower traveling body 2 is, for example, a track belt 2A in which a plurality of shoes are attached to a track link formed in an endless shape, and a left and right traveling hydraulic pressure for traveling a hydraulic excavator 1 by orbiting the track belt 2A. It is configured to include a motor (not shown). The swivel device 3 is provided between the lower traveling body 2 and the upper swivel body 4 (swivel frame 6 described later), and has a swivel wheel 3A that rotatably supports the upper swivel body 4 and a center O of the swivel wheel 3A (FIG. A swivel hydraulic motor 3B (see FIG. 6) that swivels and drives the upper swivel body 4 with the swivel center as the swivel center) is included.

As shown in FIG. 6, at the position of the turning center O, a center joint 3C for circulating pressure oil between the lower traveling body 2 and the upper turning body 4 is provided. Further, as shown in FIG. 6, the upper swivel body 4 has a width dimension in the left and right directions which is substantially equal to a width dimension (vehicle width) in the left and right directions of the lower traveling body 2. When the upper rotating body 4 turns around the turning center O on the lower traveling body 2, the rear surface 8A of the counterweight 8 described later fits within 120% to 130% of the vehicle width of the lower traveling body 2. It has become like. As a result, the hydraulic excavator 1 is configured as a rear ultra-small turning type or a rear small turning type hydraulic excavator.

The front device 5, which is also called a working device, is provided on the front side of the upper swing body 4. The front device 5 includes, for example, a boom 5A, an arm 5B, a log grapple (log fork) 5C as a work tool (attachment), and a boom cylinder 5D, an arm cylinder 5E, and a work tool cylinder 5F for driving them. Has been done. The log grapple 5C has a pair of forks 5C1 that can be opened and closed by a hydraulic actuator (not shown). The log grapple 5C can grip or open wood or the like by opening and closing the fork 5C1.

The upper swivel body 4 includes a swivel frame 6 that serves as a support structure (base frame) for the upper swivel body 4, a cab 7, a counterweight 8, a hydraulic oil tank 9, a fuel tank 10, and the like mounted on the swivel frame 6. It has. Various devices such as an engine, a hydraulic pump, a heat exchanger, and a control valve device (not shown) located on the front side of the counterweight 8 are mounted on the swivel frame 6. These various devices are covered with an exterior cover 11 that forms an outer shell of the upper swing body 4. A front device 5 is attached to the front side of the swivel frame 6.

As shown in FIG. 7, the swivel frame 6 is erected on a bottom plate 6A made of a thick steel plate or the like extending in the front and rear directions, and is erected on the bottom plate 6A in the front and rear directions at predetermined intervals in the left and right directions. Left vertical plate 6B and right vertical plate 6C extending to the left, and a plurality of overhanging beams 6D arranged outward from each vertical plate 6B and 6C in the left and right directions at intervals in the front and rear directions, and left, It is located on the outside in the right direction and is attached to the tip of each overhang beam 6D, and is composed of a left side frame 6E and a right side frame 6F extending in the front and rear directions.

Here, the bottom plate 6A, the left vertical plate 6B, and the right vertical plate 6C form the center frame of the swivel frame 6. This center frame (bottom plate 6A, left vertical plate 6B, right vertical plate 6C) is located inside the swivel frame 6 in the left and right directions, that is, in the middle portion (center) in the left and right directions of the swivel frame 6. There is. On the other hand, the left side frame 6E and the right side frame 6F are located outside the swivel frame 6 in the left and right directions, that is, on both sides of the center frame (bottom plate 6A, left vertical plate 6B, right vertical plate 6C) in the left and right directions. Each is arranged.

A plurality of, for example, four engine brackets 6G are provided on the rear side of the swivel frame 6 so as to be located between the left vertical plate 6B and the right vertical plate 6C. The engine bracket 6G supports the engine (neither shown) via a vibration-proof mount. Further, the boom 5A and the boom cylinder 5D of the front device 5 are attached to the front side of the left vertical plate 6B and the right vertical plate 6C, and the counterweight 8 is attached to the rear portion.

Further, a guard member 21 described later is provided at an outer position of the right side frame 6F, which is one of the left side frame 6E and the right side frame 6F. Here, the "one side frame" corresponds to the right side frame, that is, the right side frame 6F, which is the side on which the hydraulic oil tank 9 and the fuel tank 10 described later are provided. The "outer position" corresponds to the outer position of the upper swing body 4, that is, the outer position opposite to the direction toward the center side of the upper swing body 4. A guard support shaft portion 12 and a guard fixed shaft portion 17, which will be described later, are provided at the outer position of the right side frame 6F.

A driver's seat (not shown) in which the operator sits is provided in the cab 7. A traveling lever / pedal operating device and a working lever operating device for operating the hydraulic excavator 1 are provided around the driver's seat. By operating the traveling lever / pedal operating device and the working lever operating device, the operator performs a traveling operation by the lower traveling body 2, a turning operation of the upper turning body 4, a wood gripping operation by the front device 5, and the like. Can be done.

The counterweight 8 is provided on the rear side of the swivel frame 6. The counterweight 8 is formed as a heavy object that balances the weight with the front device 5. As shown in FIG. 6, the turning radius R when the upper turning body 4 performs the turning operation is defined by the distance from the turning center O to the rear surface 8A of the counterweight 8. Therefore, the rear surface 8A of the counterweight 8 is formed in an arc shape having a radius R centered on the turning center O. By arranging the counterweight 8 closer to the front side near the turning center O, the counterweight 8 is configured to be able to turn within 120% to 130% of the vehicle width of the lower traveling body 2.

The hydraulic oil tank 9 as an oil storage tank is located on the front side of the counterweight 8 (more specifically, the front side of the hydraulic pump) and is provided on the swivel frame 6. That is, the hydraulic oil tank 9 is located on the swivel frame 6 on the right side, which is one side in the left and right directions with the front device 5 in between. The hydraulic oil tank 9 includes hydraulic actuators (running hydraulic motor, swivel hydraulic motor, swivel hydraulic motor 3B, boom cylinder 5D, arm cylinder 5E, work) provided in the lower traveling body 2, the swivel device 3, and the front device 5. It stores the hydraulic oil for driving the tool cylinder 5F, etc.).

The fuel tank 10 as an oil storage tank is provided on the swivel frame 6 so as to be lined up on the left and right outside of the upper swivel body 4 with respect to the hydraulic oil tank 9. That is, like the hydraulic oil tank 9, the fuel tank 10 is also provided on the swivel frame 6 located on the right side, which is one side in the left and right directions with the front device 5 in between. In this case, the fuel tank 10 is provided on the outer peripheral side of the upper swing body 4 with respect to the hydraulic oil tank 9. The fuel tank 10 stores fuel to be supplied to the engine.

Next, the guard member 21 attached to the upper swing body 4 will be described.

At the outer position of the right side frame 6F of the swivel frame 6, a guard member 21 is rotatably attached at a position corresponding to the fuel tank 10. That is, the guard member 21 is rotatably attached to the right side frame 6F, which is the side frame on the fuel tank 10 side of the left and right side frames 6E and 6F. In this case, the guard member 21 can be switched between the guard position shown in FIGS. 1, 2, 6 and 7, and the step position shown in FIGS. 3 to 5, that is, the guard position and the step position are 2. It can be selectively fixed in one position. In this case, the guard member 21 is arranged at a required position between the guard position and the step position by rotating the guard member 21 from the guard position to the step position or by rotating the guard member 21 from the step position to the guard position. Can be done.

Here, when the guard member 21 is in the guard position, the entire guard member 21 is arranged above the lower traveling body 2. That is, the guard position corresponds to the position where the guard member 21 protects the fuel tank 10 by extending in the front and rear directions. As shown in FIG. 6, when the guard member 21 is in the guard position, the guard member 21 fits in the virtual circle S having the turning radius R when the upper swivel body 4 swivels. On the other hand, when the guard member 21 is in the step position, the guard member 21 is arranged between the upper swing body 4 and the lower traveling body 2. That is, the step position is a position where the guard member 21 extends upward and downward so that the guard member 21 can be used to move up and down on the upper swing body 4 (for raising and lowering the upper swing body 4). Corresponds to the step position). In this case, that is, even when the guard member 21 is in the step position, the guard member 21 fits in the virtual circle S having a turning radius R when the upper swivel body 4 swivels, as in the case of the guard position. When the guard member 21 is in the step position, the upper swivel body 4 is not swiveled.

As described above, as shown in FIG. 8, the guard support shaft portion 12 and the guard are attached to the right side frame 6F so that the guard member 21 can be selectively fixed to the guard position and the step position. A fixed shaft portion 17 is provided. Here, the guard support shaft portion 12 rotatably supports the guard member 21. The guard support shaft portion 12 includes a frame mounting portion 13, a support cylinder portion 14, and a lid body 15.

The frame mounting portion 13 serves as a base portion (bracket) for fixing the support cylinder portion 14 to the right side frame 6F, and is formed in a clog shape (U-shape) as a whole. That is, the frame mounting portion 13 includes a support plate 13A having an insertion hole 13A1 through which the support cylinder portion 14 is inserted, and a pair of leg portions 13B and 13B extending from the support plate 13A toward the right side frame 6F. .. The support cylinder portion 14 is fixed to the support plate 13A by using, for example, welding means in a state of being inserted into the insertion hole 13A1 of the support plate 13A. The legs 13B and 13B are fixed at positions outside the right side frame 6F and at positions corresponding to the front side of the fuel tank 10, for example, by using welding means. As a result, the frame mounting portion 13 is firmly fixed to the right side frame 6F together with the support cylinder portion 14.

The support cylinder portion 14 is formed as a cylindrical body. The rotary fitting cylinder portion 24 of the guard member 21 is rotatably fitted to the outer peripheral side of the support cylinder portion 14. As a result, the guard member 21 can rotate around the support cylinder portion 14 of the guard support shaft portion 12. The support cylinder portion 14 is provided with a pair of pin holes 14A facing each other in the horizontal direction at positions separated by 180 ° in the circumferential direction. When the guard member 21 is fixed at the guard position or the step position, the fixing pin 27 described later is inserted into the pin hole 14A.

The lid 15 is provided in the support cylinder portion 14 so as to close the opening of the support cylinder portion 14. A pair of female screw holes 15A and 15A are formed in the lid body 15. Bolts 16 and 16 for fixing the rotation restricting member 20 to the guard support shaft portion 12 are screwed into the female screw holes 15A and 15A. That is, in a state where the rotation fitting cylinder portion 24 of the guard member 21 is fitted to the support cylinder portion 14, the rotation regulation member 20 is fixed to the support cylinder portion 14 (lid body 15) by using bolts 16 and 16. Will be done.

The guard fixing shaft portion 17 fixes the guard member 21 at the guard position and the step position. As shown in FIG. 8, the guard fixed shaft portion 17 includes a mounting plate 18 and a fixed shaft 19. The mounting plate 18 serves as a base portion (bracket) for fixing the fixing shaft 19 to the right side frame 6F. On the surface side of the mounting plate 18, the fixing shaft 19 is fixed by using, for example, welding means. The back surface side of the mounting plate 18 is fixed to the right side frame 6F at an outer position and at a position corresponding to the rear side of the fuel tank 10 by using, for example, welding means. As a result, the mounting plate 18 is firmly fixed to the right side frame 6F together with the fixed shaft 19.

Here, in the mounting plate 18, the separation dimension H1 between the fixed shaft 19 (center) of the guard fixed shaft portion 17 and the support cylinder portion 14 (center) of the guard support shaft portion 12 is rotationally fitted to the guard member 21. The separation dimension H2 between the cylinder portion 24 (center) and the guard position fixing cylinder portion 25 (center), and the rotary fitting cylinder portion 24 (center) of the guard member 21 and the step position fixing cylinder portion 26 (center) It is fixed so as to be the same as the distance dimension H3 from the center). That is, the separation dimensions H1, H2, and H3 have a relationship of H1 = H2 = H3.

The fixed shaft 19 is formed as a cylindrical body. A guard position fixing cylinder 25 or a step position fixing cylinder 26 of the guard member 21 is fitted on the outer peripheral side of the fixed shaft 19. That is, when the guard member 21 is in the guard position, the guard position fixing cylinder portion 25 of the guard member 21 is fitted to the outer peripheral side of the fixed shaft 19 of the guard fixing shaft portion 17. On the other hand, when the guard member 21 is in the step position, the step position fixing cylinder portion 26 of the guard member 21 is fitted to the outer peripheral side of the fixed shaft 12B of the guard fixing shaft portion 17.

The rotation restricting member 20 is provided on the guard support shaft portion 12. That is, the rotation restricting member 20 is fixed to the guard support shaft portion 12 by using a pair of bolts 16 and 16. For this purpose, the rotation restricting member 20 is provided with bolt insertion holes 20B and 20B. The bolts 16 and 16 are inserted into the bolt insertion holes 20B and 20B of the rotation restricting member 20, and are screwed into the female screw holes 15A and 15A provided in the lid 15 inside the guard support shaft portion 12. As a result, the rotation restricting member 20 is attached to the guard support shaft portion 12.

The rotation restricting member 20 prevents the rotation fitting cylinder portion 24 of the guard member 21 from coming out of the support cylinder portion 14 of the guard support shaft portion 12. At the same time, when the guard member 21 is rotated, the rotation regulating member 20 regulates the rotation of the guard member 21, specifically, the range of 90 ° between the guard position and the step position. Therefore, the rotation restricting member 20 is formed in a disk shape having an outer diameter larger than the outer diameter of the rotation fitting cylinder portion 24 of the guard member 21, and is a part of the outer peripheral edge thereof, that is, , The range from 9 o'clock to 12 o'clock in the clockwise direction when viewed from the outside of the upper swivel body 4 is notched inward in the radial direction. In other words, a notch 20A is provided on the outer peripheral edge of the rotation restricting member 20 over a range of 9 o'clock to 12 o'clock in the clockwise direction.

The notch 20A regulates the displacement of the corner portion 23A3 of the central connecting plate 23A of the guard member 21 within a range of 90 ° between the guard position and the step position when the guard member 21 is rotated. The corner portion 23A3 of the guard member 21 comes into contact with the step portion 20A1 corresponding to the 12 o'clock position in the notch 20A, so that the guard member 21 is positioned at the guard position. On the other hand, the corner portion 23A3 of the guard member 21 comes into contact with the step portion 20A2 corresponding to the 9 o'clock position in the notch 20A, so that the guard member 21 is positioned at the step position.

The guard member 21 includes a frame body 22, a plurality of connecting plates 23A, 23B, 23C, a rotary fitting cylinder portion 24, a guard position fixing cylinder portion 25, and a step position fixing cylinder portion 26. .. The frame body 22 is formed in a rectangular shape as a whole by using a pipe material. That is, the frame body 22 is formed in a rectangular shape as a whole by the pair of support columns 22A and 22B and the pair of connecting portions 22C and 22D. The pair of support columns 22A and 22B are the columns of the guard member 21, respectively, and one of the support columns (for example, the one that is on the lower side at the guard position and the front side at the step position) and the other (for example, at the guard position). The strut portions 22B on the upper side and the rear side at the step position) extend in parallel with each other.

The strut portions 22A and 22B are provided with narrow frame rods 22E and 22E extending in parallel with the strut portions 22A and 22B, respectively. For example, when an article is placed on the connecting plates 23A, 23B, 23C, a fixing rope (not shown) for fixing the article is tied to the narrow frame rods 22E, 22E, or for covering the article. You can hook the hook of the holding net (net). In addition, it also serves as a handrail when used in steps, and serves as a grip when rotating.

The pair of connecting portions 22C and 22D serve as connecting members for the guard member 21. One connecting portion 22C connects one end side of one strut portion 22A (for example, the side that becomes the rear end side at the guard position and the lower end side at the step position) and one end side of the other strut portion 22B. There is. The other connecting portion 22D connects between the other end side of one strut portion 22A (for example, the side that becomes the front end side at the guard position and the upper end side at the step position) and the other end side of the other strut portion 22B. ing. A foot plate 22F, which serves as a footrest when the guard member 21 is used as a step, is fixed to the connecting portions 22C and 22D by using, for example, welding means.

The connecting plates 23A, 23B, 23C are provided in the frame body 22 in parallel with the connecting portions 22C, 22D. The connecting plates 23A, 23B, and 23C correspond to connecting members together with the connecting portions 22C, 22D of the frame body 22. That is, the three connecting plates 23A, 23B, 23C, together with the two connecting portions 22C, 22D of the frame body 22, have a predetermined (for example, constant) interval in the length direction of the column portions 22A, 22B of the frame body 22. Is arranged with. The connecting plates 23A, 23B, and 23C connect the support portions 22A, 22B of the frame body 22 together with the connecting portions 22C, 22D of the frame body 22.

The central connecting plate 23A located at the center of the three connecting plates 23A, 23B, and 23C is provided between the rotary fitting cylinder portion 24 and the step position fixing cylinder portion 26. That is, one side of the central connecting plate 23A is fixed to the outer peripheral side of the rotary fitting cylinder portion 24 by using, for example, welding means, and the other side is fixed to the outer peripheral side of the step position fixing cylinder portion 26 by using, for example, welding means. ing. A semicircular cutout relief portion 23A1 is provided on one side of the central connecting plate 23A, that is, on the rotary fitting cylinder portion 24 side. The tip of the fixing pin 27 enters the relief portion 23A1 when the guard member 21 is in the step position. As a result, the tip of the fixing pin 27 and the central connecting plate 23A are prevented from interfering with each other.

Further, the outer edge 23A2 of the central connecting plate 23A (for example, the X-direction side in FIG. 9) projects outward from the outer end of the rotary fitting cylinder portion 24. That is, the outer corner portion 23A3 on one side of the central connecting plate 23A projects outward from the outer opening edge of the rotary fitting cylinder portion 24. When the guard member 21 is rotated, the corner portion 23A3 enters the notch 20A of the rotation restricting member 20. Then, for example, the guard member 21 is rotated counterclockwise around the guard support shaft portion 12 from the guard position to the step position. At this time, the guard member 21 is positioned at the step position by the corner portion 23A3 coming into contact with the step portion 20A2 corresponding to the 9 o'clock position in the notch 20A. On the other hand, the guard member 21 is rotated clockwise around the guard support shaft portion 12 from the step position to the guard position. At this time, the guard member 21 is positioned at the guard position by the corner portion 23A3 coming into contact with the step portion 20A1 corresponding to the 12 o'clock position in the notch 20A.

The three connecting plates 23A, 23B, 23C including the central connecting plate 23A are provided with female screw holes 23A4, 23B1, 23C1 for attaching articles to the connecting plates 23A, 23B, 23C. Further, the tread plates 22F and 22F provided in the connecting portions 22C and 22D of the frame body 22 are also provided with female screw holes 22F1, 22F1 for attaching articles to the tread plates 22F and 22F. Therefore, as in the first modification shown in FIG. 10, a storage box 31 such as a tool box is bolted (shown) to the first connecting plate 23B which is on the upper side when the guard member 21 is in the step position. It can be attached using. In this case, the bottom plate of the storage box 31 is provided with a female screw hole for screwing a bolt.

Further, for example, a mounting table 32 for mounting various articles such as a chainsaw and a carrying tank can be attached to the tread plate 22F of one connecting portion 22C by using bolts 33. Further, as in the second modification shown in FIG. 11, the mounting base 32 can be attached to both the tread plate 22F of one connecting portion 22C and the tread plate 22F of the other connecting portion 22D by using the bolt 33. .. By providing the mounting table 32 in this way, the portion on which the foot is placed or the portion on which the article is placed can be made wider (extended) than the tread plate 22F.

The rotary fitting cylinder portion 24 is rotatably fitted to the guard support shaft portion 12 (support cylinder portion 14). The rotary fitting cylinder portion 24 is provided on one of the strut portions 22A of the pair of strut portions 22A and 22B. In this case, the rotary fitting cylinder portion 24 is located at the intermediate portion in the length direction of one of the strut portions 22A. The rotary fitting cylinder portion 24 is formed as a cylindrical body. A guard support shaft portion 12 (support cylinder portion 14) is rotatably inserted through the inner peripheral side of the rotary fitting cylinder portion 24. As a result, the guard member 21 can rotate around the support cylinder portion 14 of the guard support shaft portion 12.

Further, the rotary fitting cylinder portion 24 has a shorter axial dimension than the support cylinder portion 14 of the guard support shaft portion 12. As a result, the rotary fitting cylinder portion 24 can move in the axial direction of the guard support shaft portion 12 (support cylinder portion 14). Specifically, as shown in FIG. 9, the rotary fitting cylinder portion 24 moves in the axial direction by the axial dimension A between the frame mounting portion 13 of the guard support shaft portion 12 and the rotation restricting member 20. It is possible. That is, the guard member 21 can be moved between the position shown by the broken line and the position shown by the solid line in FIG. 9 by the axial dimension A. In this case, the axial dimension A is larger than the axial dimension (height dimension, protruding dimension) B of the fixed shaft 19 of the guard fixed shaft portion 17.

That is, the inner end of the rotary fitting cylinder portion 24 is in contact with the support plate 13A of the frame mounting portion 13, and the guard position fixing cylinder portion 25 is fitted to the fixed shaft 19 of the guard fixing shaft portion 17. When the axial dimension A is moved in the X direction from this state, the state shown by the solid line in FIG. 9 is obtained. In this state, the guard position fixing cylinder portion 25 is separated from the fixing shaft 19 of the guard fixing shaft portion 17 by the gap dimension C, and the corner portion 23A3 of the central connecting plate 23A is in the notch 20A of the rotation restricting member 20. Get in. That is, the axial dimensions A and B and the gap dimension C have a relationship of AB = C. When the guard member 21 is moved from the position shown by the broken line in FIG. 9 to the position shown by the solid line, the guard member 21 can rotate along the notch 20A of the rotation restricting member 20.

The rotary fitting cylinder portion 24 is provided with pin holes 24A and 24B, respectively, at positions separated by 90 ° in the circumferential direction. That is, the rotary fitting cylinder portion 24 is provided with a pair of guard position pin holes 24A, 24A facing each other at positions corresponding to the direction in which the support column portion 22A extends. Further, the rotary fitting cylinder portion 24 is provided with a pair of pin holes 24B and 24B for step positions facing each other at positions corresponding to the direction in which the central connecting plate 23A extends. A fixing pin 27 is inserted into the guard position pin holes 24A and 24A when the guard member 21 is fixed to the guard position. A fixing pin 27 is inserted into the step position pin holes 24B and 24B when the guard member 21 is fixed at the step position. As shown in FIG. 8, the separation dimension K between the center of the guard position pin holes 24A and 24A and the step position pin holes 24B and 24B and the inner edge of the rotary fitting cylinder portion 24 is the guard support shaft portion 12 The distance between the center of the pin hole 14A of the support cylinder portion 14 and the support plate 13A of the guard support shaft portion 12 is the same as the separation dimension L. That is, the separation dimensions K and L are K = L.

The guard position fixing cylinder portion 25 fits into the guard fixing shaft portion 17 (fixed shaft 19) when the guard member 21 is in the guard position. The guard position fixing cylinder portion 25 is provided on one of the support column portions 22A and 22B. In this case, the guard position fixing cylinder portion 25 is located on one end side in the length direction of one of the strut portions 22A (the side that is the rear end side at the guard position and the lower end side at the step position). The guard position fixing cylinder portion 25 is formed as a cylindrical body. When the guard member 21 is in the guard position, the fixing shaft 19 of the guard fixing shaft portion 17 is inserted inside the guard position fixing cylinder portion 25.

The step position fixing cylinder portion 26 fits into the guard fixing shaft portion 17 (fixed shaft 19) when the guard member 21 is in the step position. The step position fixing cylinder portion 26 is provided on the other strut portion 22B of the pair of strut portions 22A and 22B. In this case, the step position fixing cylinder portion 26 is located at the intermediate portion in the length direction of the other strut portion 22B. The step position fixing cylinder portion 26 is formed as a cylindrical body. When the guard member 21 is in the step position, the fixing shaft 19 of the guard fixing shaft portion 17 is inserted inside the step position fixing cylinder portion 26.

The fixing pin 27 is a rotation blocking pin that prevents the rotation fitting cylinder portion 24 of the guard member 21 from rotating around the guard support shaft portion 12 (support cylinder portion 14). The fixing pin 27 has a rotary fitting cylinder portion 24 when the guard member 21 is in the guard position and the inner end portion of the rotary fitting cylinder portion 24 is in contact with the support plate 13A of the frame mounting portion 13. Can be inserted into the guard position pin holes 24A and 24A and the pin holes 14A of the guard support shaft portion 12 (support cylinder portion 14). Further, the fixing pin 27 has a rotary fitting cylinder when the guard member 21 is in the step position and the inner end of the rotary fitting cylinder portion 24 is in contact with the support plate 13A of the frame mounting portion 13. It can be inserted into the step position pin holes 24B and 24B of the portion 24 and the pin holes 14A of the guard support shaft portion 12 (support cylinder portion 14).

The base end side of the fixing pin 27 is a grip portion 27A that is gripped when the fixing pin 27 is inserted and removed. An engagement hole 27B (FIG. 8) to which a retaining tool 28 serving as a stopper is attached is provided on the tip end side of the fixing pin 27. The fixing pin 27 is prevented from coming out of the pin holes 24A, 24B, 14A by attaching the retaining tool 28 to the engaging hole 27B. On the other hand, when the retaining tool 28 is removed from the engaging hole 27B of the fixing pin 27, the fixing pin 27 can be pulled out from the pin holes 24A, 24B, 14A.

Then, when the fixing pin 27 is pulled out from the pin holes 24A, 24B, 14A and the guard member is moved in the X direction of FIG. 9, the corner portion 23A3 of the guard member 21 enters the notch 20A of the rotation restricting member 20. Further, the guard position fixing cylinder portion 25 or the step position fixing cylinder portion 26 of the guard member 21 is detached from the fixing shaft 19 of the guard fixing shaft portion 17. In this state, the guard member 21 can rotate within the range of the notch 20A of the rotation restricting member 20, that is, within a range of 90 ° between the guard position and the step position.

As described above, in the embodiment, the guard support shaft portion 12 and the guard fixed shaft portion 17 are attached to the upper swing body 4, and the guard member is used by using the guard support shaft portion 12 and the guard fixed shaft portion 17. 21 is attached to the upper swing body 4. On the other hand, the guard member 21 includes a frame body 22 formed of a pipe material in a frame shape and connecting plates 23A, 23B, 23C formed of a plate material (plate material) and arranged in parallel with each other in the frame body 22. It is composed of. In this case, the guard member 21 has a rotary fitting cylinder portion 24 that is rotatably supported by the support cylinder portion 14 of the guard support shaft portion 12, and a horizontal direction (guard position) and a direction perpendicular to the support cylinder portion 14. A guard position fixing cylinder portion 25 and a step position fixing cylinder portion 26 for maintaining the posture of the guard member 21 are provided at (step position).

Here, the guard position fixing cylinder portion 25 and the step position fixing cylinder portion 26 are arranged at the same distances H2 and H3 from the rotary fitting cylinder portion 24, respectively. Therefore, even if the guard member 21 is rotated by 90 °, the guard position fixing cylinder portion 25 or the step position fixing cylinder portion 26 can be supported by the fixed shaft 19 of the guard fixing shaft portion 17. When the guard member 21 is arranged at the step position, the connecting portions 22C and 22D of the frame body 22 and the connecting plates 23A, 23B and 23C can be used as steps.

To rotate the guard member 21 from the guard position (FIGS. 1 and 2) to the step position (FIGS. 3 and 4), first pull out the fixing pin 27 from the pin holes 24A and 14A and pull the guard member 21 toward you (FIG. 3 and 4). Move in the X direction of 9). When the guard member 21 is pulled toward you, the corner portion 23A3 of the central connecting plate 23A of the guard member 21 enters the notch 20A, and the guard position fixing cylinder portion 25 is separated from the fixing shaft 19 of the guard fixing shaft portion 17. Move to. At this time, the guard member 21 is prevented from rotating clockwise based on the contact between the step portion 20A1 of the notch 20A and the corner portion 23A3.

Then, when the guard member 21 is completely moved to the front, that is, when the outer end of the rotary fitting cylinder portion 24 is displaced in the X direction in FIG. 9 until it comes into contact with the rotation restricting member 20, the guard position is fixed. The tubular portion 25 is detached from the fixed shaft 19 of the guard fixed shaft portion 17, and the guard member 21 can be rotated 90 ° counterclockwise along the notch 20A. When the corner portion 23A3 of the central connecting plate 23A of the guard member 21 comes into contact with the step portion 20A2 of the notch 20A due to this counterclockwise rotation, the guard member 21 is prevented from rotating further counterclockwise. Will be done.

In this state, when the guard member 21 is pushed in the direction opposite to the X direction in FIG. 9, the step position fixing cylinder portion 26 fits into the fixed shaft 19 of the guard fixing shaft portion 17. Finally, the fixing pin 27 is inserted into the pin holes 24B and 14A, and the retaining tool 28 is attached to the tip of the fixing pin 27 (engagement hole 27B). In this case, as shown in FIG. 5, the guard member 21 can be used as a step (ladder), and access to the fuel filler port of the fuel tank 10 (the fuel filler port of the hydraulic oil tank 9 if necessary) becomes easy. ..

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

When the operator on board the cab 7 starts the engine, the engine drives the hydraulic pump. The pressure oil discharged from the hydraulic pump is used for the traveling lever / pedal operating device provided in the cab 7, the lever operation of the working lever operating device, and the traveling hydraulic motor, the turning hydraulic motor, and the boom according to the pedal operation. Discharge toward the cylinder 5D, arm cylinder 5E, work tool cylinder 5F, and the like. As a result, the hydraulic excavator 1 can perform a traveling operation by the lower traveling body 2, a turning operation of the upper rotating body 4, a wood gripping operation by the front device 5, and the like.

When working with the hydraulic excavator 1, the guard member 21 is fixed at the guard position. In this case, the upper swing body 4 can be protected from surrounding obstacles (for example, trees) by the guard member 21. When the work is finished, the operator stops the engine. Then, for example, when refueling the fuel tank 10 (the hydraulic oil tank 9 if necessary), the guard member 21 is rotated from the guard position to the step position, and the guard member 21 is fixed at the step position. In this case, as shown in FIG. 5, the guard member 21 can be used as a step to approach the fuel filler port of the fuel tank 10 (the hydraulic oil tank 9 if necessary). As a result, the fuel tank 10 (the hydraulic oil tank 9 if necessary) can be easily refueled.

As described above, according to the embodiment, the outside of the right side frame 6F which is one of the left and right side frames 6E and 6F (that is, the side frame on the fuel tank 10 side as the oil storage tank). At the position, a guard member 21 is rotatably attached at a position corresponding to the fuel tank 10. The guard member 21 has a guard position that is entirely arranged above the lower traveling body 2 and extends in the front and rear directions to protect (guard) the fuel tank 10, and the upper rotating body 4 and the lower traveling body 2. By being arranged between the spaces and extending upward and downward, it is possible to switch to a step position that serves as an ascending / descending step on the upper swing body 4.

Therefore, when the guard member 21 is fixed at the guard position, the guard member 21 can protect the upper swing body 4 from surrounding obstacles (for example, trees). On the other hand, when the guard member 21 is fixed at the step position, the guard member 21 can be used as an elevating step to approach the fuel filler port of the fuel tank 10. As a result, the fuel tank 10 can be easily refueled. Moreover, when the guard member 21 is fixed to the step position, the position of the first step (one connecting portion 22C) from the bottom of the guard member 21 is set to a position lower than the upper surface of the track 2A of the lower traveling body 2. be able to. In other words, by lowering the position of the first step (one connecting portion 22C) from the bottom of the guard member 21 to, for example, the position of the knee of a person, the ascending / descending operation can be easily performed. As a result, the upper swing body 4 can be easily moved up and down, and the fuel tank 10 can be easily refueled from this aspect as well.

According to the embodiment, the guard support shaft portion 12 that rotatably supports the guard member 21 and the guard member 21 are fixed to the guard position and the step position on the right side frame 6F which is one side frame. A guard fixing shaft portion 17 is provided. On the other hand, the guard member 21 includes a rotary fitting cylinder portion 24 that rotatably fits into the guard support shaft portion 12 and a guard position fixing cylinder that fits into the guard fixing shaft portion 17 when the guard member 21 is in the guard position. A portion 25 and a step position fixing cylinder portion 26 that fits into the guard fixing shaft portion 17 when the guard member 21 is in the step position are provided.

Therefore, the guard member 21 can be moved to the guard position or the step position by rotating the guard support shaft portion 12 of the right side frame 6F. At this time, by fitting the guard position fixing cylinder portion 25 of the guard member 21 to the guard fixing shaft portion 17 of the right side frame 6F, the guard member 21 can be stably fixed to the guard position. On the other hand, by fitting the step position fixing cylinder portion 26 to the guard fixing shaft portion 17 of the right side frame 6F, the guard member 21 can be stably fixed to the step position.

According to the embodiment, the guard support shaft portion 12 is provided with a rotation regulating member 20 that regulates the rotation of the guard member when the guard member 21 is rotated. Therefore, the positioning of the guard member 21, that is, the "positioning of the guard member 21 at the guard position" and the "positioning at the step position" can be easily performed by the rotation restricting member 20.

According to the embodiment, the guard member 21 is arranged with a pair of support columns 22A and 22B extending in parallel with each other and a pair of support columns 22A and 22B at predetermined intervals in the length direction. It is provided with connecting portions 22C and 22D and connecting plates 23A, 23B and 23C, which are a plurality of connecting members for connecting the support columns 22A and 22B. Then, one of the pair of strut portions 22A and 22B is provided with the rotary fitting cylinder portion 24 located at the intermediate portion in the length direction of the one strut portion 22A, and has a length. A cylinder portion 25 for fixing the guard position is provided on one end side in the direction. Further, the other strut portion 22B of the pair of strut portions 22A and 22B is provided with a step position fixing cylinder portion 26 located at an intermediate portion in the length direction of the other strut portion 22B.

Therefore, when the guard member 21 is in the guard position, the connecting portions 22C, 22D and the connecting plates 23A, 23B, 23C can be used as guards, while when the guard member 21 is in the step position, the connecting portions 22C, 22D and connecting plates 23A, 23B, 23C can be used as steps.

According to the embodiment, all of the plurality of connecting members, that is, the tread plates 22F, 22F and the connecting plates 23A, 23B, 23C of the connecting portions 22C, 22D are connected to the tread plates 22F, 22F of the connecting portions 22C, 22D. Female screw holes 22F1, 23A4, 23B1, 23C1 for attaching articles to the plates 23A, 23B, 23C are provided.

Therefore, for example, as in the first modification shown in FIG. 10, a storage box 31 such as a tool box can be attached to the first connecting plate 23B using bolts (not shown). Further, for example, a mounting table 32 for mounting various articles such as a chainsaw and a carrying tank can be attached to the tread plate 22F of one connecting portion 22C by using a bolt 33. Further, as in the second modification shown in FIG. 11, the mounting base 32 can be attached to the tread plates 22F and 22F of the connecting portions 22C and 22D by using bolts 33. As a result, even in a site where only the hydraulic excavator 1 can be inserted in the mountains (that is, a site where a transport vehicle such as a truck cannot be inserted), a storage box 31, a chainsaw, a carrying tank, etc. You can bring in various items.

In the embodiment, female screw holes 22F1, 23A4, 23B1 for attaching articles to all of the plurality of connecting members, that is, the tread plates 22F, 22F and the connecting plates 23A, 23B, 23C of the connecting portions 22C, 22D, respectively. The configuration in which 23C1 is provided has been described as an example. However, the present invention is not limited to this, and for example, a female screw hole may be provided in any of a plurality of connecting members. That is, the female screw hole can be provided in at least one of the plurality of connecting members. Further, the female screw hole may be omitted.

In the embodiment, a case where the guard support shaft portion 12 and the guard fixed shaft portion 17 are attached to the right side frame 6F by using welding means has been described as an example. However, the present invention is not limited to this, and the guard support shaft portion and the guard fixing shaft portion may be attached to the side frame by using, for example, a fastener such as a bolt.

In the embodiment, when the guard member 21 is composed of the rectangular frame body 22 and the three connecting plates 23A, 23B, 23C, that is, the frame body 22 is "supported columns 22A, 22B" and "supported columns 22A, 22B". The case where the configuration is provided with the connecting portions 22C and 22D that serve as steps at the step position has been described as an example. However, the present invention is not limited to this, and for example, although not shown, by using the connecting portion of the frame body as a connecting plate, the guard member is connected to a support column made of a pair of rod-shaped bodies and five connections for connecting these columns. It may be composed of a plate. Further, the number of connecting members (connecting portion, connecting plate) is not limited to 5, and may be increased or decreased as necessary.

In the embodiment, a case where the fuel tank 10 is provided on the outside of the hydraulic oil tank 9 has been described as an example. However, the present invention is not limited to this, and for example, a hydraulic oil tank may be provided outside the fuel tank.

In the embodiment, the case where the hydraulic excavator 1 is provided with two oil storage tanks, a fuel tank 10 and a hydraulic oil tank 9, on the right side, which is one side in the left and right directions, has been described as an example. However, the present invention is not limited to this, and for example, one oil storage tank (fuel tank or hydraulic oil tank) may be provided on one side in the left and right directions.

In the embodiment, the case where the hydraulic excavator 1 is provided with an oil storage tank (fuel tank 10) on the right side in the left and right directions has been described as an example. However, the present invention is not limited to this, and for example, an oil storage tank (fuel tank and / or hydraulic oil tank) may be provided on the left side in the left and right directions.

In the embodiment, the rear ultra-small turning type (or rear small turning type) hydraulic excavator 1 has been described as an example. However, the present invention is not limited to this, and may be applied to, for example, a hydraulic excavator provided with a long upper swing body in the front and rear directions.

In the embodiment, a configuration in which the log grapple 5C is used as the attachment of the front device 5 of the hydraulic excavator 1 has been described as an example. However, the attachment is not limited to this, and various work tools including, for example, a bucket capable of excavating earth and sand can be used. That is, the hydraulic excavator can be widely applied not only to forestry machines used at forestry work sites but also to various construction machines (swivel type construction machines) used at work sites such as excavation, demolition, and underground construction. it can.

1 Hydraulic excavator (construction machinery)
2 Lower traveling body 4 Upper swivel body 5 Front device 6 Swivel frame 6A Bottom plate (center frame)
6B left vertical plate (center frame)
6C right vertical plate (center frame)
6E Left side frame 6F Right side frame (one side frame)
12 Guard support shaft 17 Guard fixed shaft 20 Rotation control member 21 Guard member 22A, 22B Strut (post)
22C, 22D connecting part (connecting member)
23A, 23B, 23C connecting plate (connecting member)
22F1,23A4,23B1,23C1 Female screw hole 24 Rotational fitting cylinder part 25 Guard position fixing cylinder part 26 Step position fixing cylinder part 31 Storage box (article)
32 Stand (article)

Claims (5)

It consists of a lower traveling body that can run on its own by tracks and an upper turning body that is mounted on the lower running body so that it can turn.
The upper swivel body includes a swivel frame to which a front device is mounted on the front side, and an oil storage tank which is provided on the swivel frame on one side in the left and right directions with the front device in between and stores hydraulic oil or fuel. Is equipped with
The swivel frame includes a center frame having a bottom plate located in the middle of the left and right directions, and left and right side frames arranged on both sides of the center frame in the left and right directions and extending in the front and rear directions, respectively. In a construction machine composed of and
The left, to the outside position of one of the side frame of the right side frame are attached preparative guard member at a position corresponding to the oil storage tank,
The guard member includes a frame body composed of a pair of columns and a plurality of connecting members provided between the pair of columns at predetermined intervals while connecting the pair of columns.
By the guard member to be rotated, at the upper side of the entire said lower traveling body, and, prior to the length direction of the frame body of the side frame, is disposed along the rear direction, the oil storage tank a guard position protecting over between the lower traveling body and the upper rotating body, and, on the longitudinal direction of the frame body of the upper rotating body, is arranged along the downward direction, the upper swing structure It is possible to switch to the step position that is the step for raising and lowering .
In the state where the guard member is switched to the step position, the first-stage connecting member from the bottom among the plurality of connecting members of the guard member is arranged at a position lower than the upper surface of the crawler belt of the lower traveling body. Construction machinery characterized by being done. Wherein the one of the side frame, the guard support shaft portion for supporting lifting the guard member, and has the guard member guard fixing shank for fixing is provided with the step position and the guard position,
The guard member includes a rotary fitting cylinder portion that rotatably fits into the guard support shaft portion, and a guard position fixing cylinder portion that fits into the guard fixing shaft portion when the guard member is in the guard position. The construction machine according to claim 1, wherein the guard member includes a step position fixing cylinder portion that fits into the guard fixing shaft portion when the guard member is in the step position. The construction machine according to claim 2, wherein the guard support shaft portion is provided with a rotation restricting member that regulates the rotation of the guard member when the guard member is rotated. On one of the struts of the prior Symbol pair of struts, the together with the rotating fitting tube is provided, located at one end of the longitudinally positioned in the middle portion in the length direction of the one of the struts The guard position fixing cylinder is provided.
2. The second aspect of the present invention, wherein the other column of the pair of columns is provided with the step position fixing cylinder portion located at an intermediate portion in the length direction of the other column. Construction machinery. At least one of the coupling members of the prior SL plurality of connecting members, the construction machine according to claim 1, characterized in that female screw holes for mounting the article on the connecting member.

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