JP4264495B2 - Excavation work vehicle - Google Patents

Description

  The present invention relates to a swivel structure for an excavating work vehicle, and more particularly to a support structure for a swing cylinder base.

  In the excavation work vehicle, the boom bracket pivotally supported by the attachment portion is rotated left and right by the swing cylinder. One end portion of the swing cylinder is pivotally supported by the boom bracket, and a base portion which is the other end portion on one side is pivotally supported by a mounting portion provided at a lower portion of the swing frame. Thus, the swing cylinder is expanded and contracted in the front-rear direction by hydraulic pressure, and the boom bracket is rotated left and right by the expansion and contraction.

  By the way, as shown in Patent Document 1, for example, a conventional swing cylinder base support structure is configured such that a base of the swing cylinder is pin-shaped on a mounting portion molded in a substantially U-shape in cross section on a revolving frame flat plate portion. It was pivotally supported (see Patent Document 1). More specifically, in order to mold a revolving frame having a substantially U-shaped attachment portion in cross-section, a nested member is interposed in a place corresponding to the insertion portion at one end of the swing cylinder. The swivel frame was formed by inserting.

JP-A-11-324016

  However, if the mounting portion of the swing cylinder is formed by such a molding method as described above, there is a technical problem that the insert member tends to be damaged due to a broken mold or the like, and the cost for producing the mold is high.

  Accordingly, the present invention relates to an excavation work vehicle that solves the above-described conventional problems, and can easily form a mold on a flat plate portion, reduce molding costs, and prevent member loss. The object is to propose a support structure for the base.

The problems to be solved by the present invention are as described above. Next, means for solving the problems will be described.
A boom bracket (10) is attached to the swing frame (50) so as to be turnable in the left-right direction, and a swing cylinder (21) is interposed between the boom bracket (10) and the swing frame (50). In the excavation work vehicle in which the excavation work machine (6) attached to the vehicle is pivotable in the left-right direction, the swing cylinder is provided on the lower side inside the outer peripheral frame (59) on the side of the flat plate part (51) of the turning frame (50). An attachment portion (61) for pivotally supporting the base side of (21) is formed, the attachment portion (61) is formed in a substantially L shape in cross section, and the attachment portion (61) has a lower upper surface. (61a) and an upper upper surface (61b) are provided, a mounting hole (66) is formed in the vertical direction in the center of the lower upper surface (61a), and a plurality of screw holes are formed in the upper upper surface (61b). Lower upper surface (61a) and upper upper side The difference in the height of (61b) is made to substantially coincide with the height of the base side of the swing cylinder (21), and the size of the mounting hole (66) is set vertically on the base side of the swing cylinder (21). The support hole (64) is approximately the same size as the opening, and the support shaft (67) is inserted into and supported by the support hole (64) and the attachment hole (66). The upper portion of the support shaft (67) is a fixed plate. (62) is fixed to one end, a hole is opened on the other side of the fixing plate (62), and a bolt (63) is inserted and screwed in alignment with the screw hole opened on the upper upper surface (61b). It is fixed .

As effects of the present invention, the following effects can be obtained.
A boom bracket (10) is attached to the swing frame (50) so as to be turnable in the left-right direction, and a swing cylinder (21) is interposed between the boom bracket (10) and the swing frame (50). In the excavation work vehicle in which the excavation work machine (6) attached to the vehicle is pivotable in the left-right direction, the swing cylinder is provided on the lower side inside the outer peripheral frame (59) on the side of the flat plate part (51) of the turning frame (50). An attachment portion (61) for pivotally supporting the base side of (21) is formed, the attachment portion (61) is formed in a substantially L shape in cross section, and the attachment portion (61) has a lower upper surface. (61a) and an upper upper surface (61b) are provided, a mounting hole (66) is formed in the vertical direction in the center of the lower upper surface (61a), and a plurality of screw holes are formed in the upper upper surface (61b). Lower upper surface (61a) and upper upper side The difference in the height of (61b) is made to substantially coincide with the height of the base side of the swing cylinder (21), and the size of the mounting hole (66) is set vertically on the base side of the swing cylinder (21). The support hole (64) is approximately the same size as the opening, and the support shaft (67) is inserted into and supported by the support hole (64) and the attachment hole (66). The upper portion of the support shaft (67) is a fixed plate. (62) is fixed to one end, a hole is opened on the other side of the fixing plate (62), and a bolt (63) is inserted and screwed in alignment with the screw hole opened on the upper upper surface (61b). Since it is fixed, it is not necessary to use a nested member as in the prior art, and the molding cost can be reduced and the loss of the member can be prevented. Even if a strong attractive force or repulsive force is applied to the swing cylinder, the swing cylinder can be stably supported and fixed by the fixing plate.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. 1 is a side view of an excavation work vehicle according to the present invention, FIG. 2 is a front view, FIG. 3 is a rear view, and FIG. 4 is a plan view. FIG. 5 is a plan view showing the internal structure of the revolving structure, and FIG. 6 is a plan view showing the turning of the excavation work vehicle. 7 is a perspective view of the swing frame, FIG. 8 is a lower perspective view of the swing frame, FIG. 9 is a perspective view of the vicinity of the swing cylinder mounting portion, and FIG. 10 is a sectional view of the mounting portion taken along the line XX. . 11 is a rear view of the plate, FIG. 12 is a plan view of the same, FIG. 13 is a perspective view showing the state of attachment to the mounting plate, and FIG. 14 is a perspective view of the rear part of the revolving unit. FIG. 15 is a perspective view of the revolving body in a state where the bonnet is rotated backward, FIG. 16 is a perspective view of the revolving body in the same state of forward rotation, FIG. 17 is a perspective view of a lock pin mounting member, and FIG. 19 is a plan view, and FIG. 20 is a perspective view and a front view of the lock mechanism.

  First, the overall configuration of a backhoe 1 that is an embodiment of an excavation work vehicle according to the present invention will be described with reference to FIGS. 1 to 4. Hereinafter, the mounting direction of the boom 9 in FIG. In FIG. 4, the excavation work machine 6 is omitted for convenience of explanation. In the backhoe 1, the revolving structure 2 is supported by a swivel joint 35, which will be described later, on an upper part of a crawler type traveling device 3 equipped with a pair of left and right crawlers so as to be able to turn left and right. A swivel frame 50 is formed in the lower part of the swivel body 2, and a mounting portion 52 of the boom bracket 10 is formed to project from the front left and right center of the swivel frame 50. The rear upper part of the swivel frame 50 is covered with a bonnet 4. A driver's seat 5 is disposed on the bonnet 4, and a front column 19 is disposed at a position in front of the driver's seat 5 and behind the excavator 6 above the front portion of the revolving frame 50.

  From the lower part of the front column 19, support plates 22 are extended on both sides and rearward. The support plate 22 is integrally formed with the front column 19, and the support plate 22 is located above the front portion of the swivel frame 50. It is fixed. A step 23 made of synthetic resin, rubber, or the like is laid under the front portion of the driver's seat 5 so as to cover the support plate 22, thereby securing a foothold when the operator is working or running. Further, the front column 19 is configured to rotate a bucket 7 and a boom 9 of the excavating work machine 6 to be described later, to rotate the revolving body 2, and to move the left and right crawlers forward and backward formed on the crawler type traveling device 3. In addition, an operation lever group for performing a rotation operation of the blade 20 described later is provided.

  The excavation work machine 6 is configured as follows. That is, the boom bracket 10 is pivotally supported by the mounting portion 52 so as to be pivotable in the left-right direction, and the base portion of the boom 9 is pivotally supported by the boom bracket 10 so as to be pivotable back and forth. A swing cylinder 21 is interposed between the boom bracket 10 and the swivel body 2, and the excavation work machine 6 can be turned to the left and right with respect to the swivel body 2 by expansion and contraction of the swing cylinder 21.

A boom cylinder 11 is interposed between the boom 9 and the boom bracket 10 between the boom 9 and the front bent portion, and the boom 9 can be turned up and down by the expansion and contraction of the boom cylinder 11. ing. A base portion of the arm 8 is rotatably attached to the tip of the boom 9, and an arm bracket 14 is projected upward from the base portion of the arm 8. An arm cylinder 12 is interposed between the boom 9 and the boom bracket 10 inside the front bent portion of the boom 9, and the arm 8 can be rotated back and forth by expansion and contraction of the arm cylinder 12. ing.

  Further, a bucket 7 as a work attachment is pivotally supported at the distal end portion of the arm 8 so as to be pivotable back and forth. An arm link 15 is pivotally supported near the middle end of the arm 8 so as to be rotatable, and both ends of the bucket link 16 are rotatable between one end of the arm link 15 and the bucket 7. It is pivotally supported. Further, the arm bracket 14 protrudes above the base portion of the arm 8, and the bucket cylinder 13 is interposed between the arm bracket 14 and pivot points of the arm link 15 and the bucket link 16. . The bucket 7 is rotated by the expansion and contraction of the bucket cylinder 13.

  Next, the internal configuration of the revolving structure 2 will be outlined below. As shown in FIG. 5, an engine 29, a battery 31, a fuel tank 32, a reservoir tank 33, a radiator 34 and the like serving as a prime mover are disposed inside the revolving structure 2. An oil filter 37 for hydraulic oil is disposed in front of the reservoir tank 33. In addition, a swivel joint 35 is connected to the center of the swivel body 2, and an engine 29 is disposed above the swivel joint 35. Details of the arrangement and mounting structure of the engine 29 will be described later.

  A flywheel 38 and a hydraulic pump 39 are connected to the front of the engine 29, and the hydraulic pump 39 is driven by the engine 29. The hydraulic pump 39 is connected to the swing cylinder 21, the swing motor 36, the swivel joint 35, the cylinder of the work machine 6, and the like via a hydraulic hose and a control valve in the front column 19. The swing cylinder 21 and the like can be driven by working oil discharged by the hydraulic pump 39.

  The radiator 34 is disposed at the rear portion of the swing body 2 so as to face the rear surface of the swing body 2. Since the radiator 34 is disposed immediately after the fan 41 disposed at the rear portion of the engine 29 in the rear view, the distance from the radiator 34 to the engine 29 can be shortened. . As will be described later, an exhaust port 42 is formed at the rear of the bonnet 4. Therefore, the exhaust air that has cooled the radiator 34 and the upper cylinder of the engine 29 by the fan 41 is discharged to the outside of the revolving structure 2 through the exhaust port 42.

  Below the radiator 34, a muffler 40 is provided horizontally in the left-right direction of the revolving frame 50. One end of the muffler 40 is connected to the exhaust port of the engine 29, and the other end on one side is penetrated through a rear opening 43 formed below the rear part of the turning frame 50. Exhaust gas discharged from the exhaust port of the engine 29 is discharged to the outside of the revolving structure 2 through the muffler 40.

In the present configuration example, as shown in FIG. 15, a unit body 30 attached to the frame body is configured so that the engine 29 and the radiator 34 and the like are integrated. In the unit body 30, the engine 29, the radiator 34, the muffler 40, and the like are attached by a mounting plate 75 on which a radiator 34 and the like, which will be described later, can be disposed, and a support frame 77 that can support the engine 29 and the like. Between the support frame 77 and the revolving frame 50, a rubber mount or a vibration isolator laminated rubber is disposed. The unit body 30 is a rear portion of the revolving frame 50 and is detachably fixed to the revolving frame 50 via the support frame 77 and the mounting plate 75. In this way, by making the unit body 30 detachable inside the revolving frame 50, the engine 29, the radiator 34, the swivel joint 35, etc. can be sufficiently maintained.

  The engine 29 has a crankshaft disposed in the front-rear direction, and the flywheel 38, the hydraulic pump 39, a drive pulley for the fan 41, and the like are connected to the crankshaft. Further, the crankshaft is arranged eccentrically so as to be closer to the left side than the center of the left and right of the revolving unit 2. By arranging the engine 29 in this way, a space can be formed on the left and right other sides of the engine 29 on the revolving frame 50, and the battery 31 and the like can be arranged in the space to achieve compactness. . Note that the arrangement configuration of the engine 29 is not limited as described above. For example, the crank shaft of the engine 29 may be arranged to be biased to the right side. Furthermore, you may comprise so that the longitudinal direction of this crankshaft and the front-back direction of the turning frame 50 may cross | intersect substantially perpendicularly.

In the backhoe 1 according to the present configuration example, the engine 29 is placed vertically (the longitudinal direction of the crankshaft of the engine 29 is turned) at a position overlapping the swivel joint 35 located at the turning center 54 of the turning frame 50 in a plan view. The frame 50 is arranged in a direction substantially coincident with the front-rear direction of the frame 50. As a result of the engine 29 being placed vertically, the engine 29 overlaps the swivel joint 35 in plan view, but the workability during maintenance of the swivel joint 35 is not impaired. The unit body 30 is configured. And by setting it as such an arrangement structure, it becomes possible to achieve size reduction of the turning frame 50 in the transversal direction.

Further, in the present configuration example, among the members constituting the unit body 30, it is the right side of the flywheel 38 disposed in the front part of the engine 29 that overlaps the swivel joint 35 in plan view. The flywheel 38 is a member that hardly rises in temperature even when the engine 29 is operating. Therefore, it is possible to prevent the heat generated by the engine 29 from affecting the swivel joint 35. With this configuration, the engine 29 can be disposed closer to the swivel joint 35, and the revolving structure 2 can be downsized to reduce the turning radius. Further, the flywheel 38 has a substantially circular shape in a front view and a substantially truncated cone shape in a plan view. Therefore, the flywheel 38 is relatively large between a lower right front outer peripheral surface shifted from the center and the upper surface of the revolving frame 50. A space can be formed, and by arranging the swivel joint 35 in the space, simple maintenance and the like can be performed from the side gap.

  Further, a reservoir tank 33 is disposed in front of the left side of the engine 29 in the longitudinal direction of the revolving frame 50. The reservoir tank 33 stores the hydraulic oil of the hydraulic pump 39 and is connected to the hydraulic pump 39 by a hydraulic pipe (not shown). A flywheel 38 disposed in front of the engine 29 is disposed on the right side of the rear portion of the reservoir tank 33. Therefore, the reservoir tank 33 and the flywheel 38 can be placed closer to each other by forming a chamfered slope with the corner of the right rear end of the reservoir tank 33 cut away, and the swivel frame 50 can be moved back and forth. The capacity of the reservoir tank 33 can be increased as much as possible.

  A fuel tank 32 is disposed at the left front portion of the engine 29. In particular, as described above, since the engine 29 and the like are arranged closer to the left than the center of the turning frame 50, the capacity of the fuel tank 32 can be increased. In addition, the swing cylinder 21 is provided horizontally in the front-rear direction of the revolving frame 50 below the fuel tank 32 and the battery 31. As will be described later, one end of the swing cylinder 21 is pivotally supported by a mounting portion 61 formed at the right inner end of the revolving frame 50, and one end thereof is rotatable with the boom bracket 10. It is connected to the.

  Next, the revolving structure of the excavation work vehicle according to the present invention will be described. First, the front structure of the turning frame 50 will be described below. As shown in FIGS. 5 to 7, the revolving frame 50 has a substantially semicircular rear portion, a substantially rectangular central portion, and a substantially W-shaped front portion in plan view. The outer periphery of the substantially flat plate portion 51 is extended upward by a predetermined height. A mounting portion 52 of the boom bracket 10 is formed to project forward in a substantially convex shape in plan view at the center of the front end of the revolving frame 50. An insertion hole for inserting the support shaft is opened in the vertical direction at the front end of the mounting portion 52. The revolving frame 50 is integrally formed with a mold. For this reason, the same shape can be easily manufactured and the structure of the revolving frame 50 can be easily secured.

  Further, front end projecting portions 50a and 50a are formed on both the left and right sides of the front portion of the revolving frame 50, and the positions of the front surfaces of the front end projecting portions 50a and 50a are rearward of the front end of the mounting portion 52 and the front column 19 It is located in front of the front end face. The front surfaces of the front end protrusions 50a and 50a have a predetermined width, which is sufficient to allow the operator's feet to be placed thereon. A base portion 52a having a substantially V shape in plan view is formed between the front end protruding portions 50a and 50a and the mounting portion 52 so as to form a recess, thereby reducing the weight of the turning frame 50. By constructing the swivel frame 50 in this way, the swivel body 2 can be made compact by ensuring that the internal capacity of the swivel frame 50 is secured while allowing the operator's feet to be placed on both sides of the front column 19. It is.

The relationship between the shape of the front end protrusion 50a and the turning radius of the turning frame 50 will be described with reference to FIG. The swivel body 2 has a circle center of the swivel joint 35 as a turning center 54. A distance L1 from the turning center 54 to the front end of the attachment portion 52 or a distance L2 from the rear end portion of the turning frame 50 to the substantially right and left central portion 50d is the turning radius of the turning body 2. In the revolving structure 2 according to this configuration example, the distance L2 is formed to be the turning radius. That is, since the boom bracket 10 is attached to the front portion of the revolving structure 2, the balance of the backhoe 1 is maintained by forming the distance L2 to be longer than the distance L1 (L2> L1). I have to.

  In the turning frame 50, the outer peripheral shape of the left and right front corners 50b of the front end protrusion 50a is an arc, and the outer peripheral shape of the left and right rear corners 50c of the rear is also an arc. The front end protruding portion 50a protrudes forward from the base portion 52a of the mounting portion 52, but the distance L3 from the turning center 54 to the front corner portion 50b is the rear corner portion 50c from the turning center 54. The distance L4 is equal to or shorter than the distance L4 (L3 ≦ L4).

The rear corner portion 50c and the left and right substantially central portions 50d of the rear end portion are formed so as to be on substantially the same arc. In the present configuration example, when the turning frame 50 is turned left and right, they become the same turning track 57. That is, the turning frame 50 is formed such that the distance L2 and the distance L4 are the same (L2 = L4).

  In the turning frame 50, the distance L3 from the turning center 54 to the front corner 50b is the same as or shorter than the distance L2 (= L4) as the turning radius (L3 ≦ L2 = L4). The turning track 56 is included in the turning track 57 of the turning frame 50. Therefore, even if the front end protruding portion 50a is formed to protrude forward, the revolving structure 2 can turn left and right without the front corner portion 50b colliding with an obstacle or the like, and the turning performance of the turning frame 50 is impaired. Absent. In other words, the revolving structure 2 in which the internal space of the revolving frame 50 can be widely used by forming the front end projecting portion 50a so that the distance L3 is equal to or shorter than the distance L2 or the distance L4. It can be set as this structure.

That is, in the present configuration example, first, when the turning frame is made compact, the distance L1 and the distance L2 that is the turning radius are shortened. The distance L3 is formed to be the same as or shorter than the turning radius. As long as the swivel frame 50 is reduced in the front-rear direction so that the swivel radius of the swivel frame 50 is reduced, the swivel performance of the swivel frame 50 is not impaired. Thus, the space of the front end protrusion 50a can be utilized to the maximum.

  Since the engine 29, the reservoir tank 33, the oil filter 37, the swing cylinder 21 and the like are disposed in the revolving frame 50 as described above, the reservoir tank is used when the revolving frame 50 is reduced in the front-rear direction. An arrangement space such as 33 must be secured at the same time. By providing the front end protrusion 50a, the internal space of the front end protrusion 50a can be used for disposing the reservoir tank 33 and the like even when the revolving frame 50 is reduced in the front-rear direction. That is, the distance L1 and the distance L2 are formed to be short so that the revolving body 2 can be made compact, and at the same time, a space for arranging the reservoir tank 33 and the like can be secured.

  Further, since the swing cylinder 21 is disposed on the right side of the revolving frame 50, the rod portion of the swing cylinder 21 can be protected by forming the right front end protruding portion 50a. it can. The swing cylinder 21 is expanded and contracted in the front-rear direction by hydraulic pressure, and the boom bracket 10 pivotally supported by the mounting portion 52 is rotated left and right by the swing cylinder 21. Therefore, the base portion 52a and the front end protruding portion 50a are formed to have different left and right shapes so that the expansion and contraction and rotation of the swing cylinder 21 are not hindered.

  As shown in FIG. 4, the support plate 22 and the step 23 are laid on the front portion of the revolving frame 50 so as to cover the upper portion of the revolving frame 50. The shape of the support plate 22 and the like is substantially the same as that of the front part of the turning frame 50 including the front end protruding part 50a in plan view.

  Next, the outer peripheral structure of the turning frame 50 will be described below. As shown in FIG. 7, an outer peripheral frame 59 extends vertically upward from the outer edge of the flat plate portion 51 on the outer periphery of the rear portion of the revolving frame 50. The outer peripheral frame 59 is integrally formed with the flat plate portion 51. The outer peripheral frame 59 is gradually extended from the front end protruding portion 50a of the revolving frame 50 to the left / right / front / rear halfway portion from the outer edge of the flat plate portion 51 upward and gradually from the rear end of the front portion 59a. In the rear end portion, the rear end portion 59b is extended to a position slightly higher than the step 23.

  Cover bodies 60 and 60 formed in accordance with the outer peripheral shape are detachably attached to the upper portions of the inclined portions that rise upward in front of the front portion 59a and the rear portion 59b. The outer periphery frame 59 and the cover bodies 60 and 60 can protect the inside of the turning frame 50 from dust and the like. Since the cover bodies 60 and 60 are detachably disposed as described above, the cover bodies 60 and 60 are disposed on the front side portion inside the revolving frame 50 from the side with the cover bodies 60 and 60 removed. Maintenance of the oil filter 37 and reservoir tank 33, draining operation of the fuel tank 32, and the like can be easily performed.

  Further, the revolving frame 50 is formed such that the front portion 59a extends upward from the outer edge of the flat plate portion 51, so that the revolving frame 50 has a rigidity that does not cause a “crack or crack” even if it collides with an obstacle. I have. Further, the rear portion 59b is molded integrally with the flat plate portion 51, and not only increases the rigidity behind the revolving frame 50 but also functions as a counterweight. A plate 71 is detachably disposed in a recess 70 formed at the upper rear of the rear portion 59b. Details will be described later.

  Here, a plurality of openings 51a, 51a,... Are formed in the flat plate portion 51, and the openings 51a, 51a,. In order to insert a tool or the like from below, it is formed in accordance with the shape of the device / device arranged near the upper part thereof. Further, a center opening of the flat plate portion 51 is provided with a joint opening portion 53 for supporting the traveling device and inserting the swivel joint 35 and a motor opening portion 55 for attaching the turning motor 35.

  The turning motor 35 is one form of a turning actuator for driving the turning body 2 to turn with respect to the crawler traveling device 3, and a pinion gear (not shown) is externally fitted to the rotation shaft thereof, and the pinion gear is connected to the crawler traveling device. The swivel joint 35 provided on the side 3 is meshed with a gear (not shown) having a turning center. A portion of the swivel frame 50 extending from the mounting portion 50a to the joint opening 53 is thicker than the other portions of the swivel frame 50 because a large load is applied when the excavation work machine 6 is operated. Moreover, the site | part from the circumference | surroundings of the joint opening part 53 to a little back and right and left side is also formed thickly.

  As shown in FIG. 8, on the back surface of the flat plate portion 51, a portion from the mounting portion 50 a to the rear of the turning center 54 protrudes to the lower surface side of the turning frame 50, and a reinforcing rib 90 is formed. Since the rib 90 protrudes to the lower surface side of the revolving frame 50, it does not interfere with other components (engine, battery, etc.). Therefore, the strength of the revolving frame 50 is sufficiently secured, and the degree of freedom in arranging other constituent members on the revolving frame 50 is increased, and the revolving frame 50 is arranged by arranging the other constituent members in a dense state. Can be reduced in size and the turning radius can be reduced. In addition, since the rib (50) having a large protruding amount is not provided on the upper surface side of the revolving frame 50, it is easy for an operator to insert a hand from the side and workability during maintenance. Are better.

  The right covering part 90a and the left covering part 90b constituting the rear part of the rib 90 on the lower surface side of the turning frame 50 are provided in the crawler traveling device 3 for turning the turning frame 50 with respect to the crawler traveling device 3. An unillustrated gear and a pinion gear provided in the turning motor 35 are formed so as to cover the periphery. That is, the rib 90 also serves as a means for covering a pair of gears (pinion gear and gear) that mesh with each other. By configuring in this way, the rib 90 not only functions to reinforce the revolving frame 50 but also protects the gear related to the revolving of the revolving frame 50 (interference between the surrounding obstacles and the gear, Etc.), and the reliability of the part related to the turning of the upper structure of the backhoe 1 is improved.

Further, in the conventional drilling work vehicle, the upper end portion of the high protruding rib on the upper surface of the upper structure, had been used to attach the top plate for covering the upper portion of the upper structure, the present configuration example In the case of such a turning frame 50, there is no rib with such a large (high) protruding amount. Therefore, in the revolving frame 50 according to this configuration example, a plurality of boss portions 51b, 51b,... Are erected on the flat plate portion 51 to support the unit body 30 such as the engine 29. The support legs are used for fixing the frame, mounting and fixing a reservoir tank, a fuel tank, and the like, and fixing the support plate 22. With this configuration, it is not necessary to form a protrusion having a large protrusion amount on the upper surface of the swivel frame 2, so that the swivel frame 2 can be easily manufactured by casting.

  Here, the support structure for the base of the swing cylinder 21 inside the revolving frame will be described below. In the revolving structure 2 according to the present embodiment, as shown in FIGS. 9 and 10, the base side (bottom side) of the swing cylinder 21 is pivotally supported at the lower part of the outer peripheral frame 59 on the right side portion of the flat plate portion 51. A mounting portion 61 is formed for this purpose. The attachment portion 61 is formed in a substantially L shape in cross section, and is provided with a lower upper surface 61a and an upper upper surface 61b. A mounting hole 66 is formed in the center of the lower upper surface 61a in the vertical direction, and a plurality of screw holes are formed in the upper upper surface 61b. The difference in height between the lower upper surface 61a and the upper upper surface 61b is substantially the same as the height on the base side of the swing cylinder 21, and the size of the mounting hole 66 is a support hole that opens vertically on the base side of the swing cylinder 21. The size is approximately the same as 64, and the support shaft 67 is inserted into and supported by the support hole 64 and the attachment hole 66.

  The upper part of the support shaft 67 is fixed to one end of the fixed plate 62. In this embodiment, it is penetrated and fixed by welding, but it is not limited. Screw holes are opened on the other side of the fixing plate 62, and bolts 63 and 63 are inserted and screwed to be aligned with the screw holes opened on the upper upper surface 61b. In this manner, the support shaft 67 is fixed to a part of the flat plate portion 51 inside the revolving frame 5, so that the base portion of the swing cylinder 21 pivotally supported by the support shaft 67 As a center of rotation, it can be rotated in the left-right direction.

  Conventionally, the base portion of the swing cylinder 21 has been pivotally supported by a mounting portion that is molded on the flat plate portion 51 in a substantially U-shape in cross section. In order to mold the revolving frame 50 so as to have a substantially U-shaped cross-sectional view as in the conventional mounting portion, the nesting member is provided at a position corresponding to the insertion portion at one end of the swing cylinder 21. The swivel frame 50 was formed by inserting the. However, according to such a molding method, there is a technical problem that the nesting member is easily damaged due to mold breakage or the like, and the cost for producing the mold is high. Therefore, by configuring like the mounting portion 61 in this embodiment, the upper side of the lower upper surface 61a is open, so that the mold can be easily pulled up and down, and the nesting member and the like can be removed. Since the mold can be easily formed on the flat plate portion 51 without using it, the molding cost can be reduced and the loss of the member can be prevented.

  Further, as shown in FIG. 10B, a stepped portion 68 for fitting the fixing plate 62 into the upper upper surface 61b of the mounting portion 61 may be provided. That is, as shown in FIG. 10A, when the swing cylinder 21 is rotated by receiving a large force with the fixing plate 62 fastened and fixed by the bolt 63 on the horizontal surface of the upper upper surface 61b, the fixing plate 62 May be twisted or bent without being able to withstand the load. Therefore, as shown in FIG. 10B, the contact area between the fixing plate 62 and the upper upper surface 61b is increased by fitting the fixing plate 62 into the stepped portion 68 of the upper upper surface 61b and tightening and fixing with the bolts 63. The surfaces that contact each other also increase, the load resistance can be increased, and the support shaft 67 can be stably supported and fixed.

  Next, the rear structure of the turning frame 50 will be described below. As shown in FIGS. 3 and 7, a recessed portion 70 that is recessed downward is formed in the upper part of the rear surface of the left and right center of the rear portion 59 b. The recess 70 is provided with a plate 71 formed substantially in the same shape as the recess 70. As shown in FIGS. 11 and 12, the plate 71 has a substantially trapezoidal shape in front view in which both left and right sides are inclined inwardly from the upper side to the lower side, and the center of the left and right is curved backward (upward in FIG. 12). By doing so, it is formed along the shape of the rear portion 59b.

  A bolt insertion hole 72 for fixing the plate 71 is provided below the center of the upper and lower sides of the plate 71. On the front surface of the plate 71, a mounting plate 73 for fixing the plate 71 to a mounting plate 75 described later is fixed. The mounting plate 73 is provided with a mounting hole 74 extending coaxially with the bolt insertion hole 72. The number and position of the bolt insertion holes 72 are not limited as long as the plate 71 can be fixed.

  The plate 71 is detachably disposed on the mounting plate 75. As described above, the plate 71 is detachably disposed on the mounting plate 75, so that the bonnet hinge 80 fixed to the mounting plate 75 can be easily removed. For this reason, the bonnet 4 can be easily removed and the maintainability is improved. Further, noise from the engine 29 can be reduced. Further, since the plate 71 is fixed to the mounting plate 75 constituting the unit body 30, it is not necessary to form another member for arranging the plate 71 on the rear portion 59b, thereby reducing the molding cost. Can be made.

  The plate 71 may be provided with an air outlet 42 for discharging the cooling air from the radiator 34 to the outside of the hood 4 (as shown by a dotted line in FIG. 11). By providing the rear portion 59b as an exhaust means for the radiator 34 at the rear portion 59b, the exhaust portion 42 is provided at the rear portion 59b. It can be discharged to the outside. Even if the position of the radiator 34 is lowered, the exhaust air from the radiator 34 is not hindered. The exhaust port 42 is configured to have a sufficient area for passing the exhaust air.

On the other hand, since the rear portion 59b functions as a counterweight, it is formed with a large molding thickness. For this reason, it is difficult to mold the exhaust vent 42 and the like that penetrate the front and rear directions of the rear portion 59b, and the cost is high. Therefore, like the swivel body 2 according to the present configuration example, a recess 70 is formed in front of the radiator 34 in advance, and a plate 71 formed separately is disposed in the recess 70, so that the rear surface of the rear portion 59b is In this case, the rear portion 59b can secure a volume as a counterweight, and can also secure an exhaust area by the radiator 34.

  As shown in FIGS. 13 and 14, the plate 71 is detachably disposed on the mounting plate 75 described above. The mounting plate 75 is formed so that the radiator 34 can be disposed above a long plate-like installation portion 75 a that is substantially horizontal to the flat plate portion 51. A mounting portion 75b formed upward in the vertical direction of the installation portion 75a is disposed at a substantially right and left center of the installation portion 75a. A mounting plate 73 disposed on the plate 71 and a bonnet hinge 80 described later are fixed to the mounting portion 75b by bolts. As described above, the mounting plate 75 not only mounts the radiator 34 but also functions as a support member that fixes the plate 71 and the bonnet hinge 80 and is disposed behind the revolving frame 50. Is also provided.

  At both left and right end portions of the mounting plate 75, continuous portions 75c and 75c are formed so as to project forward from the front surface of the end portion so as to be substantially L-shaped in a side view. The upper ends of the rear portions of the support frames 77 and 77 capable of supporting and fixing the engine 29 from both the left and right sides are fixed to the connecting portions 75c and 75c via rubber mounts or vibration isolator laminated rubber. The support frame 77 is formed so as to be gently inclined forward from the upper end portion 77a. The lower end portion 77b of one side end portion is provided with the flat plate portion via a rubber mount or a vibration isolator laminated rubber. A fixing plate 78 for fixing the support frame 77 is fixed to 51. The left and right end portions of the fixing plate 78 and the mounting plate 75 are fastened to the boss portion 51b inside the revolving frame 50 in a detachable manner.

  As described above, the unit body 30 is configured by the mounting plate 75 and the support frame 77 so that the engine 29, the radiator 34, and the like are integrated. Since the unit body 30 can be easily detached from the turning frame 50, maintenance of the engine 29 and the like can be easily performed. Moreover, the fixing position in the up-down direction of the radiator 34 disposed at the rear part of the revolving unit 2 can be lowered, and the up-down direction of the revolving unit 2 can be made compact. By such compactification, the height of the step 23 and the driver's seat 5 can be lowered from the ground surface, and the operability of the excavation work vehicle by the operator can be improved.

Next, the attachment structure and locking structure of the bonnet 4 will be described below. The attachment structure of the rotating member of the bonnet 4 in the revolving structure 2 according to this configuration example is shown in FIGS. The bonnet 4 is disposed on the revolving frame 50 via a bonnet hinge 80 combined with a flat plate member so as to be able to rotate back and forth. One end of the bonnet hinge 80 is detachably fastened to the mounting portion 75b of the mounting plate 75, which is disposed above the rear portion of the swivel frame 50 and substantially at the center of the left and right. On the other hand, on the bonnet 4 side, one end of the bonnet hinge is fixed to the rear lower end of the bonnet 4.

  That is, the bonnet 4 is rotated in the front-rear direction, with the bonnet hinge 80 disposed at the approximate center of the rear left and right of the revolving structure 2 as a rotation fulcrum. In this way, the rotation angle of the bonnet 4 can be increased by adopting a configuration in which the rotation fulcrum is arranged at the center of the rear left and right. Therefore, internal components such as the unit body 30 arranged so as to protrude upward behind the swivel frame 50 can be maintained without being obstructed by the bonnet 4.

  The bonnet hinge 80 is fastened to the mounting portion 75b. Since the mounting portion 75b is installed in the revolving frame 50, the rotation performance of the bonnet hinge 80 due to dust, external collision, or the like. Decline can be prevented. Further, the attachment position for disposing the bonnet hinge 80 is preferably substantially planar, and is directly attached to the left and right substantially central portion 50d of the rear end portion of the revolving frame 50 formed in a curved shape at the rear. I can't. Therefore, by arranging the substantially flat mounting portion 75c above the rear portion of the swivel frame 50, a rotation fulcrum using the bonnet hinge 80 can be provided.

Further, since the plate 71 is detachably disposed on the attachment portion 75b, the other end of the bonnet hinge 80 is detached from the attachment portion 75b after the plate 71 is removed. Thus, the bonnet 4 can be easily detached from the turning frame 50 as a separate body. In this case, since the bonnet hinge 80 is fixed to the lower end portion of the bonnet 4, it is possible to prevent the hinge member from being lost. Further, as shown in this configuration example, by using a simple hinge member such as the bonnet hinge 80, it is possible to reduce the manufacturing cost by reducing the number of parts.

In the revolving structure 2 according to this configuration example, the rearward rotation position of the bonnet 4 is controlled by a slide-type locking stopper (not shown) disposed on the side of the radiator 34. The locking stopper prevents the bonnet hinge 80 from being damaged by the load of the bonnet 4 itself when the bonnet 4 is rotated rearward.

  On the other hand, as shown in FIGS. 16 to 20, a lock pin 83 serving as a locking means for the bonnet 4 is provided in front of the revolving frame 50 as follows. First, a step plate 81 is fixed to the support plate 22 so as to be behind the front column 19 and at the substantially right and left center of the revolving frame 50. Therefore, the outer edge of the step plate 81 is shaped along the support plate 22, the front column 19, and the like. Further, since the turning motor 36, the hydraulic pump 39, and the like are disposed in front of the turning frame 50, the left and right substantially central portion 81a is provided on the step plate 81, and the turning motor, the hydraulic pump 39, etc. are provided. Covering from above, the operator's operating space is secured. When performing the maintenance of the turning motor 36, it is only necessary to remove the step plate 81, so that the maintenance work can be easily performed.

  The step plate 81 is formed in an elongated shape in plan view so that the left and right substantially central part 81a is convex upward, and is supported so as to be concave forward at the left and right ends of the rear part of the step plate 81. Mounting grooves 81b and 81b for the stand 82 are formed. A lower end of a support stand 82 is fixed to the mounting grooves 81b and 81b, and the support stand 82 is formed with a pipe or a steel rod in a substantially U-shape when viewed from the front, and an opening is disposed downward. Since the step plate 81 is disposed on the support plate 22, the outer edge of the step plate 81 is shaped to follow the support plate 22, the front column 19, and the like.

  The support stand 82 is composed of an upper horizontal portion 82a and stand portions 82b and 82b formed so as to spread from the left and right end portions of the horizontal portion 82a in the front and lower direction. Lower ends of the stand portions 82b and 82b are fixed to the mounting grooves 81b and 81b of the step plate 81, respectively. A lock pin 83 is provided projecting forward from the horizontal center of the horizontal portion 82a. The lock pin 83 may be formed integrally with the support stand 82 or may be attached as a separate body.

  The lock pin 83 can be locked to a lock mechanism 84 provided below the front portion of the bonnet 4. As shown in FIGS. 20A and 20B, the lock mechanism 84 is operated by a lever 85 disposed near the center of the front surface of the bonnet 4. The lever 85 has a pivot shaft of the bonnet 4 penetrating from the front surface to the rear surface, and is inserted into a cylindrical body 86 fixed to the inner surface of the bonnet 4. A hook 87 is fixed to the end of the pivot of the lever 85 so as not to rotate relative to the lever 85. A stopper plate 88 for restricting the amount of rotation of the hook 87 is fixed to the cylindrical body 86. A helical spring 89 is inserted into the cylindrical body 86, the helical spring 89 is locked to the hook 87, and the hook 87 is biased by the helical spring 89 so as to rotate toward the stopper plate 88. It has been done.

  The hook 87 is formed in a flat plate shape, and the lock pin 83 is configured to be engaged with a tip end portion 87 a formed in a substantially U shape in front view of the hook 87. The stopper plate 88 is formed in a substantially Z shape in a side view, and a horizontal portion 88a formed to project downward from the front / rear horizontal portion 88b (downward in FIG. 20B) is in contact with the lock pin 83. It is made possible. Further, a substantially central portion of the front and rear horizontal portion 88 b of the stopper plate 88 is formed so as to be able to contact the central portion 87 b of the hook 87.

  Then, when the lever 85 is rotated in a direction for releasing the lock mechanism 84 (counterclockwise in FIG. 20B), the hook 87 is also rotated in the same direction. That is, the lock pin 83 can be locked and released only by operating the lever 85 in the lock mechanism 84. The rear end portion 87c of the hook 87 is brought into contact with the upper flat surface of the front / rear horizontal portion 88b of the stopper plate 88 so that the amount of rotation of the hook 87 toward the open side is restricted.

  As described above, since the lock pin 83 and the lock mechanism 84 are provided at the front center of the bonnet 4, the vertical height of the revolving body is reduced by downsizing the revolving body 2. Even if the operation space in front of the hood 4 of the revolving structure 2 is narrow, the operator can easily operate the lever 85. Therefore, the bonnet 4 can be easily opened and closed, and the labor required for maintenance work or the like can be reduced.

In this configuration example, the bonnet 4 is opened and closed by a lever 85, the bonnet hinge 81 is detached from the mounting plate 75 to remove the bonnet 4, or the step plate 81 is detached from the support plate 22. Alternatively, maintenance of the inside of the swivel body 2 can be performed by handling the swivel body 2 according to the purpose.

The side view of the excavation work vehicle which concerns on this invention. Similarly front view. Similarly rear view. FIG. The top view which shows the internal structure of a turning body. The top view of the excavation work vehicle which shows turning. The perspective view of a turning frame. The lower perspective view of a turning frame. The perspective view of the attachment part vicinity of a swing cylinder. Similarly XX arrow sectional drawing of an attachment part. Rear view of the plate. FIG. The perspective view showing the attachment state of the member to a mounting plate. The perspective view of a rotating body rear part. The perspective view of the turning body of a bonnet back rotation state. The perspective view of the turning body in the same state of turning forward. The perspective view of the attachment member of a lock pin. Similarly rear view. FIG. The perspective view and front view of a locking mechanism.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Boom bracket 21 Swing cylinder 50 Turning frame 51 Flat plate part 61 Mounting part 61a Lower upper surface 61b Upper upper surface 62 Fixed plate 64 Support hole 67 Support shaft

Claims (1)

A boom bracket (10) is attached to the swing frame (50) so as to be turnable in the left-right direction, and a swing cylinder (21) is interposed between the boom bracket (10) and the swing frame (50). In the excavation work vehicle in which the excavation work machine (6) attached to the vehicle is pivotable in the left-right direction, the swing cylinder is provided on the lower side inside the outer peripheral frame (59) on the side of the flat plate part (51) of the turning frame (50). An attachment portion (61) for pivotally supporting the base side of (21) is formed, the attachment portion (61) is formed in a substantially L shape in cross section, and the attachment portion (61) has a lower upper surface. (61a) and an upper upper surface (61b) are provided, a mounting hole (66) is formed in the vertical direction in the center of the lower upper surface (61a), and a plurality of screw holes are formed in the upper upper surface (61b). Lower upper surface (61a) and upper upper side The difference in the height of (61b) is made to substantially coincide with the height of the base side of the swing cylinder (21), and the size of the mounting hole (66) is set vertically on the base side of the swing cylinder (21). The support hole (64) is approximately the same size as the opening, and the support shaft (67) is inserted into and supported by the support hole (64) and the attachment hole (66). The upper portion of the support shaft (67) is a fixed plate. (62) is fixed to one end, a hole is opened on the other side of the fixing plate (62), and a bolt (63) is inserted and screwed in alignment with the screw hole opened on the upper upper surface (61b). Excavation work vehicle characterized by being fixed .

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