JP2021080709A - Revolving work machine - Google Patents

Abstract

To control the cooling of cooling water and hydraulic fluid separately.SOLUTION: A revolving work machine comprises a revolving base, a work device that is provided on the revolving base, a radiator fan that cools a radiator, and an oil cooler fan that cools an oil cooler apart from the radiator fan.SELECTED DRAWING: Figure 11

Description

The present invention relates to a swivel work machine such as a backhoe.

The swivel work machine disclosed in Patent Document 1 cools the cooling water by the swivel table, the work device provided on the swivel table, the prime mover, the fan provided on the prime mover, and the cooling air generated by the fan. It includes a radiator unit and an oil cooler unit that cools the hydraulic oil with cooling air.

JP-A-2019-70311

However, in the technique of Patent Document 1, since the cooling water and the hydraulic oil are cooled by the same fan, it is not possible to control the cooling of the cooling water and the cooling of the hydraulic oil individually, and both are efficiently performed. In some cases, it could not be cooled. Further, even when the hydraulic oil does not need to be cooled, the fan is driven to cool the hydraulic oil, which may hinder the warming of the hydraulic oil.
The present invention has been made to solve such problems of the prior art, and an object of the present invention is to provide a swivel work machine capable of individually controlling the cooling of cooling water and hydraulic oil.

The swivel work machine according to one aspect of the present invention includes a swivel, a work device provided on the swivel, a radiator fan for cooling the radiator, an oil cooler fan for cooling the oil cooler separately from the radiator fan, and an oil cooler fan for cooling the oil cooler. It has.

According to the swivel work machine, the cooling of the cooling water and the hydraulic oil can be controlled individually.

It is a figure which shows the hydraulic system circuit of a swivel work machine. It is a right front perspective view which shows a swivel table. It is a right rear perspective view which shows a swivel table. It is a top view which shows the lower traveling body, a swivel, and various devices arranged on a swivel. It is a left side view which shows the swivel and various devices arranged on the swivel. It is a rear view which shows the lower traveling body, a swivel, and various devices arranged on a swivel. It is a left front perspective view which shows a swivel base and an exterior cover. It is a right rear perspective view which shows a swivel base and an exterior cover. It is a right front perspective view which shows a swivel base and a protection mechanism. It is a right front perspective view which shows a swivel board, a battery unit, an electric component, an electric motor, and a hydraulic pump. It is a figure explaining the system of a turning work machine. It is a top view which shows the battery unit, the electrical component, and a radiator. It is a right rear perspective view which shows the installation of a battery unit and an electrical component. It is a top view which shows the support stay and a plurality of mounting devices. It is a left rear perspective view which shows the installation of an electric motor and a hydraulic pump. It is a left side sectional view which shows the battery unit which shows the arrangement space, the electrical component, and the support stay. It is a right rear perspective view which shows a radiator, an oil cooler, a shroud, a support frame, and a swivel board. It is a right rear perspective view which shows a radiator, an oil cooler, and a shroud. It is a top view which shows the positional relationship of a radiator, an oil cooler, and a shroud. It is a figure which shows the installation of a radiator, an oil cooler, and a shroud. It is a figure which shows the installation of a radiator and an oil cooler. FIG. 1 is a diagram showing a screen displayed on a display device. FIG. 2 is a diagram showing a screen displayed on a display device. FIG. 3 is a diagram showing a screen displayed on a display device. FIG. 4 is a diagram showing a screen displayed on a display device. FIG. 5 is a diagram showing a screen displayed on a display device. It is a figure explaining a series flow of setting of an output battery of a control device. It is a schematic side view which shows the turning work machine. It is a schematic plan view which shows a turning work machine. It is a schematic rear view which shows the turning work machine.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
First, the overall configuration of the working machine 1 will be described. As shown in FIG. 23, the working machine 1 is, for example, a turning work machine such as a backhoe including a turning table (body) 2, a lower traveling body 10, and a working device 20. Further, the turning work machine 1 is an electric work machine driven by electric power. A driver's seat 8 on which an operator sits is provided on the swivel table 2, and the periphery of the driver's seat 8 is covered with a protection mechanism 80.

In the present embodiment, the front side (arrow A1 direction of FIGS. 23 and 24) of the worker seated in the driver's seat 8 of the turning work machine 1 is forward, and the rear side of the worker (arrows of FIGS. 23 and 24). The left side of the worker (front side of FIG. 23, the direction of the arrow B1 of FIGS. 24 and 25) is the left side, the right side of the worker (the back side of FIG. 23, the arrow B2 of FIGS. 24 and 25). Direction) will be described as the right side. Further, the horizontal direction, which is a direction orthogonal to the front-rear direction, will be described as a width direction (see FIGS. 24 and 25). The direction from the central portion in the width direction of the swivel table 2 toward the right portion or the left portion will be described as the outer side in the width direction. An operable operating device 5 is provided around the driver's seat 8, and the turning work machine 1 is operated by operating the operating device 5.

The swivel base 2 can rotate around a swivel axis (vertical axis) X extending in the vertical direction. Specifically, the swivel base 2 is rotatably supported on the lower traveling body 10 via a swivel bearing 3 around the swivel axis X (swivelable to the left and right). The center of the swivel bearing 3 is the swivel axis X (swivel center), and the swivel motor (swivel device) MT described later is attached to the swivel base 2. The swivel motor MT is a hydraulic device M driven by the hydraulic oil discharged from the hydraulic pump P, and is a motor that rotationally drives the swivel base 2 around the swivel axis X. The swivel motor MT is provided below the protection mechanism 80 and below the front portion of the driver's seat 8, and is attached to the swivel board 60 described later. The swivel base 2 is provided with an exterior cover (cover) 70, a bracket, a stay, and the like. The exterior cover 70 forms a space (rear room) R in which equipment, tanks, other parts, and the like are arranged at the rear of the swivel table 2. Brackets, stays, etc. are members for attaching the above-mentioned parts, etc.

As shown in FIGS. 23 and 24, the lower traveling body 10 has a traveling frame 11 and a traveling mechanism 12. The traveling frame (truck frame) 11 is a structure to which the traveling mechanism 12 is attached and supports the swivel base 2 on the upper portion.
The traveling mechanism 12 is, for example, a crawler type. As shown in FIG. 25, the traveling mechanism 12 is provided on one side (left side) traveling portion 11a and the other side (right side) traveling portion 11b of the traveling frame 11 in the width direction, respectively. The traveling mechanism 12 is a traveling system hydraulic device M (traveling motor ML) driven by an idler 13, a driving wheel 14, a plurality of rolling wheels 15, an endless crawler belt 16, and hydraulic oil discharged from a hydraulic pump P. , MR) and. The idler 13 is arranged at the front of the traveling frame 11, and the drive wheels 14 are arranged at the rear of the traveling frame 11. The plurality of rolling wheels 15 are provided between the idler 13 and the driving wheels 14. The crawler belt 16 is wound around the idler 13, the drive wheels 14, and the rolling wheels 15. The traveling motors ML and MR17 are composed of a hydraulic motor, and drive the drive wheels 14 to circulate and circulate the crawler belt 16 in the circumferential direction. A dozer device 18 is attached to the front portion of the lower traveling body 10. The dozer device 18 is pivotally supported at the front portion of the traveling frame 11 and is swingable by a support arm. The support arm is driven up and down by expanding and contracting the dozer cylinder C5, which is a hydraulic cylinder (hydraulic actuator).

As shown in FIGS. 23 and 24, the working device 20 is provided on the front side of the swivel table 2 and is driven by hydraulic oil. Further, the working device 20 is arranged on the other side (right side) of the center line L in the width direction of the swivel table 2. The working device 20 is operated by the operating device 5. As shown in FIG. 23, the working device 20 has a boom 21, an arm 22, and a bucket (working tool) 23. The base end side of the boom 21 is pivotally attached to the swing bracket 24 around a horizontal axis (an axis extending in the width direction of the machine body) so that the boom 21 can swing in the vertical direction (vertical direction). Has been done. The arm 22 is pivotally attached to the tip end side of the boom 21 so as to be rotatable around a horizontal axis, so that the arm 22 can swing in the front-rear direction or the up-down direction. The bucket 23 is provided on the tip end side of the arm 22 so that it can perform a squeeze operation and a dump operation. The swivel work machine 1 can be equipped with another work tool (hydraulic attachment) that can be driven by hydraulic oil in place of or in addition to the bucket 23. Examples of other working tools include a hydraulic breaker, a hydraulic crusher, an angle bloom, an earth auger, a pallet fork, a sweeper, a mower, and a snow blower.

As shown in FIG. 23, the swivel work machine 1 includes a work system hydraulic device M that operates by the hydraulic oil discharged from the hydraulic pump P, and the work device 20 is driven by the work system hydraulic device M. Operate. In the present embodiment, the hydraulic device M includes a swing cylinder C1, a boom cylinder C2, an arm cylinder C3, and a bucket cylinder C4. The swing cylinder C1, the boom cylinder C2, the arm cylinder C3, and the bucket cylinder C4 are composed of a hydraulic cylinder (hydraulic actuator). As shown in FIG. 23, the swing bracket 24 can swing by expanding and contracting the swing cylinder C1 provided on the right side of the swivel base 2. The boom 21 can swing by expanding and contracting the boom cylinder C2. The arm 22 can be swung by expanding and contracting the arm cylinder C3. The bucket 23 can be squeezed and dumped by expanding and contracting the bucket cylinder C4.

Hereinafter, the hydraulic circuit of the swivel work machine 1 will be described. As shown in FIG. 1, the hydraulic circuit of the swivel work machine 1 includes a hydraulic device M, a hydraulic pump P, a hydraulic oil tank T, a control valve V, an oil passage 40, and an oil cooler 30. ing. The hydraulic pump P is mounted on the swivel base 2 and driven by a drive source that outputs power. The hydraulic pump P includes a first hydraulic pump P1, a second hydraulic pump P2, a third hydraulic pump P3, and a fourth hydraulic pump P4.

The first hydraulic pump P1, the second hydraulic pump P2, and the third hydraulic pump P3 are hydraulic oils for the working system hydraulic device M for driving the work device 20 and the traveling system hydraulic device M for driving the lower traveling body 10. It is a pump that discharges. Specifically, the first hydraulic pump P1 supplies hydraulic oil for driving the swing cylinder C1, the boom cylinder C2, and the traveling motor ML. The second hydraulic pump P2 supplies hydraulic oil for driving the arm cylinder C3, the dozer cylinder C5, and the traveling motor MR. The third hydraulic pump P3 supplies hydraulic oil for driving the bucket cylinder C4 and the swivel motor MT. The first hydraulic pump P1, the second hydraulic pump P2, and the third hydraulic pump P3 are variable displacement hydraulic pumps provided with a pump capacity control mechanism such as a swash plate.

The fourth hydraulic pump P4 is a pump that supplies hydraulic oil for signals or control, that is, pilot oil. The hydraulic pump P only needs to be able to discharge the hydraulic oil for operating the hydraulic device M and the pilot oil for controlling the hydraulic device M, and its configuration is not limited to the above configuration.
The hydraulic oil tank T is a tank for storing hydraulic oil.

As shown in FIG. 1, the control valves V have control valves V1 to V8, and the control valves V1 to V8 adjust the hydraulic oil output from the hydraulic pump P to the hydraulic device M. The control valve V is a swing control valve V1 that controls the swing cylinder C1, a boom control valve V2 that controls the boom cylinder C2, an arm control valve V3 that controls the arm cylinder C3, and a bucket control valve that controls the bucket cylinder C4. V4, a dozer control valve V5 that controls the dozer cylinder C5, a left travel control valve V6 that controls the travel motor ML of the left travel mechanism 12, and a right travel control that controls the travel motor MR of the right travel mechanism 12. It has a valve V7 and a swivel control valve V8 that controls the swivel motor MT.

The spools of the control valves V1 to V8 are moved by the action of pilot oil in proportion to the amount of operation of the remote control valves (operation valves) PV1 to PV6 by the operation of the operation lever (operation member) 5a of the operation device 5. .. In other words, the operating device 5 can operate the hydraulic device M by adjusting the hydraulic oil (pilot oil) acting on the control valves V1 to V8 to control the control valves V1 to V8. The control valves V1 to V8 run the hydraulic equipment M (swing cylinder C1, boom cylinder C2, arm cylinder C3, bucket cylinder C4, dozer cylinder C5, running) whose control target is hydraulic oil in an amount proportional to the amount of movement of the spool. It is supplied to the motors ML, MR, and swivel motor MT).

The oil cooler 30 is a device that cools the hydraulic oil flowing through the oil passage 40. The oil cooler 30 is cooled by a rotationally driven oil cooler fan 30a. The oil cooler fan 30a sucks in the air around the oil cooler 30 and discharges the sucked air from the inside of the rear room R formed by the exterior cover 70 to the outside.
As shown in FIG. 1, the oil passage 40 connects a hydraulic device M, a hydraulic pump P, control valves V1 to V8 (control valves V), and the like, and allows hydraulic oil and pilot oil to flow. The oil passage 40 includes a first pipeline 41, a second pipeline 42, a third pipeline 44, and a second discharge oil passage 45.

As shown in FIG. 1, the first pipeline (first discharge oil passage) 41 uses the hydraulic oil discharged by the hydraulic pumps P (first hydraulic pump P1, second hydraulic pump P2, and third hydraulic pump P3). Flow toward the hydraulic device M. Specifically, the first pipeline 41 includes a first supply oil passage 41a connected to the first hydraulic pump P1 and a plurality of second supply oil passages 41b branching from the first supply oil passage 41a. And, including. The plurality of second supply oil passages 41b are connected to the control valves V1 to V8, respectively. That is, the hydraulic oil flowing through the first pipeline 41 is supplied to the flood control device M through the first supply oil passage 41a, the second supply oil passage 41b, and the control valves V1 to V8. In the present embodiment, the first pipeline 41 includes the first supply oil passage 41a and the plurality of second supply oil passages 41b, but the first pipeline 41 includes at least the hydraulic pump P. It may be any oil passage for flowing the discharged hydraulic oil toward the hydraulic equipment M, and may include an oil passage connecting the control valves V1 to V8 and the hydraulic equipment M, and is not limited to the above configuration.

As shown in FIG. 1, the second pipeline 42 flows the hydraulic oil discharged from the hydraulic device M. Specifically, the second pipeline 42 is connected to the control valves V1 to V8 on one end side, merges in the middle portion, and is connected to the oil cooler 30 on the other end side. Therefore, the hydraulic oil discharged from the hydraulic device M returns to the second pipeline 42 through the control valves V1 to V8 and flows to the oil cooler 30. In the present embodiment, the second pipeline 42 is connected to the control valves V1 to V8, but at least it may be an oil passage through which the hydraulic oil discharged from the hydraulic device M flows, and the control valves V1 to V8. And the hydraulic device M may be connected to include an oil passage through which the hydraulic oil discharged from the hydraulic device M flows, and the present invention is not limited to the above configuration.

As shown in FIG. 1, the third pipeline 44 connects the oil cooler 30 and the hydraulic pump P (the first hydraulic pump P1, the second hydraulic pump P2, and the third hydraulic pump P3) from the oil cooler 30. Hydraulic oil is flowed through the first hydraulic pump P1, the second hydraulic pump P2, and the third hydraulic pump P3. Specifically, the third pipeline 44 has a discharge oil passage 44a for flowing the hydraulic oil cooled by the oil cooler 30 to the hydraulic oil tank T, and the hydraulic oil in the hydraulic oil tank T for the first hydraulic pumps P1 and the second. The hydraulic pump P2 and the suction oil passage 44b sucked by the third hydraulic pump P3 are included. Therefore, the hydraulic oil cooled by the oil cooler 30 is returned to the hydraulic oil tank T through the discharge oil passage 44a, and the hydraulic oil stored in the hydraulic oil tank T passes through the suction oil passage 44b. It is supplied to 1 hydraulic pump P1, 2nd hydraulic pump P2, and 3rd hydraulic pump P3.

As shown in FIG. 1, the second discharge oil passage 45 connects the hydraulic pump P (fourth hydraulic pump P4) and the remote control valves PV1 to PV6, and the hydraulic oil discharged by the fourth hydraulic pump P4 is used as the remote control valve. It flows through PV1 to PV6. The second discharge oil passage 45 is branched into a plurality of parts in the middle portion, and each is connected to a port (primary port) on the primary side of the remote control valves PV1 to PV6.
As shown in FIG. 1, the swivel work machine 1 includes a drive limiting device 47 that prohibits or limits the driving of the working device 20. The drive limiting device 47 prohibits or limits the driving of the hydraulic device M by shutting off the supply of hydraulic oil from the hydraulic pump P to the hydraulic device M. For example, the drive limiting device 47 allows the supply of hydraulic oil to the remote control valves PV1 to PV6 to allow the control valves V1 to V8 to be operated, that is, the hydraulic device M to be operated, and the remote control valves PV1 to PV6. It is possible to switch between the operation of the control valves V1 to V8, that is, the state of prohibiting or restricting the operation of the hydraulic device M by stopping the supply of the hydraulic oil to the device. As a result, the drive limiting device 47 prohibits or limits the driving of the hydraulic device M, that is, prohibits or limits the driving of the working device 20.

In the present embodiment, the drive limiting device 47 includes an unload valve 48 provided in the second discharge oil passage 45 and an unload lever (unload operating tool) 5b for operating the unload valve 48. .. The unload valve 48 is a two-position switching valve that can switch between the supply position 48a and the shutoff position 48b. When the unload valve 48 is at the supply position 48a, the unload valve 48 supplies the hydraulic oil flowing through the second discharge oil passage 45 to the remote control valves PV1 to PV6. When the unload valve 48 is at the shutoff position 48b, the supply of the hydraulic oil to the remote control valves PV1 to PV6 is cut off, that is, the supply of the hydraulic oil in the second discharge oil passage 45 to the remote control valves PV1 to PV6 is stopped. To do.

The unload valve 48 is urged in a direction of being switched to the cutoff position (unload position) 48b by a spring, and is set to the cutoff position 48b by degaussing the solenoid, and is set to the supply position 48a by exciting the solenoid. Can be switched. Specifically, the unload valve 48 is excited at a position where the unload operation tool 5b is lowered, and is degaussed by pulling up the unload operation tool 5b.

Therefore, when the unloading operation tool 5b is lowered, the unloading valve 48 is switched to the supply position 48a, and the hydraulic oil (discharged oil) discharged from the fourth hydraulic pump P4 is the remote control valve PV1 to the remote control valve PV1 via the unloading valve 48. It is supplied to the primary port of PV6.
When the unloading operation tool 5b is pulled up, the unloading valve 48 is switched to the shutoff position 48b, hydraulic oil (pilot oil) is not supplied to the remote control valves PV1 to PV6, and the hydraulic device M cannot be operated.

In the present embodiment, the drive limiting device 47 is an unload valve 48 that prohibits or limits the driving of the hydraulic device M by shutting off the supply of hydraulic oil from the hydraulic pump P to the hydraulic device M. Driving the hydraulic device M by attaching an operable locking piece (not shown) to the operating device 5 (operating lever 5a) for operating the device M (working device 20) and restraining the operation of the operating lever 5a. May be configured to prohibit or limit. In such a case, the drive limiting device 47 is a lever lock that restrains the operation of the operating lever 5a.

Hereinafter, the swivel table 2 will be described. As shown in FIGS. 2 and 3, the swivel base 2 includes a swivel substrate (board) 60, a plurality of vertical ribs (first vertical rib 61 and second vertical rib 62), a support bracket 63, and a partition plate 64. And a support frame 65. The swivel substrate 60 is formed of a thick steel plate or the like, and is arranged so that the plate surface faces in the vertical direction. The swivel substrate 60 is rotatably supported on the lower traveling body 10 via the swivel bearing 3 around the swivel axis X.

As shown in FIGS. 2 and 3, the first vertical rib 61 and the second vertical rib 62 are members for reinforcing the swivel substrate 60, and are provided so as to extend from the front portion to the rear portion of the swivel substrate 60. There is. The first vertical rib 61 and the second vertical rib 62 are erected on the swivel substrate 60 and are arranged side by side so as to be separated from each other in the width direction. The first vertical rib 61 is arranged on the left side of the swivel substrate 60, and the second vertical rib 62 is arranged on the right side of the swivel board 60.

As shown in FIGS. 2 and 3, the support bracket 63 is provided on the front portion of the first vertical rib 61 and the second vertical rib 62. As shown in FIG. 4, the support bracket 63 and the front portions of the first vertical rib 61 and the second vertical rib 62 are provided at positions deviated from the center in the width direction of the swivel substrate 60 to the right. As shown in FIG. 23, the swing bracket 24 is swingably attached to the support bracket 63 around the vertical axis (the axis extending in the vertical direction). The base end side of the work device 20 (boom 21) is rotatably attached to the swing bracket 24 around the horizontal axis.

As shown in FIG. 2, the partition plate 64 is a member that partitions the lower part of the front surface of the rear room R. The partition plate 64 has a plate surface facing in the front-rear direction, and is arranged at the rear portion of the swivel substrate 60 from one side (left side) to the other side (right side) in the width direction.
As shown in FIGS. 2, 3 and 4, the support frame 65 is the rear portion of the swivel substrate 60 and is erected behind the partition plate 64. The rear portion of the support frame 65 is located behind the rear portion of the lower traveling body 10. Specifically, the support frame 65 is arranged in the rear room R and supports the exterior cover 70 and peripheral parts arranged inside the exterior cover 70. The support frame 65 is fixed to a plurality of leg members (first leg 65a, second leg 65b, third leg 65c, and fourth leg 65d) erected on the swivel board 60, and above the plurality of leg members. It has a rod member 65e and a rod member 65e.

As shown in FIGS. 2 and 3, the first leg 65a has a first support column portion 65a1 and a first extension portion 65a2. The first support column portion 65a1 is erected on the left side of the front portion of the rear room R and extends in the vertical direction. Specifically, the lower end of the first support column portion 65a1 is attached to the left side of the rear surface of the partition plate 64. The first extending portion 65a2 extends rearward and upward from the upper end of the first strut portion 65a1, bends in the middle portion, and extends rearward.

As shown in FIGS. 2 and 3, the second leg 65b has a second strut portion 65b1 and a second extension portion 65b2. The second strut portion 65b1 is erected on the right side of the front portion of the rear room R and extends in the vertical direction. Specifically, the lower end of the second support column portion 65b1 is attached to the right side of the partition plate 64. That is, the lower end of the second strut portion 65b1 is located in front of the first strut portion 65a1. The second extending portion 65b2 extends rearward and upward from the upper end of the second strut portion 65b1, bends in the middle portion, and extends rearward.

As shown in FIGS. 2 and 3, the third leg 65c has a third strut portion 65c1 and a third extension portion 65c2. The third strut portion 65c1 is erected on the rear left side of the rear room R and extends in the vertical direction. The rear portion of the third strut portion 65c1 is located behind the rear portion of the lower traveling body 10. The third extending portion 65c2 extends forward and upward from the upper end of the third strut portion 65c1, bends in the middle portion, and extends forward.

As shown in FIGS. 2 and 3, the fourth leg 65d has a fourth strut portion 65d1 and a fourth extension portion 65d2. The fourth strut portion 65d1 is erected at the rear portion of the rear room R and extends in the vertical direction. The rear portion of the fourth strut portion 65d1 is located behind the rear portion of the lower traveling body 10. The fourth extending portion 65d2 extends forward and upward from the upper end of the fourth strut portion 65d1, bends in the middle portion, and extends forward.

As shown in FIGS. 2 and 3, the rod member 65e is arranged so that the plate surface faces in the vertical direction and extends in the width direction. The rod member 65e is placed over the upper end of the first extension portion 65a2, the upper end of the second extension portion 65b2, the third extension portion 65c2, and the upper end of the fourth extension portion 65d2, and each of these extensions It is fixed to the protrusion. Specifically, as shown in FIG. 6, the rod member 65e extends to the left from the upper end of the first extending portion 65a2, bends downward at the left end portion, and reaches the upper end of the second extending portion 65b2. There is.

As shown in FIGS. 7 and 8, the exterior cover 70 has a bonnet 71. The bonnet 71 includes a bonnet center 72, a rear bonnet 73, a first side bonnet 74, and a second side bonnet 75. The bonnet center 72 is a cover member that forms the upper side and the front side of the rear room R, and blocks the inside (indoor) side and the rear room R side of the protection mechanism 80. The bonnet center 72 is attached to the upper part of the rod member 65e, and the lower part of the bonnet center 72 is attached to the upper part of the partition plate 64. The rear bonnet 73 is a cover member forming the rear of the rear room R, and is attached to the support frame 65. The first side bonnet 74 is a cover member forming the left side of the rear room R. The second side bonnet 75 is a cover member forming the right side of the rear room R. The second side bonnet 75 is formed with an opening that communicates the inside and the outside of the rear room R (bonnet 71).

Hereinafter, the protection mechanism 80 provided on the swivel table 2 and covering the driver's seat 8 will be described. As shown in FIGS. 23 and 24, the protection mechanism 80 is mounted near the front of the swivel base 2 and protects the driver's seat 8. The protection mechanism 80 is arranged on one side (left side) with respect to the center line L in the width direction of the swivel base 2. As shown in FIG. 9, the protection mechanism 80 has a support column 81 and a roof 84 supported by the support column 81. In the present embodiment, the support column 81 includes a first support column 82 arranged on one side (left side) in the width direction of the swivel base 2 and a second support column 83 arranged on the other side (right side) in the width direction. The protection mechanism 80 is a cabin. The structure of the protection mechanism 80 is not limited to the above configuration, and may be a cabin having a two-pillar structure or a three-pillar structure, or a canopy.

As shown in FIG. 9, the first support column 82 is arranged at the front portion on one side (left side) of the swivel table 2 in the width direction and at the rear portion on the left side of the swivel table 2. It includes a first rear strut 82b and a first upper connecting portion 82c that connects the upper end of the first front strut 82a and the upper end of the first rear strut 82b. The first front strut 82a and the first rear strut 82b are provided on the left side of the swivel base 2 at intervals in the front-rear direction, and extend in the vertical direction, respectively. The first upper connecting portion 82c is curved rearward from the upper end of the first front strut 82a, and is curved downward in the middle portion to reach the upper end of the first rear strut 82b.

As shown in FIG. 9, the second support column 83 is arranged at the front portion on the other side (right side) of the swivel table 2 in the width direction and the second front column 83a arranged at the rear portion on the right side of the swivel table 2. It includes a second rear strut 83b and a second upper connecting portion 83c that connects the upper end of the second front strut 83a and the upper end of the second rear strut 83b. The second front strut 83a and the second front strut 83a are provided on the right side of the swivel base 2 at intervals in the front-rear direction and extend in the vertical direction. The second upper connecting portion 83c is curved rearward from the upper end of the second front strut 83a, and is curved downward in the middle portion to reach the upper end of the second rear strut 83b.

As shown in FIG. 9, the roof 84 is a substantially plate-like structure in a plan view arranged above the driver's seat 8, and is supported on the upper portion of the support column 81 so that the plate surface faces in the vertical direction. There is. The roof 84 is provided between the first upper connecting portion 82c and the second upper connecting portion 83c, extends from the front portion to the rear portion of the swivel base 2, and is one side in the width direction of the swivel base 2. It extends from (left side) to the other side (right side).

As shown in FIG. 9, a front lower frame 85 is provided at the lower end of the front portion of the protection mechanism 80. The front lower frame 85 is provided between the lower end of the first front support 82a and the lower end of the second front support 83a. The front lower frame 85 extends in the width direction and is attached to the front upper portion of the swivel base 2 via a plurality of support mounts (not shown).
As shown in FIG. 9, a rear lower frame 86 is provided at the lower end of the rear portion of the protection mechanism 80. The rear lower frame 86 is provided between the lower end portion of the first rear strut 82b and the lower end portion of the second rear strut 83b. The rear lower frame 86 is provided at a position higher than that of the front lower frame 85. The rear lower frame 86 extends in the width direction, is attached to the upper part of the bonnet center 72 via a plurality of support mounts (not shown), and is arranged on the upper part of the rod member 65e.

Hereinafter, the equipment mounted on the rear room R of the swivel base 2 will be described. As shown in FIG. 11, the swivel work machine 1 includes a battery unit 90, an electric motor 91, an electrical component 92, a charging port 93, and a radiator 94, and includes FIGS. 4, 5, and 6. As shown in the above, the battery unit 90, the electric motor 91, the electrical component 92, the charging port 93, and the radiator 94 are provided on the swivel base 2. The battery unit 90 is a structure that can store electricity and outputs the stored electric power.

The electric motor 91 is a drive source driven by the electric power output from the battery unit 90. The electric motor 91 is a permanent magnet embedded type three-phase AC synchronous motor. The electric motor 91 has a rotatable rotor (rotor) and a stator (stator) that generates a force for rotating the rotor. The rotation speed of the electric motor 91 is operated by, for example, the rotation speed operating tool 5c. The rotation speed operating tool 5c can set the range of the motor rotation speed of the electric motor 91 when the motor rotation speed of the electric motor 91 is set according to the current value that changes according to the operation of the operating device 5. The rotation speed control tool 5c is, for example, a dial-shaped switch such as a selector switch having a plurality of switching positions, and a target value of the rotation speed of the electric motor 91 is assigned to the plurality of switching positions. The rotation speed control tool 5c can set and operate the target value range of the rotation speed of the electric motor 91 in the range of 1500 to 2600 rpm / min. The electric motor 91 may be another type of synchronous motor, an AC motor, or a DC motor. Further, the operation of the rotation speed of the electric motor 91 is not limited to the rotation speed operation tool 5c, and may be another member included in the operation device 5. For example, the rotation speed of the electric motor 91 may be operated based on a preset table according to the amount of operation of the operating device 5.

The electric motor 91 rotates the drive shaft by the electric power supplied from the battery unit 90, and transmits the drive force from the drive shaft to the hydraulic pump P. The hydraulic pump P is connected to the drive shaft of the electric motor 91 and is driven by the drive force transmitted from the drive shaft. That is, the hydraulic pump P is driven by the drive of the electric motor 91 to discharge the hydraulic oil.
The electrical component 92 is a device or the like that is directly or indirectly connected to the battery unit 90 and transmits the electric power supplied by the battery unit 90 or operates by the electric power. The electrical component 92 is, for example, a junction box 92a, an inverter 92b, and a DC / DC converter 92c. The junction box 92a is connected to other devices including the battery unit 90 and the inverter 92b, and transmits the electric power supplied from the battery unit 90 to the other devices.

The inverter 92b is provided in the power supply path 132 from the battery unit 90 to the electric motor 91, and adjusts the electric power output to the electric motor 91. In the present embodiment, the inverter 92b is connected to the junction box 92a and the electric motor 91. The inverter 92b is a device for driving the electric motor 91, converts DC power into three-phase AC power, and supplies the three-phase AC power to the electric motor 91. The inverter 92b can arbitrarily change the current and voltage of the electric power supplied to the electric motor 91.

The DC / DC converter 92c converts the voltage of the input DC current into a different voltage. In the present embodiment, the DC / DC converter 92c is a step-down converter that converts an input voltage into a low voltage. The DC / DC converter 92c is provided in, for example, the swivel work machine 1 and supplies electric power to an in-vehicle battery 96 that supplies electric power to electronic devices.
The charging port 93 is a socket to which a cable for supplying electric power from the outside and storing electricity in the battery unit 90 is connected. As shown in FIG. 6, the charging port 93 is attached to the rear portion of the support frame 65. The support frame 65 is attached to a support stay 66 attached over a midway portion in the vertical direction of the third strut portion 65c1 and a midway portion in the vertical direction of the fourth strut portion 65d1. The support stay 66 is arranged so as to extend in the width direction, and supports the charging port 93 at the center in the width direction. As shown in FIG. 8, when the charging port 93 is connected to a cable that supplies electric power from the outside, the charging lid (lid member) 73a attached to the rear bonnet 73 is opened to be exposed from the exterior cover 70. The charging lid 73a is swingably connected to the rear bonnet 73 and the support frame 65 by a hinge or the like, and can be opened and closed around the swing shaft of the hinge. The rear bonnet 73 can be opened and closed at least at a portion corresponding to the charging port 93, and the opening and closing method is not limited to the charging lid 73a described above, and even if the lid member can be opened and closed by sliding, for example. Good.

The radiator 94 is a device that cools the cooling water (refrigerant) that cools the electric motor 91, the battery unit 90, the electrical component 92, and the like. The radiator 94 is cooled (heat removed) by the radiator fan 94a. The radiator fan 94a is rotationally driven to generate cooling air to remove heat from the radiator 94. The radiator fan 94a sucks in the air around the radiator 94 and discharges it from the inside of the rear room R to the outside of the rear room R through the opening of the exterior cover 70. As a result, the cooling air whose temperature has risen due to heat exchange with the radiator 94 is discharged to the outside.

As shown in FIG. 12, the swivel work machine 1 was cooled by the radiator 94 by connecting the radiator 94, the electric motor 91, the battery unit 90, the electrical components 92 (for example, the inverter 92b and the DC / DC converter 92c) and the like. It is provided with a water cooling path 95 through which the refrigerant and the refrigerant whose heat has been exchanged in the electric motor 91, the battery unit 90, and the electrical component 92 flow. The water cooling path 95 is provided with a cooling pump 95a that discharges cooling water and circulates the cooling water as a refrigerant. In the present embodiment, the water cooling path 95 circulates cooling water from the radiator 94 through the inverter 92b, the DC / DC converter 92c, and the electric motor 91 to the radiator 94. Specifically, the water cooling path 95 includes a feed channel 95b, a return channel 95c, a first channel 95d, and a second channel 95e.

As shown in FIG. 12, the feed water channel 95b is a channel for sending the refrigerant from the electrical components 92, the electric motor 91, and the like to the radiator 94. Specifically, the feed channel 95b connects the electric motor 91 and the radiator 94. The refrigerant flows from the electric motor 91 toward the radiator 94. The return water channel 95c is a water channel that returns the refrigerant from the radiator 94 to the electrical components 92, the electric motor 91, and the like. Specifically, the radiator 94 and the inverter 92b are connected to flow the refrigerant from the radiator 94 to the inverter 92b.

The first water channel 95d connects the inverter 92b and the DC / DC converter 92c, and allows the refrigerant flowing from the inverter 92b to the DC / DC converter 92c. The second water channel 95e connects the DC / DC converter 92c and the electric motor 91, and allows the refrigerant flowing from the DC / DC converter 92c to the electric motor 91. That is, the cooling water cooled by the radiator 94 passes from the radiator 94 through the return channel 95c, the inverter 92b, the first channel 95d, the DC / DC converter 92c, the second channel 95e, the electric motor 91, and the feed channel 95b. Return to radiator 94.

As shown in FIGS. 4 and 5, in the rear room R, in addition to the battery unit 90, the electric motor 91, the hydraulic pump P, and the electrical component 92, an oil cooler 30, a hydraulic oil tank T, and a control valve V ( Control valves V1 to V8) are provided. Hereinafter, the arrangement of the battery unit 90, the electric motor 91, the hydraulic pump P, the electrical components 92, the hydraulic oil tank T, and the control valve V will be described. The battery unit 90 is arranged at the rear part of the swivel table 2, and more specifically, the battery unit 90 is arranged from the middle part of the swivel table 2 in the front-rear direction to the rear part of the swivel table 2. That is, the rear portion of the battery unit 90 is located behind the rear portion of the lower traveling body 10. Further, as shown in FIG. 24, the center of gravity of the battery unit 90 is arranged on one side (left side) with respect to the center line L in the width direction of the swivel base 2, and is arranged behind the protection mechanism 80. ..

The connector 90b from which the battery unit 90 outputs electric power is arranged so as to be located at the front portion of the battery unit 90. The connector 90b projects forward at the front of the battery unit 90.
As shown in FIG. 4, the second strut portion 65b1 of the second leg 65b is located in front of the battery unit 90, and the third strut portion 65c1 of the third leg 65c and the third strut portion 65c1 are located behind the battery unit 90. The fourth strut portion 65d1 of the fourth leg 65d is located. A second extension portion 65b2, a third extension portion 65c2, a fourth extension portion 65d2, and a rod member 65e are located above the battery unit 90. Further, the first leg 65a is located on the left side of the battery unit 90, and the outer circumference of the battery unit 90 is surrounded by the support frame 65.

As shown in FIG. 24, the electric motor 91 and the hydraulic pump P are located on the opposite side of the center line L in the width direction of the swivel base 2 and on the side of the battery unit 90 as shown in FIGS. 4 and 5. They are arranged side by side in the direction. Specifically, the electric motor 91 and the hydraulic pump P are arranged below the side (right side) of the battery unit 90. The electric motor 91 is located behind the hydraulic pump P, and is arranged so that the drive shaft faces the front-rear direction. The hydraulic pump P is located in front of the electric motor 91. The rear end of the electric motor 91 substantially coincides with the rear end of the battery unit 90, and the front end of the hydraulic pump P substantially coincides with the front end of the battery unit 90.

As shown in FIGS. 4 and 10, the electrical components 92 are arranged side by side in the width direction above the battery unit 90. In other words, the battery unit 90 is arranged below the electrical component 92, and the swivel base 2, the battery unit 90, and the electrical component 92 are such that the swivel base 2, the battery unit 90, and the electrical component 92 are arranged from the lower side to the upper side. The electrical components 92 are arranged in this order. That is, the relatively heavy battery unit 90 is arranged below the electrical component 92, and the position in the swivel work machine 1 is low.

As shown in FIG. 5, the radiator (cooling mechanism) 94 and the oil cooler (cooling mechanism) 30 are arranged above the hydraulic pump P and the electric motor 91. As a result, the radiator fan 94a and the oil cooler fan 30a suck in the air around the battery unit 90 including the air radiated by the battery unit 90, and the air radiated from the hydraulic pump P and the electric motor 91 and moved upward. , Discharge to the outside of the aircraft.

As shown in FIGS. 4, 5, and 24, the battery unit 90, the electric motor 91, the hydraulic pump P, the radiator 94, and the oil cooler 30 are arranged behind the turning axis X.
As shown in FIGS. 4 and 24, the hydraulic oil tank T and the control valve V are arranged in front of the battery unit 90. The hydraulic oil tank T is arranged on the front side of the swivel base 2 on the opposite side (right side) with respect to the center line L in the width direction, and is arranged on the right side of the second vertical rib 62. Further, the hydraulic oil tank T is arranged in front of the electric motor 91 and the hydraulic pump P. The hydraulic oil tank T and the hydraulic pump P are arranged side by side in the front-rear direction on the right side of the swivel base 2.

As shown in FIGS. 4 and 24, the control valve V is arranged on the front side (left side) on one side (left side) with respect to the center line L in the width direction in the swivel base 2, and is arranged to the left of the first vertical rib 61. Have been placed. Further, the control valve V is arranged below the protection mechanism 80. The hydraulic oil tank T and the control valve V are arranged in front of the turning axis X.
Hereinafter, the installation of the battery unit 90, the electric motor 91, the hydraulic pump P, and the electrical component 92 will be described in detail. As shown in FIG. 10, the swivel work machine 1 includes a support substrate 100, a connecting portion 102, and an erection frame 103. The support substrate 100 is a structure that supports the battery unit 90, the electric motor 91, and the hydraulic pump P at the rear portion of the swivel base 2.

As shown in FIGS. 13 and 14, the support substrate 100 is formed of a thick steel plate or the like, and is arranged on the swivel base 2 so that the plate surface faces in the vertical direction. The support substrate 100 includes a first mounting portion 100a and a second mounting portion 100b. The first mounting portion 100a is a substantially rectangular or substantially rectangular portion in a plan view, and the battery unit 90 is mounted. The first mounting portion 100a is a portion on one side (left side) in the width direction of the support substrate 100, and a mounting bracket 100a1 for mounting and fixing the battery unit 90 is mounted.

As shown in FIG. 14, the mounting bracket 100a1 extends from one end side (left side) to the other end side (right side) of the battery unit 90 in the width direction, and is located at the front and rear portions of the first mounting portion 100a. , Each is extended upward. The mounting bracket 100a1 is mounted and fixed to the lower side of the rear portion of the battery unit 90 by a fastening member such as a bolt. Further, a plurality of first communication holes 100a2 are formed in the central portion of the first mounting portion 100a. The plurality of first communication holes 100a2 are holes penetrating in the vertical direction and are located at equal intervals at positions corresponding to the battery unit 90, so that the heat released from the battery unit 90 can be discharged. The number, shape, and position of the plurality of first communication holes 100a2 are not limited to the above configuration.

As shown in FIG. 15, the second mounting portion 100b is a portion to which the electric motor 91 and the hydraulic pump P are mounted. The second mounting portion 100b is a portion extending laterally from the first mounting portion 100a. Specifically, the second mounting portion 100b is an intermediate portion in the front-rear direction of the first mounting portion 100a and extends to the right from the other side (right side) in the width direction.
As shown in FIG. 14, the support substrate 100 is attached to the swivel base 2 via a plurality of mounting devices 101. The plurality of mounting devices 101 are anti-vibration mechanisms composed of elastic members and the like that can be elastically deformed. The plurality of mounting devices 101 include a front mounting device 101a, a rear mounting device 101b, and an intermediate mounting device 101c. A pair of front mounting devices 101a are arranged in the width direction on the front side of the support substrate 100. The left front mounting device 101a supports the left front end of the support substrate 100 with respect to the swivel base 2. On the other hand, the right front mounting device 101a supports the right front end of the support substrate 100 with respect to the swivel base 2.

As shown in FIG. 14, a pair of rear mounting devices 101b are arranged in the width direction on the rear side of the support substrate 100. The left rear mounting device 101b supports the left rear end of the support substrate 100 with respect to the swivel base 2. On the other hand, the right rear mounting device 101b supports the right rear end of the support substrate 100 with respect to the swivel base 2.
As shown in FIG. 14, the intermediate mounting device 101c is arranged between the rear mounting devices 101b, and supports the central portion of the rear end of the support substrate 100 with respect to the swivel base 2. The intermediate mounting device 101c is located behind the rear mounting device 101b. In other words, the intermediate mounting device 101c is offset rearward with respect to the rear mounting device 101b.

As shown in FIGS. 5, 10 and 15, the connecting portion 102 is a coupling that connects the electric motor 91 and the hydraulic pump P. The connecting portion 102 connects the electric motor 91 and the hydraulic pump P so that the drive shaft of the electric motor 91 is connected to the hydraulic pump P. As shown in FIG. 15, the connecting portion 102 includes a tubular portion 102a and a mounting portion 102b. The tubular portion 102a extends in the front-rear direction, and the drive shaft of the electric motor 91 and the input shaft of the hydraulic pump P are internally connected to each other. The mounting portion 102b is a portion to be mounted on the second mounting portion 100b, and is, for example, a substantially L-shaped portion in a lateral view. The mounting portion 102b is mounted and fixed to the second mounting portion 100b with a fastening member such as a bolt. A tubular portion 102a is provided on the front side of the mounting portion 102b, and an electric motor 91 is mounted and fixed on the opposite side (rear side) of the tubular portion 102a with a fastening member such as a bolt.

As shown in FIGS. 10 and 13, the erection frame 103 is a structure that supports one side surface (left side) and the other side surface (right side) of the battery unit 90 and supports the electrical component 92 above the battery unit 90. is there. The erection frame 103 has a first erection portion 103L, a second erection portion 103R, and a connecting stay 103U. The first standing portion 103L stands on the upper part of the swivel base 2 and supports one side surface of the battery unit 90. Specifically, the first upright portion 103L is fixed to the upper part of the support substrate 100. The first standing portion 103L is fixed to the left side of the first mounting portion 100a of the support substrate 100. As shown in FIG. 12, the front end of the first standing portion 103L is substantially flush with the front surface of the battery unit 90, and the rear end of the first standing portion 103L is substantially flush with the rear surface of the battery unit 90. is there. Therefore, the first upright portion 103L supports the battery unit 90 in the front-rear direction on one side (left side) in the width direction of the battery unit 90.

On the other hand, as shown in FIGS. 10 and 13, the second standing portion 103R stands on the upper part of the swivel base 2 and supports the other side surface (right side) of the battery unit 90. Specifically, the second upright portion 103R is fixed to the upper part of the support substrate 100. The second standing portion 103R is fixed to the right side of the first mounting portion 100a of the support substrate 100. As shown in FIG. 12, the front end of the second standing portion 103R is substantially flush with the front surface of the battery unit 90, and the rear end of the second standing portion 103R is substantially flush with the rear surface of the battery unit 90. is there. Therefore, the second upright portion 103R supports the battery unit 90 in the front-rear direction on the other side (right side) of the battery unit 90 in the width direction. That is, the battery unit 90 is sandwiched by the first standing portion 103L and the second standing portion 103R in the width direction.

As shown in FIG. 13, the first erection portion 103L and the second erection portion 103R each have an anti-sway portion 104 and an extension portion 105, respectively. The steady rest portion 104 is attached to the battery unit 90 in the front-rear direction. The anti-sway portion 104 is provided on the left side and the right side of the first mounting portion 100a, respectively. The anti-sway portion 104 of the second standing portion 103R is erected between the connecting portion 102 and the battery unit 90, and is attached to the other side surface (right surface) of the battery unit 90. Further, the anti-sway portion 104 of the first standing portion 103L is erected on one side surface (left surface) of the battery unit 90 above the first mounting portion 100a (swivel stand 2), and the second standing portion 103R It is attached to one side surface of the battery unit 90 separately from the steady rest portion 104.

In the present embodiment, the anti-sway portion 104 is configured by connecting a plurality of rod-shaped members. For example, as shown in FIG. 13, the anti-sway portion 104 has a plurality of first horizontal rails 104a and a plurality of first vertical rails 104b. The plurality of first cross rails 104a are arranged so as to extend in the front-rear direction, and are arranged separately from each other at the upper part and the lower part of the steady rest portion 104. The plurality of first cross rails 104a and the battery unit 90 are attached and fixed by fastening members such as bolts.

As shown in FIG. 13, the plurality of first vertical rails 104b extend in the vertical direction and are arranged so as to be separated from each other in the front-rear direction, and connect the upper first horizontal rail 104a and the lower first horizontal rail 104a. It is a member. Specifically, the plurality of first vertical rails 104b are arranged separately from each other at the front portion, the middle portion, and the rear portion of the steady rest portion 104. The first vertical rail 104b on the front side connects the front ends of the first horizontal rail 104a to each other, and the first vertical rail 104b in the middle portion connects the middle portions of the first horizontal rail 104a to each other, and the first vertical rail on the rear side. The crosspiece 104b connects the rear ends of the first cross rail 104a to each other. The plurality of first vertical rails 104b and the battery unit 90 are attached and fixed by fastening members such as bolts.

As shown in FIG. 13, the extension portion 105 is a portion extending upward from the steady rest portion 104. As shown in FIGS. 12 and 13, the extension portion 105 has a shorter length in the front-rear direction than the steady rest portion 104. The extension portion 105 has a plurality of second vertical rails 105a and a second horizontal rail 105b. The plurality of second vertical rails 105a extend in the vertical direction and are arranged so as to be separated from each other in the front-rear direction. Of the plurality of second vertical rails 105a, the front second vertical rail 105a is located behind the front first vertical rail 104b of the anti-sway portion 104, and the rear second vertical rail 105a is located. It is located in front of the first vertical rail 104b on the rear side of the steady rest portion 104. Of the plurality of second vertical rails 105a, the second vertical rail 105a in the middle portion is located between the second vertical rail 105a on the front side and the second vertical rail 105a on the rear side.

As shown in FIG. 13, the second cross rail 105b is arranged so as to extend in the front-rear direction, and connects the upper portions of the plurality of second vertical rails 105a. The second horizontal rail 105b is arranged from the front second vertical rail 105a to the rear second vertical rail 105a.
As shown in FIGS. 12 and 13, the connecting stay 103U is a stay that connects the upper portion of the first standing portion 103L and the upper portion of the second standing portion 103R to support the electrical component 92. That is, the connecting stay 103U also serves to reinforce the first standing portion 103L and the second standing portion 103R and to support the electrical component 92. Specifically, the connecting stay 103U is formed of, for example, a thick steel plate, and is arranged so that the plate surface faces in the vertical direction. The length of the connecting stay 103U in the width direction is longer than the length in the front-rear direction, and the length in the front-rear direction is shorter than the length in the front-rear direction of the battery unit 90. One end (left end) of the connecting stay 103U in the width direction is attached to the upper portion of the first standing portion 103L, that is, the second cross rail 105b. The left end of the connecting stay 103U is attached and fixed to the second cross rail 105b with a fastening member such as a bolt. On the other hand, the other end (right end) of the connecting stay 103U in the width direction is attached to the upper portion of the second standing portion 103R, that is, the second cross rail 105b. The right end of the connecting stay 103U is attached and fixed to the second cross rail 105b with a fastening member such as a bolt.

As shown in FIGS. 12 and 13, electrical components 92 are placed side by side in the width direction on the upper portion of the connecting stay 103U. The electrical components 92 are arranged in the upper part of the connecting stay 103U in the order of the inverter 92b, the junction box 92a, and the DC / DC converter 92c from one side (left side) in the width direction. The electrical component 92 and the connecting stay 103U are attached and fixed by fastening members such as bolts. As shown in FIG. 13, a plurality of second communication holes 103U1 are formed in the connecting stay 103U at positions corresponding to the electrical components 92. The plurality of second communication holes 103U1 are holes that penetrate in the vertical direction, and a cable connected to the electrical component 92 mounted on the connecting stay 103U can be arranged. Further, the plurality of communication holes can release the heat released from the electrical component 92. The plurality of second communication holes 103U1 need only be able to arrange cables connected to the electrical component 92, and the number, shape, and position thereof are not limited to the above configuration.

As shown in FIG. 16, a gap (arrangement space) E is formed between the lower surface of the connecting stay 103U and the upper surface of the battery unit 90. Various cables connected to the electrical component 92 provided in the swivel work machine 1 are arranged in the arrangement space E. In the present embodiment, a cable 91a connected to the lower part of the inverter 92b and connected to the electric motor 91 is arranged in the arrangement space E.

As shown in FIGS. 4, 5, 6, and 17, the swivel work machine 1 includes a shroud 110 that arranges the radiator 94 and the oil cooler 30 above the hydraulic pump P and the electric motor 91. The shroud 110 is a structure that surrounds and supports both the radiator 94 (radiator fan 94a) and the oil cooler 30 (oil cooler fan 30a), and supports the radiator fan 94a and the oil cooler fan 30a so as to line up in the front-rear direction. To do. Specifically, the shroud 110 supports the radiator fan 94a on the front side and the oil cooler fan 30a on the rear side. The shroud 110 has a fixing portion 111 and a guide portion 112.

As shown in FIGS. 18 and 19, the fixing portion 111 surrounds the radiator fan 94a and the oil cooler fan 30a, and supports the radiator 94 and the oil cooler 30. The fixing portion 111 covers the front side of the radiator fan 94a and the rear side of the oil cooler fan 30a. Further, the fixing portion 111 covers the upper side and the lower side of the radiator fan 94a and the oil cooler fan 30a. The fixing portion 111 includes a lower plate portion 111a, an upper plate portion 111b, a front plate portion 111c, a rear plate portion 111d, and a partition wall 111e. The lower plate portion 111a is a plate-shaped portion constituting the lower side of the fixed portion 111, and is arranged so that the plate surface faces in the vertical direction.

As shown in FIG. 18, the upper plate portion 111b is a plate-shaped portion constituting the upper side of the fixing portion 111, and is arranged so that the plate surface faces in the vertical direction. The upper plate portion 111b is arranged above the lower plate portion 111a, and is arranged so as to face the lower plate portion 111a in the vertical direction.
As shown in FIG. 18, the front plate portion 111c is a plate-shaped portion constituting the front side of the fixing portion 111, extends upward from the front end of the lower plate portion 111a, and reaches the front end of the upper plate portion 111b. ing.

As shown in FIG. 18, the rear plate portion 111d is a plate-shaped portion constituting the rear side of the fixing portion 111, extends upward from the rear end of the lower plate portion 111a, and is rear of the upper plate portion 111b. It has reached the edge. That is, the front plate portion 111c and the rear plate portion 111d are arranged facing each other so as to be separated from each other in the front-rear direction.
As shown in FIGS. 18 and 19, the partition wall 111e is a wall that separates the radiator fan 94a and the oil cooler fan 30a. The partition wall 111e is arranged so as to extend in the vertical direction, and connects the middle portion in the front-rear direction of the upper plate portion 111b and the middle portion in the front-rear direction of the lower plate portion 111a.

As shown in FIGS. 18 and 19, the guide portion 112 extends rearward and outward in the width direction from the front portion of the fixed portion 111, and the cooling air and the oil cooler fan 30a generated by driving the radiator fan 94a. Guides at least one of the cooling air generated by the drive of. In the present embodiment, the guide unit 112 guides the cooling air generated by driving the radiator fan 94a. The guide portion 112 is a straightening vane extending from the front plate portion 111c so as to be inclined to the right rear, and guides the cooling air along the plate surface. One end (left front end) of the guide portion 112 is provided at the outer end (right side) of the front plate portion 111c in the width direction, and the other end (right rear end) of the guide portion 112 is on the right. It is inclined rearward and reaches the middle part of the oil cooler fan 30a in the front-rear direction and reaches the front part of the opening of the exterior cover 70 in a lateral view. That is, the cooling air guided by the guide portion 112 is discharged to the outside from the rear room R through the opening.

As shown in FIGS. 4, 5, 6, and 17, the shroud 110 is arranged on the other side (right side) of the support frame 65 in the width direction. Specifically, as shown in FIGS. 20A and 20B, the shroud 110 is fixed to the fixing bracket 65B attached to the first leg 65a. The fixing bracket 65B extends downward from the first extending portion 65a2 and reaches the right side and the upper side of the battery unit 90. The shroud 110 is attached and fixed by a fastening member such as a bolt. As shown in FIG. 20A, the shroud 110 supports the oil cooler 30 and the radiator 94 together with the fixing bracket 65B by being fastened together with the oil cooler 30, the radiator 94, the fixing bracket 65B, and the fastening member. In the present embodiment, the rear plate portion 111d is fastened and fixed together with the rear side of the oil cooler 30 and the rear side of the fixing bracket 65B. The partition wall 111e is fastened and fixed together with the front side of the radiator 94 and the middle portion of the fixing bracket 65B. The front plate portion 111c is fastened and fixed together with the front side of the radiator 94 and the front side of the fixing bracket 65B. The attachment of the oil cooler 30 and the radiator 94 is not limited to the above configuration, and may be fixed to the fixing bracket 65B separately from the shroud 110 as shown in FIG. 20B.

As shown in FIG. 11, the swivel work machine 1 includes a control device 120 and a storage unit 121. The control device 120 is a device composed of an electric / electronic circuit, a program stored in a CPU, and the like, and controls various devices included in the swivel work machine 1. For example, the control device 120 controls the rotation speed of the electric motor 91 based on the operation of the rotation speed operating tool 5c which is provided around the driver's seat 8 and can be operated. Further, the control device 120 controls the start of the turning work machine 1 based on the operation of the starter switch 7 which is provided around the driver's seat 8 and can start the turning work machine 1.

The storage unit 121 is a non-volatile memory or the like, and stores various information or the like related to the control of the control device 120. For example, the storage unit 121 stores information such as a table regarding the rotation speed of the electric motor 91 with respect to the operation amount of the rotation speed operation tool 5c.
As shown in FIGS. 11, 12, and the like, the battery unit 90 includes a plurality of batteries 90a. The plurality of batteries 90a are connected in parallel with each other. The battery 90a can store electricity and is a secondary battery such as a lithium ion battery or a lead storage battery. The battery 90a has a plurality of cells inside, and the plurality of cells are electrically connected in series and / or in parallel. In this embodiment, the battery unit 90 has two batteries 90a. The number of batteries 90a included in the battery unit 90 may be a plurality, not limited to two, and may be three or more.

As shown in FIG. 11, the swivel work machine 1 includes a connection switching unit 131. The connection switching unit 131 switches the power supply path 132 from the battery 90a to the electric motor 91 between the connected state and the cutoff state for each battery 90a. The connection switching unit 131 switches between a connected state and a cutoff state by, for example, performing a relay opening / closing operation of at least a part of the power supply path 132. As a result, the battery unit 90 outputs power from the battery 90a in the connected state among the plurality of batteries 90a, and stops the output of power from the battery 90a in the other cutoff state. The control device 120 controls the connection switching unit 131, that is, sets the battery 90a that outputs power from the battery unit 90.

Further, each battery 90a has a BMU (battery management unit) 123 that monitors and controls the battery 90a. The BMU 123 acquires the voltage, temperature, current, terminal voltage of the internal cell, and the like of the battery 90a, and calculates the remaining capacity of the battery 90a. Further, the BMU 123 can control the opening and closing of the relay inside the battery 90a, and can control the start and stop of the power supply of the battery 90a. The BMU 123 may be built in each battery 90a or may be installed outside each battery 90a.

The control device 120 is set as an output battery that outputs power from the battery unit 90 by connecting one battery 90a among the plurality of batteries 90a, and shuts off the other batteries 90a to output power. Set as. The control device 120 has a battery control unit 120a that controls switching of the output battery.
The battery control unit 120a is communicably connected to the connection switching unit 131 by wire or wirelessly, and controls the connection switching unit 131 by transmitting a signal. As a result, the battery control unit 120a switches between the connected state and the cutoff state of the plurality of batteries 90a, and performs switching control (switching process) of the output battery and the stopped battery.

The battery control unit 120a controls switching between the output battery and the stopped battery based on a predetermined condition. Specifically, the battery control unit 120a includes a selector 122 communicably connected to the control device 120 and a plurality of batteries 90a when the drive limiting device 47 prohibits or limits the driving of the working device 20. The output battery and the stop battery are set based on the remaining capacity of each of the above. In other words, the battery control unit 120a performs the process of switching the output battery after the drive of the work device 20 is prohibited or restricted by the drive limiting device 47.

Specifically, the control device 120 acquires a state acquisition unit 120d that acquires information indicating whether the drive limiting device 47 is in a state in which driving of the working device 20 is permitted, prohibited, or restricted. The battery control unit 120a performs a process of switching the output battery after the drive of the work device 20 is prohibited or restricted by the drive limiting device 47 based on the information acquired by the state acquisition unit 120d. In the present embodiment, the state acquisition unit 120d shuts off the unload valve 48 from the supply position 48a based on the signal acquired from the sensor connected to the control device 120 and detecting the operation state of the unload operation tool 5b. Which of the positions 48b is acquired.

The control device 120 may set the output battery and the stop battery in a state where the work device 20 is not driven, and detects a state in which the work device 20 is not driven separately from the operation of the drive limiting device 47. , The output battery and the stop battery may be set. For example, the control device 120 may acquire the operation information of the operation device 5 to acquire the information on whether or not the hydraulic device M and the work device 20 are being driven.

The battery control unit 120a sets the battery 90a selected and instructed via the selector 122 as the output battery. On the other hand, the battery control unit 120a sets the battery 90a, which is not instructed to be selected via the selector 122, as the stop battery.
The selector 122 selects one of the plurality of batteries 90a, the battery 90a, based on the operation of the operator. That is, the selector 122 receives an instruction from the operator to select the battery 90a as the output battery. For example, the selector 122 is a plurality of operation switches that are arranged around the driver's seat 8 and can be pressed. Each of the plurality of operation switches is associated with the battery 90a, and when one operation switch is operated, one battery 90a associated with the one operation switch is selected.

The configuration of the selector 122 is not particularly limited, and it is sufficient that one of the plurality of batteries 90a can be selected and operated. Further, the selector 122 may perform a selection operation of the battery 90a in conjunction with the display device 124a. The selector 122 may be such that one battery 90a icon is selected from a plurality of battery 90a icons displayed on the display device 124a by a key button operation, a jog dial operation, a touch panel operation, or the like.

The battery control unit 120a sets the remaining capacity of the battery 90a selectable as the output battery by the selector 122 to a value larger than zero based on the remaining capacity detected by the capacity detecting unit. The battery 90a is equal to or higher than the first threshold value. Limit to.
The battery control unit 120a stops supplying electric power to the electric motor 91 due to insufficient remaining capacity of the battery 90a selected as the output battery (for example, the remaining capacity is less than the first threshold value), and the other batteries 90a When there is a battery 90a having a remaining capacity capable of supplying electric power to the electric motor 91, the output battery is switched to one of the batteries 90a having a remaining capacity.

Further, the battery control unit 120a is a battery that can be selected as an output battery by the selector 122 when there is a battery 90a in which the remaining capacity of the output battery is zero and the remaining capacity exceeds zero and is less than the first threshold value. The 90a is limited to the battery 90a having a remaining capacity exceeding zero, and the output battery is switched to one of the batteries 90a having a remaining capacity capable of supplying power to the electric motor 91. Alternatively, when there is a battery 90a in which the remaining capacity of the output battery is zero and the remaining capacity exceeds zero and is less than the first threshold value, the battery control unit 120a determines the remaining capacity regardless of the selection of the selector 122. The battery 90a in which the value exceeds zero and is less than the first threshold value may be automatically set as the output battery.

The capacity detection unit detects the remaining capacity of the battery 90a, respectively. The capacity detection unit is communicably connected to the control device 120 by wire or wirelessly, and outputs information regarding the detected remaining capacity of the battery 90a to the control device 120. In the present embodiment, the function of the capacity detection unit is performed by the BMU 123 provided in each of the plurality of batteries 90a. For example, the BMU 123 detects the remaining capacity of the battery 90a by using the terminal voltage of the cell inside the battery 90a and the voltage measuring method. The method for detecting the remaining capacity of the battery 90a is not limited to the voltage measurement method, and may be a Coulomb counter method, a battery cell modeling method, an impedance track method, or the like. Further, the capacity detection unit may be provided separately from the BMU 123.

Further, the battery control unit 120a includes a battery 90a in which the remaining capacity of the battery 90a selected as the output battery is reduced to less than the first threshold value and the remaining capacity of the other batteries 90a is equal to or more than the first threshold value. In this case, the output battery is switched to one of the batteries 90a whose remaining capacity is equal to or greater than the first threshold value. As shown in FIG. 11, the battery control unit 120a has a selection unit 120a1. The selection unit 120a1 selects one of the plurality of batteries 90a as the output battery. Specifically, when the battery unit 90 has a battery 90a having a remaining capacity of the first threshold value or more, the selection unit 120a1 selects any of the batteries 90a having a remaining capacity of the first threshold value or more as the output battery. In other words, when the battery unit 90 has a battery 90a having a remaining capacity of the first threshold value or more, the selection unit 120a1 does not select the battery 90a having a remaining capacity less than the first threshold value as an output battery. At this time, for example, the battery 90a having the maximum remaining capacity may be selected from the batteries 90a having a remaining capacity less than the first threshold value and not more than zero.

Further, the turning work machine 1 includes a notification device 124, and the battery control unit 120a has a remaining capacity of the battery 90a selected as the output battery based on the remaining capacity detected by the capacity detection unit (BMU123). When the value drops below the first threshold value, the notification device 124 is made to give a notification prompting the switching of the output battery. Further, the battery control unit 120a does not have a battery 90a in which the remaining capacity of the battery 90a selected as the output battery is lower than the first threshold value and the remaining capacity is equal to or higher than the first threshold value among the other batteries 90a. In this case, the notification device 124 is made to perform a notification prompting charging. Further, the control device 120 causes the notification device 124 to give a warning notification of the remaining capacity when the remaining capacity of the battery 90a selected as the output battery drops to less than the second threshold value, which is smaller than the first threshold value.

The notification device 124 is a device that notifies the operator or the manager of the remaining capacity of the plurality of batteries 90a detected by the capacity detection unit (BMU123). The notification device 124 is communicably connected to the control device 120 and is controlled by the control device 120. The notification device 124 notifies the operator boarding the turning work machine 1 of the remaining capacity of the battery 90a by sound, light, video, or a combination thereof. Specifically, when the notification device 124 notifies the remaining capacity of the battery 90a by video, the notification device 124 is a display device 124a such as a monitor provided in the turning work machine 1 and displaying an image.

As shown in FIG. 21A, the battery control unit 120a causes the display device 124a to display the remaining capacity of each battery 90a. The battery control unit 120a displays the remaining capacity display 124a1 of the output battery and the display 124a2 of the remaining capacity of the stopped battery in different display modes. For example, the display 124a2 of the remaining capacity of the stopped battery is grayed out and displayed. As shown in FIG. 21B, when the remaining capacity of the output battery drops below the first threshold value, the battery control unit 120a displays in the vicinity of the display 124a1 of the remaining capacity of the output battery to prompt the switching of the output battery. .. As shown in FIG. 21C, when the remaining capacity of the output battery drops below the first threshold value and there is no battery 90a among the other batteries 90a whose remaining capacity is equal to or higher than the first threshold value, the battery control unit 120a sets the battery control unit 120a. The display 124a3 of the remaining capacity of the battery 90a whose remaining capacity is less than the first threshold value and / or its vicinity is displayed to indicate that the output battery cannot be switched and that charging is urged. Further, as shown in FIG. 21D, when the remaining capacity of the output battery drops below the second threshold value, the battery control unit 120a displays the remaining capacity of the battery 90a whose remaining capacity is less than the second threshold value 124a4 and / Or in the vicinity thereof, display that the output battery has no remaining capacity and that charging is urged.

Further, when the notification device 124 notifies the remaining capacity of the battery 90a by sound, the notification device 124 is a voice output device 124b (speaker) that notifies by voice. The notification device 124 only needs to be able to notify the operator and the administrator of the remaining capacity of the battery 90a, and the notification device 124 is provided around the driver's seat 8 and is composed of a plurality of lamps (for example, LED bulbs). The light emitting device 124c (indicator) may be one or more of the display device 124a, the audio output device 124b, and the light emitting device 124c.

The battery control unit 120a performs the first process, the second process, and the third process to perform the output battery switching process. Specifically, when the battery control unit 120a performs the output battery switching process, the battery control unit 120a first instructs the connection switching unit 131 to shut off all the batteries 90a among the plurality of batteries 90a including the output battery (). First process).
After the first process, the battery control unit 120a instructs the connection switching unit 131 to put the battery 90a set as the output battery into the connected state (second process). Further, the control device 120 connects the battery 90a selected as the output battery in the second process and the inverter 92b.

After the second process, the battery control unit 120a instructs the battery 90a to start supplying power to the electric motor 91 from the battery 90a which is set as the output battery and is in the connected state. Specifically, the battery control unit 120a gives an instruction to start power supply to the BMU 123 provided in each of the plurality of batteries 90a.
Hereinafter, a series of steps for setting the output battery and the stopped battery by the control device 120 (battery control unit 120a) will be described mainly with reference to FIG. 22. First, the control device 120 determines whether the unload valve 48 is at the shutoff position 48b (S1). When it is determined that the unload valve 48 is not the shutoff position 48b (S1, No), the control device 120 continues the process of S1 and monitors that the unload valve 48 is switched to the shutoff position 48b.

When the unload valve 48 is determined to be the shutoff position 48b (S1, Yes), the control device 120 determines whether or not the starter switch 7 has been operated based on the operation signal input from the starter switch 7 (S1, Yes). S2). When the starter switch 7 is not operated (S2, No), the control device 120 continues the process of S2 and monitors that the starter switch 7 is operated.

When it is determined that the starter switch 7 has been operated (S2, Yes), the battery control unit 120a instructs the connection switching unit 131 to shut off all the batteries 90a among the plurality of batteries 90a including the output battery. The connection switching unit 131 switches all the batteries 90a to the cutoff state (first process, S3).
When the first process (S3) is performed, the battery control unit 120a selects the battery 90a that can be selected as the output battery by the selector 122 based on the remaining capacity detected by the BMU 123, and the remaining capacity of the battery 90a is equal to or greater than the first threshold value. (S4), the operator operates the selector 122 to select the designated battery 90a as the output battery from the batteries 90a set to be selectable, and switches to the connected state (S5). Specifically, the battery control unit 120a instructs the connection switching unit 131 to put the battery 90a set as the output battery into the connected state, and the connection switching unit 131 switches the battery 90a to the connected state and controls the control device 120. Brings the battery 90a and the inverter 92b into a connected state (second process).

Next, after the second process, the battery control unit 120a instructs the BMU 123 to start supplying power to the electric motor 91 from the battery 90a set as the output battery and connected, and the BMU 123 instructs the battery 90a to start supplying power to the electric motor 91. The internal relay is controlled to open and close, and the power supply of the output battery is started (third process, S6).
After that, the battery control unit 120a determines whether or not the remaining capacity of the output battery is less than the first threshold value based on the remaining capacity of the output battery detected by the BMU 123 (S7). When it is determined that the remaining capacity of the output battery is equal to or greater than the first threshold value (S7, No), the battery control unit 120a proceeds to the process of S15.

When the battery control unit 120a determines that the remaining capacity of the output battery is less than the first threshold value (S7, Yes), the battery whose remaining capacity is equal to or larger than the first threshold value based on the remaining capacity of the output battery detected by the BMU 123. It is determined whether or not there is 90a (S8).
When the battery control unit 120a determines that there is a battery 90a equal to or higher than the first threshold value (S8, Yes), the battery control unit 120a outputs, for example, in the vicinity of the display 124a1 of the remaining capacity of the output battery of the display device 124a, as shown in FIG. 21B. A message indicating that the battery switching is urged is displayed, and the notification device 124 is made to perform a notification prompting the output battery switching (S9).

After that, the battery control unit 120a determines whether the unload valve 48 is at the shutoff position 48b (S10). When it is determined that the unload valve 48 is not at the shutoff position 48b (S10, No), the battery control unit 120a continues the process of S10 and monitors that the unload valve 48 reaches the shutoff position 48b.
On the other hand, when the battery control unit 120a determines that the unload valve 48 is at the shutoff position 48b (S10, Yes), the battery control unit 120a determines whether or not a predetermined time has elapsed since the unload valve 48 was switched to the shutoff position 48b. Judgment (S11). When the battery control unit 120a determines that the predetermined time has not elapsed (S11, No), the battery control unit 120a continues the process of S11 and monitors that the predetermined time has elapsed. After a lapse of a predetermined time (S11, Yes), the battery control unit 120a instructs the connection switching unit 131 to shut off all the batteries 90a among the plurality of batteries 90a including the output battery, and the connection switching unit 131 sends the connection switching unit 131. All batteries 90a are switched to the cutoff state (first process, S12).

Next, the selection unit 120a1 selects one of the batteries 90a having a remaining capacity of the first threshold value or more in the battery unit 90 as the output battery, and the battery control unit 120a uses the battery 90a selected by the selection unit 120a1 as the output battery. The connection switching unit 131 is instructed to be in the connected state, the connection switching unit 131 switches the battery 90a to the connected state, and the control device 120 puts the battery 90a and the inverter 92b in the connected state (second process, S13). ).

Next, the battery control unit 120a instructs the BMU 123 to start supplying power to the electric motor 91 from the battery 90a which is set as the output battery and is in the connected state, and the BMU 123 controls the opening and closing of the relay inside the battery 90a. , The power supply of the output battery is started (third process, S14). After that, the battery control unit 120a determines whether or not to end the operation of the work machine 1 (S15). When the battery control unit 120a determines that the operation is not terminated (S15, No), the battery control unit 120a returns to the process of S7.

On the other hand, when the battery control unit 120a determines that the operation is terminated (S16, Yes), the battery control unit 120a terminates a series of controls related to switching of the output battery and performs a predetermined operation stop process. The determination as to whether or not to end the operation of the work machine 1 may be made based on, for example, whether or not the engine stop switch has been operated. The operation stop process may include, for example, a process of switching all the batteries 90a to a cutoff state.

Further, when the battery control unit 120a determines in S8 that there is no battery 90a equal to or higher than the first threshold value (S8, No), as shown in FIG. 21C, the battery control unit 120a may use, for example, display 124a3 of the display device 124a. In and / or in the vicinity thereof, an indication that the output battery cannot be switched is displayed, and the notification device 124 is made to notify that the output battery cannot be switched and that charging is urged (S16).

Next, the battery control unit 120a acquires a signal from the BMU 123 and determines whether or not the charging process has started (S17). When the charging process is started, the battery control unit 120a ends a series of controls relating to switching of the output battery.
On the other hand, when the charging process is not started (S17, No), the battery control unit 120a sets the remaining capacity of the output battery as the second threshold value based on the remaining capacity of the output battery detected by the battery control unit 120a of the BMU 123. It is determined whether or not it is less than (S18). When it is determined that the remaining capacity of the output battery is less than the second threshold value (S18, No), the battery control unit 120a returns to the process of S16.

When the battery control unit 120a determines that the remaining capacity of the output battery is less than the second threshold value (S18, Yes), as shown in FIG. 21D, the battery control unit 120a is a battery having a remaining capacity less than the second threshold value. Display of the remaining capacity of 90a At 124a4 and / or in the vicinity thereof, it is displayed that the output battery has no remaining capacity and that charging is urged (S19).
After that, the battery control unit 120a determines whether or not the remaining capacity of the output battery is zero based on the remaining capacity of the output battery detected by the battery control unit 120a (S20). When it is determined that the remaining capacity of the output battery is not zero (S20, No), the battery control unit 120a returns to the process of S16.

On the other hand, when it is determined that the remaining capacity of the output battery is zero (S20, Yes), the battery control unit 120a stops the power supply from the battery 90a connected as the output battery to the electric motor 91. The BMU 123 is instructed to open and close the relay inside the battery 90a to stop the power supply of the output battery (S21). That is, when the remaining capacity of the output battery is zero, the battery control unit 120a cuts off the connection between the output battery and the power supply path (power supply line) 132 by the relay open / close control.

Further, as shown in FIG. 21E, the battery control unit 120a causes the notification device 124 to notify the notification device 124 to prompt the operation of the unload operation tool 5b (S22), and based on the remaining capacity of the output battery detected by the BMU 123. It is determined whether or not there is a battery 90a having a remaining capacity other than zero, that is, a battery 90a having a remaining capacity exceeding zero (S23). When the battery control unit 120a determines that there is no battery 90a having a remaining capacity other than zero (S23, No), the battery control unit 120a ends a series of controls related to switching of the output battery.

On the other hand, when the battery control unit 120a determines that there is a battery 90a having a remaining capacity other than zero (S23, Yes), the battery control unit 120a determines whether the unload valve 48 is at the shutoff position 48b (S24). When the battery control unit 120a determines that the unload valve 48 is not the shutoff position 48b (S24, No), the battery control unit 120a continues the process of S24 and monitors that the unload valve 48 is switched to the shutoff position 48b.

When the battery control unit 120a determines that the unload valve 48 is at the shutoff position 48b (S24, Yes), the battery control unit 120a determines whether or not a predetermined time has elapsed since the unload valve 48 was switched to the shutoff position 48b. (S25). When the battery control unit 120a determines that the predetermined time has not elapsed (S25, No), the battery control unit 120a continues the process of S11 and monitors that the predetermined time has elapsed. When the battery control unit 120a determines that the predetermined time has elapsed (S25, Yes), the battery control unit 120a instructs the connection switching unit 131 to shut off all the batteries 90a among the plurality of batteries 90a including the output battery, and connects them. The switching unit 131 switches all the batteries 90a to the cutoff state (first process, S26).

Next, the battery control unit 120a sets the battery 90a that can be selected as the output battery by the selector 122 to the battery 90a whose remaining capacity is non-zero based on the remaining capacity detected by the BMU 123 (S27), and can be selected. The operator operates the selection tool 122 to select the designated battery 90a as the output battery from the batteries 90a set in the above, and switches to the connected state (S28). Specifically, the battery control unit 120a instructs the connection switching unit 131 to put the battery 90a set as the output battery into the connected state, and the connection switching unit 131 switches the battery 90a to the connected state and controls the control device 120. Brings the battery 90a and the inverter 92b into a connected state (second process).

Next, the battery control unit 120a instructs the BMU 123 to start supplying power to the electric motor 91 from the battery 90a which is set as the output battery after the second processing and is in the connected state, and the BMU 123 is inside the battery 90a. The relay opening and closing control of the above is performed, and the power supply of the output battery is started (third process, S29).
After that, the battery control unit 120a determines whether or not to end the operation of the work machine 1 (S30), and when it is determined to end the operation (S30, Yes), as in S15, a series of series related to switching of the output battery. The control is terminated and a predetermined operation stop process is performed. When the battery control unit 120a determines that the operation is not terminated (S30, No), the battery control unit 120a returns to the process of S16.

As shown in FIG. 11, the swivel work machine 1 includes a first drive motor 30b for driving the oil cooler fan 30a and a second drive motor 94b for driving the radiator fan 94a, and includes the oil cooler fan 30a and the second drive motor 94b. The radiator fan 94a can be driven independently of the electric motor 91. Hereinafter, control of the oil cooler fan 30a and the radiator fan 94a will be described.

As shown in FIG. 11, the first drive motor 30b and the second drive motor 94b are connected to the control device 120, respectively, and the control device 120 controls the drive of the first drive motor 30b and the second drive motor 94b. It has a fan control unit 120b. The fan control unit 120b independently controls the first drive motor 30b (radiator fan 94a) and the second drive motor 94b (oil cooler fan 30a).

As shown in FIG. 11, the swivel work machine 1 includes a water temperature detection unit 126 and an oil temperature detection unit 127. The water temperature detection unit 126 is a sensor that detects the temperature of the cooling water (refrigerant) as a voltage value. The water temperature detection unit 126 is provided in, for example, the feed water channel 95b, and detects the temperature of the cooling water toward the radiator 94. The water temperature detection unit 126 is connected to the control device 120 by wire or wirelessly, and outputs the detected temperature information of the cooling water as a signal to the control device 120.

The oil temperature detection unit 127 is a sensor that detects the temperature of the hydraulic oil as a voltage value. The oil temperature detection unit 127 is provided in, for example, the second pipeline 42, and detects the temperature of the hydraulic oil toward the oil cooler 30. The oil temperature detection unit 127 is connected to the control device 120 by wire or wirelessly, and outputs the detected hydraulic oil temperature information as a signal to the control device 120.
The fan control unit 120b controls the drive of the radiator fan 94a so that the temperature of the cooling water does not exceed the set temperature based on the temperature of the cooling water detected by the water temperature detection unit 126 and the preset control map. .. Further, when the temperature of the hydraulic oil detected by the oil temperature detection unit 127 is less than a predetermined value, the fan control unit 120b stops the drive of the oil cooler fan 30a, and the temperature of the hydraulic oil detected by the oil temperature detection unit 127. When is equal to or more than a predetermined value, the temperature of the hydraulic oil is controlled so as not to exceed the set temperature based on the preset control map.

As shown in FIG. 11, the operation device 5 has a rotation speed control tool 5c, and the control device 120 has a rotation speed control unit 120c. The rotation speed operation tool 5c receives a setting input of the rotation speed range (upper limit value and lower limit value of the rotation speed) of the electric motor 91 from the operator. Specifically, a plurality of selectable rotation speed ranges are set in advance, and the operator can operate the rotation speed control tool 5c to select a desired rotation speed range.

The rotation speed control unit 120c has a normal mode and an AI (auto idle) mode. In the normal mode, the rotation speed control unit 120c changes the rotation speed of the electric motor 91 according to the load of the hydraulic pump P that changes according to the operating state of the work device 20 or the current consumption of the electric motor 91. It is controlled within the rotation speed range set by using 5c. In the AI mode, the rotation speed control unit 120c sets the rotation speed of the electric motor 91 to be lower than the lower limit of the rotation speed (for example, 1500 rpm) that can be set by using the rotation speed control tool 5c. Control to (for example, 500 rpm).

The rotation speed control unit 120c switches between the normal mode and the AI mode based on the current value detected by the current detection unit that detects the current (current value) of the electric power output from the battery unit 90 or the inverter 92b. When the magnitude of the current value output by the battery unit 90 can be changed according to the load of the electric motor 91, the current detection unit detects the current value output from the battery unit 90 or the inverter 92b. On the other hand, when the magnitude of the current value output by the battery unit 90 cannot be changed according to the load of the electric motor 91, the current detection unit detects the current value output from the inverter 92b. The current detection unit is wirelessly or wiredly and communicably connected to the control device 120, and outputs the detected current value to the control device 120.

In the present embodiment, the battery unit 90 can change the magnitude of the output current value, and the current detection unit detects the current value output from the battery unit 90. For example, the battery unit 90 is provided. BMU123.
For example, when the operating lever 5a is operated, the spool is moved by the operation, and the control valves V1 to V8 supply the hydraulic oil M in an amount proportional to the moved amount of the spool to the flood control device M to be controlled. As a result, the load of the hydraulic pump P that discharges the hydraulic oil increases, and the current consumption of the electric motor 91 that drives the hydraulic pump P increases. Therefore, the battery unit 90 increases the magnitude of the output current value, and the current value detected by the BMU 123 increases. In other words, as the amount of operation from the neutral position of the operating lever 5a increases, the current value detected by the BMU 123 increases.

On the other hand, when the operating lever 5a is operated from the operated state to the neutral position side, the operating amount of the operating lever 5a is reduced, the load of the hydraulic pump P is reduced, and the current of the electric motor 91 for driving the hydraulic pump P is reduced. Consumption is reduced. Therefore, the battery unit 90 reduces the magnitude of the output current value, and the current value detected by the BMU 123 decreases. In other words, when the amount of operation from the neutral position of the operation lever 5a decreases, the current value detected by the BMU 123 decreases.

When the current detection unit detects the current value output from the inverter 92b, the load on the hydraulic pump P increases when the operation lever 5a is operated from the neutral position, that is, when the operation amount of the operation lever 5a increases. The current consumption of the electric motor 91 that drives the hydraulic pump P increases. Therefore, the inverter 92b increases the magnitude of the output current value, and the current value detected by the current detection unit increases. In other words, as the amount of operation from the neutral position of the operating lever 5a increases, the current value detected by the current detection unit increases.

On the other hand, when the operating lever 5a is operated from the operated state to the neutral position side, the operating amount of the operating lever 5a is reduced, the load of the hydraulic pump P is reduced, and the current of the electric motor 91 for driving the hydraulic pump P is reduced. Consumption is reduced. Therefore, the inverter 92b reduces the magnitude of the output current value, and the current value detected by the current detection unit decreases. In other words, when the amount of operation from the neutral position of the operation lever 5a decreases, the current value detected by the current detection unit decreases.

Explaining in detail the switching between the normal mode and the AI mode of the rotation speed control unit 120c, the rotation speed control unit 120c rotates when the current value detected by the current detection unit (BMU123) is equal to or higher than a predetermined value (third threshold value). The range of the motor rotation speed of the electric motor 91 is set according to the setting operation for the number operating tool 5c (normal mode). On the other hand, when the current value detected by the BMU 123 is less than the third threshold value, the rotation speed control unit 120c switches to the AI mode and sets the motor rotation speed of the electric motor 91 to a predetermined idling rotation speed.

Specifically, when the current value detected by the BMU 123 is less than the third threshold value, the rotation speed control unit 120c detects the current value for a predetermined time (for example, 3 seconds, 4 seconds, etc.) after the current value becomes less than the third threshold value. The motor rotation speed of the electric motor 91 is set within the range set by the rotation speed controller 5c according to the current value detected by the unit, and after a predetermined time elapses, the mode is switched to the AI mode to determine the motor rotation speed of the electric motor 91. Set to the idling speed of. Specifically, when the detected current value is less than the third threshold value, the rotation speed control unit 120c sets the motor rotation speed within a range set by the rotation speed controller 5c for a predetermined time after the current value becomes less than the third threshold value. Set to the lower limit of. Further, after the lapse of a predetermined time, the rotation speed control unit 120c switches to the AI mode and sets the motor rotation speed of the electric motor 91 to an idling rotation speed which is lower than the lower limit value in the above range.

That is, when the current value detected by the BMU 123 becomes less than a predetermined value in the normal mode, the rotation speed control unit 120c maintains the normal mode for a predetermined time and switches to the AI mode after the predetermined time elapses.
On the other hand, in the AI mode, when the current value detected by the BMU 123 becomes equal to or higher than a predetermined value, the rotation speed control unit 120c immediately switches to the normal mode. The third threshold value is a threshold value that is preset and stored in the storage unit 121, and is the battery unit 90 or the battery unit 90 when the operation lever 5a is not operated and the hydraulic device M (working device 20) is not operating. It is set based on the current value of the electric power output from the inverter 92b, is communicably connected to the control device 120, and can be arbitrarily changed by an external terminal operated by an administrator or an operator.

As shown in FIG. 1, the hydraulic circuit of the swivel work machine 1 has a heating circuit H that heats the inside of the protection mechanism 80 using the hydraulic oil used in the hydraulic circuit as a heat medium. The heating circuit H includes a heating device 130, the above-mentioned first pipeline 41, and a second pipeline 42.
The heating device 130 exchanges heat with the heat of the hydraulic oil flowing through the oil passage 40 to heat the inside of the protection mechanism 80. The heating device 130 exchanges heat between the oil passage 40, the oil passage through which the hydraulic oil warmed by the drive of the hydraulic pump P and the hydraulic device M flows, and a medium such as ambient air. The heating device 130 is provided in either one of the first pipe line 41 and the second pipe line 42 in the hydraulic system circuit, and is an oil passage through which the hydraulic oil cooled (removed by heat) by at least the oil cooler 30 flows. It is provided in an oil passage 40 different from 40. In the present embodiment, the heating device 130 is provided in the middle of the second pipeline 42. The second pipeline 42 has a first portion 42a for flowing the hydraulic oil discharged from the hydraulic device M to the heating device 130, and a second portion 42b for flowing the hydraulic oil discharged from the heating device 130 to the radiator 94. Includes.

As shown in FIG. 1, the heating device 130 includes a heat exchange unit 130a and a blower fan 130b. The heat exchange unit 130a is a portion where hydraulic oil flows inside and exchanges heat with a medium such as surrounding air. In the present embodiment, the heat exchange unit 130a is a plurality of fins. The plurality of fins 130a are arranged in parallel and at predetermined intervals so as to face a predetermined direction. The inside of the plurality of fins 130a is hollow, and the inside of the plurality of fins 130a communicates from the fin on one end side toward the fin on the other end side. That is, the hydraulic oil supplied from the first portion 42a flows through the fin on one end side, and the hydraulic oil flows through the inside of the fin in the middle portion toward the fin on the other end side. The hydraulic oil supplied to the fin on the other end side is discharged to the second portion 42b.

The blower fan 130b is a fan that is electrically driven and blows air. The blower fan 130b blows air from the heating device 130 into the protection mechanism 80. Specifically, the blower fan 130b sends the air around the plurality of fins 130a into the inside of the protection mechanism 80. As a result, heat is exchanged with the hydraulic oil via the plurality of fins 130a, and the warmed air is sent into the protection mechanism 80 to heat the inside of the protection mechanism 80.

Further, the swivel work machine 1 can heat the inside of the protection mechanism 80 separately from the heating device 130. Specifically, at least one of the first line 41 and the second line 42 is arranged outside or inside the protection mechanism 80, and is around the first line 41 and the second line 42. It exchanges heat with air to heat the inside of the protection mechanism 80. In the present embodiment, the first pipeline 41 is arranged on the lower side of the floor material (step) inside the protection mechanism 80, the lower side of the driver's seat 8, and the like, and holes such as slits formed in the floor material are formed. The air whose heat has been exchanged flows into the inside of the protection mechanism 80. The hole formed in the floor material has an operable shutter member, and optionally communicates with the periphery of the first pipeline 41 and the inside of the protection mechanism 80, and a shutoff state of blocking. It may be possible to switch to. Further, a fan for blowing air is provided around the first pipe 41 and the second pipe 42, and the heat-exchanged warm air around the first pipe 41 and the second pipe 42 is protected inside the protection mechanism 80. It may be configured to be sent to.

As shown in FIG. 1, the hydraulic circuit only needs to be able to heat the inside of the protection mechanism 80 by using hydraulic oil as a heat medium, and at least of the first pipe 41 and the second pipe 42. A bypass pipeline 50 provided on one side and arranged inside the protection mechanism 80 to heat the inside of the protection mechanism 80 may be provided. The bypass pipeline 50 is an oil passage whose midway portion is arranged inside the protection mechanism 80, and is branched from, for example, a portion (third portion) of the first pipeline 41 on the P side of the hydraulic pump, and is the first pipeline. It joins the part (fourth part) on the M side of the hydraulic device 41.

An operating valve 51 is provided at a branch point where the first pipeline 41 branches to the bypass pipeline 50. The operating valve 51 is, for example, a two-position switching valve with a solenoid valve, and switches between the first position and the second position by exciting or degaussing the solenoid of the solenoid valve. The first position is the first pipe. It is a position that regulates the hydraulic oil flowing from the road 41 to the bypass pipeline 50 and allows the hydraulic oil flowing from the third portion to the fourth portion of the first pipeline 41. The second position is a position that allows the hydraulic oil flowing from the first pipeline 41 to the bypass pipeline 50 and regulates the hydraulic oil flowing from the third portion to the fourth portion of the first pipeline 41. That is, when the operating valve 51 is located at the first position, the hydraulic oil does not flow into the bypass pipe line 50 and the inside of the protection mechanism 80 is not heated (non-heating state). On the other hand, when the operating valve 51 is located at the second position, hydraulic oil is flowed through the bypass pipe line 50 to heat the inside of the protection mechanism 80 (heating state).

The swivel work machine 1 described above includes a swivel table 2, a work device 20 provided on the swivel table 2, a battery unit 90, an electric motor 91 driven by electric power output from the battery unit 90, and a drive of the electric motor 91. The battery unit 90 is arranged at the rear of the swivel base 2, and the electric motor 91 and the hydraulic pump P are arranged side by side in the front-rear direction on the side of the battery unit 90. Has been done. According to the above configuration, the battery unit 90, the electric motor 91, and the hydraulic pump P can be arranged at the rear part of the swivel base 2, and the electric motor 91 and the hydraulic pump P can be arranged in the space on the side of the battery unit 90. it can. As a result, the center of gravity can be positioned on the rear side of the swivel base 2, and the electric motor 91 and the hydraulic pump P can be arranged compactly.

Further, the swivel base 2 can rotate around the swivel axis X extending in the vertical direction, and the battery unit 90, the electric motor 91, and the hydraulic pump P are arranged behind the swivel axis X. According to the above configuration, by locating the center of gravity on the rear side of the swivel axis X, the swivel work machine 1 can maintain its posture even when the work device 20 is being driven.
Further, the turning work machine 1 includes a lower traveling body 10 that supports the turning table 2 around the turning axis X and is capable of traveling, and the rear portion of the battery unit 90 is rearward of the rear end portion of the lower traveling body 10. Is located in. According to the above configuration, by locating the relatively heavy battery unit 90 at the rear, it is possible to easily maintain the posture of the turning work machine 1.

Further, the swivel work machine 1 is arranged on the side of the battery unit 90 and above the hydraulic pump P and the electric motor 91, and includes cooling mechanisms 30 and 94 for cooling the hydraulic oil and the electric motor 91. According to the above configuration, the cooling mechanisms 30 and 94 can be located in the surplus space of the battery unit 90, the hydraulic pump P, and the electric motor 91.
Further, the swivel work machine 1 includes a battery unit 90, an electric motor 91, and a cover 70 that covers the hydraulic pump P, and the cooling mechanisms 30 and 94 discharge air outward in the width direction from the space formed by the cover 70. .. According to the above configuration, the cooling mechanisms 30 and 94 can discharge the heat released laterally from the battery unit 90 and the heat released upward from the electric motor 91 and the hydraulic pump P to the outside of the cover 70. it can.

Further, the swivel work machine 1 swivels with a lower traveling body 10 that supports the swivel base 2 around the swivel axis X and is capable of traveling, a battery unit 90, an electric motor 91, and a cover 70 that covers the hydraulic pump P. A support frame 65 provided on the table 2 and supporting the cover 70 is provided, and the rear portion of the support frame 65 is located behind the rear portion of the lower traveling body 10. According to the above configuration, by locating the support frame 65 behind the lower traveling body 10, the strength of the rear portion of the turning work machine 1 can be improved.

Further, the swivel work machine 1 is provided on the swivel table 2 and includes a protection mechanism 80 for protecting the driver's seat 8, and the protection mechanism 80 is supported by a support frame 65. According to the above configuration, the protection mechanism 80 is arranged at the rear part of the swivel base 2 and can be supported by the support frame 65 having a relatively high strength. As a result, the center of gravity can be moved to the rear side of the swivel base 2, and the protection mechanism 80 can be firmly supported.
Further, the swivel work machine 1 is mounted on a hydraulic oil tank T for storing hydraulic oil, a hydraulic device M driven by the hydraulic oil discharged by the hydraulic pump P, and a swivel base 2, and the hydraulic oil discharged by the hydraulic pump P. The control valves V1 to V8 for adjusting the hydraulic device M and controlling the hydraulic device M are provided, and the hydraulic oil tank T and the control valves V1 to V8 are arranged in front of the battery unit 90. According to the above configuration, the balance of the center of gravity in the front-rear direction can be properly maintained.

Further, the swivel work machine 1 is provided on the swivel table 2 and includes a protection mechanism 80 for protecting the driver's seat 8, and the center of gravity of the battery unit 90 is on one side of the center line L in the width direction of the swivel table 2. The protection mechanism 80 is arranged on one side with respect to the center line L and in front of the battery unit 90, and the control valves V1 to V8 are arranged on one side with respect to the center line L and below the protection mechanism 80, and are electrically operated. The motor 91 and the hydraulic pump P are arranged on the other side of the center line L and on the side of the battery unit 90, and the hydraulic oil tank T is on the other side of the center line L and in front of the electric motor 91 and the hydraulic pump P. It is located in. According to the above configuration, the position of the center of gravity can be lowered by arranging the control valves V1 to V8 below the protection mechanism 80. Further, the battery unit 90, the control valves V1 to V8, the electric motor 91, the hydraulic pump P, and the hydraulic oil tank T can be arranged even in a narrow space, and the balance of the center of gravity of the entire swivel table 2 can be properly balanced. Can be kept.

Further, the center of gravity of the battery unit 90 is arranged on one side of the center line L in the width direction of the swivel table 2, and the working device 20 is arranged on the other side of the center line L. According to the above configuration, the battery unit 90 and the working device 20 can maintain an appropriate balance of the center of gravity in the width direction.
Further, the swivel work machine 1 is a swivel table 2, a work device 20 provided on the swivel table 2, a battery unit 90, an electric motor 91 driven by electric power output from the battery unit 90, and a drive of the electric motor 91. It is provided with a hydraulic pump P for discharging hydraulic oil, and an erection frame 103 that supports one side surface and the other side surface of the battery unit 90 and supports the electrical component 92 above the battery unit 90. According to the above configuration, the position of the center of gravity can be lowered by arranging the battery unit 90 below the electrical component 92. Further, the erection frame 103 can firmly support the battery unit 90 by supporting one side surface and the other side surface of the battery unit 90.

Further, the erection frame 103 is erected on the upper portion of the swivel base 2 and is erected on the first erection portion 103L that supports one side surface of the battery unit 90, and is erected on the upper portion of the swivel base 2 in addition to the battery unit 90. It has a second standing portion 103R that supports the side surface, and a connecting stay 103U that connects the upper portion of the first standing portion 103L and the upper portion of the second standing portion 103R to support the electrical component 92. According to the above configuration, since the erection frame 103 supports the battery unit 90 by sandwiching one side surface and the other side surface of the battery unit 90, it is possible to suppress fluctuations in the relative position of the electrical component 92 with respect to the battery unit 90.

Further, the first upright portion 103L supports the battery unit 90 in the front-rear direction on one side in the width direction of the battery unit 90, and the second upright portion 103R supports the battery unit 90 in the width direction of the battery unit 90. On the side, the battery unit 90 is supported in the front-rear direction. According to the above configuration, since the first standing portion 103L and the second standing portion 103R support the battery unit 90 in the front-rear direction, the battery unit 90 can be firmly supported.

Further, the first upright portion 103L and the second upright portion 103R extend upward from the anti-sway portion 104 and are connected to the anti-sway portion 104 attached to the battery unit 90 in the front-rear direction of the battery unit 90. It has an extension portion 105 that supports the stay 103U and has a shorter length in the front-rear direction than the steady rest portion 104. According to the above configuration, the anti-sway portion 104 can firmly support the battery unit 90 against shaking in the width direction, and the extension portion 105 can support the electrical component 92 relatively compactly.

Further, an arrangement space E for arranging cables is formed between the battery unit 90 and the connecting stay 103U. According to the above configuration, since the connection stay 103U has little fluctuation in the relative position with respect to the battery unit 90, the cable arranged in the arrangement space E is arranged while suppressing damage due to vibration or the like. it can.
Further, the swivel work machine 1 includes a support substrate 100 that supports the battery unit 90, the electric motor 91, the hydraulic pump P, the first standing portion 103L, and the second standing portion 103R at the rear portion of the swivel base 2. The substrate 100 is attached to the swivel base 2 via a plurality of mounting devices 101. According to the above configuration, the battery unit 90, the electric motor 91, the hydraulic pump P, the first standing portion 103L, the second standing portion 103R, and the support substrate 100 are attached to the swivel base 2 as a single unit. Therefore, the battery unit 90, the electric motor 91, the hydraulic pump P, the first standing portion 103L, and the second standing portion 103R can be easily attached. Further, it is possible to prevent the vibration transmitted from the swivel base 2 from reaching the battery unit 90, the electric motor 91, and the hydraulic pump P.

Further, the plurality of mounting devices 101 are a front mounting device 101a arranged in a pair in the width direction on the front side of the support board 100, and a rear mounting device 101b arranged in a pair in the width direction on the rear side of the support board 100. Includes an intermediate mounting device 101c arranged between the rear mounting devices 101b on the rear side of the support substrate 100. According to the above configuration, since the plurality of mounting members are evenly arranged, the battery unit 90 supported by the support substrate 100, the electric motor 91, the hydraulic pump P, the first erection portion 103L, and the second erection The unit 103R can be firmly supported.

Further, the intermediate mounting device 101c is located behind the rear mounting device 101b. According to the above configuration, since the intermediate mounting device 101c is arranged at the rearmost position among the plurality of mounting devices 101, the intermediate mounting device 101c has the battery unit 90 and the electric motor 91 against shaking in the front-rear direction. , The hydraulic pump P, the first standing portion 103L, and the second standing portion 103R can be firmly supported.

Further, the battery unit 90 has a connector 90b that outputs electric power, and the connector 90b is provided at the front portion of the battery unit 90. According to the above configuration, by arranging the connector 90b in the front portion, it is possible to prevent the connector 90b from being damaged when an impact or the like is applied to the rear side of the battery unit 90.
Further, the electrical component 92 includes at least one of a junction box 92a and an inverter 92b connected to the battery unit 90. According to the above configuration, the junction box 92a and the inverter 92b connected to the battery unit 90 can be arranged in the vicinity of the battery unit 90 and can be firmly supported.

Further, the swivel work machine 1 is based on the swivel table 2, the work device 20 provided on the swivel table 2, the support board 100 provided on the swivel table 2, the battery unit 90, and the electric power output by the battery unit 90. The support board 100 includes a battery unit 90, which includes an electric motor 91 to be driven, a hydraulic pump P for discharging hydraulic oil by driving the electric motor 91, and a connecting portion 102 for connecting the electric motor 91 and the hydraulic pump P. It has a first mounting portion 100a to be mounted and a second mounting portion 100b on which the connecting portion 102 is mounted. According to the above configuration, the support substrate 100 can support the battery unit 90, the electric motor 91 connected to the connecting portion 102, and the hydraulic pump P. In other words, the battery unit 90, the electric motor 91, and the hydraulic pump P are one structure supported by the support substrate 100, and can be easily attached to the swivel base 2.

Further, the support board 100 is attached to the swivel base 2 via a plurality of mounting devices 101. According to the above configuration, it is possible to prevent the vibration transmitted from the swivel base 2 from reaching the battery unit 90, the electric motor 91, and the hydraulic pump P.
Further, the plurality of mounting devices 101 are a front mounting device 101a arranged in a pair in the width direction on the front side of the support board 100, and a rear mounting device 101b arranged in a pair in the width direction on the rear side of the support board 100. Includes an intermediate mounting device 101c arranged between the rear mounting devices 101b on the rear side of the support substrate 100. According to the above configuration, since the plurality of mounting members are arranged at equal positions, the battery unit 90, the electric motor 91, the hydraulic pump P, the first standing portion 103L, and the second standing portion 103L supported by the support substrate 100 are arranged. The upright portion 103R can be firmly supported.

Further, the intermediate mounting device 101c is located behind the rear mounting device 101b. According to the above configuration, by arranging the intermediate mounting device 101c at the rearmost position among the plurality of mounting devices 101, the battery unit 90, the electric motor 91, the hydraulic pump P, and the first standing device against shaking in the front-rear direction. The installation unit 103L and the second installation unit 103R can be firmly supported.

Further, the connecting portion 102 is a coupling that supports the electric motor 91 and the hydraulic pump P so that power is transmitted from the electric motor 91 to the hydraulic pump P. According to the above configuration, it is possible to suppress fluctuations in the relative positions of the electric motor 91 and the hydraulic pump P. Therefore, in the transmission of power from the electric motor 91 to the hydraulic pump P, the loss of power can be suppressed.
Further, the swivel work machine 1 is provided with a steady rest portion 104 which is erected on the upper part of the swivel base 2 and is attached to one side surface of the battery unit 90 between the connecting portion 102 and the battery unit 90. According to the above configuration, it is possible to prevent the battery unit 90 from coming into contact with the electric motor 91 and the hydraulic pump P due to shaking.

Further, the swivel work machine 1 has an anti-sway portion 104 that is erected on the upper portion of the swivel base 2 on the other side surface of the battery unit 90 and is attached to the other side surface of the battery unit 90 separately from the anti-sway portion 104. I have. According to the above configuration, since one side surface and the other side surface of the battery unit 90 are supported by the steady rest portion 104, it is possible to further suppress the battery unit 90 from shaking.

Further, the swivel work machine 1 is an oil cooler that cools the oil cooler 30 separately from the swivel base 2, the work device 20 provided on the swivel base 2, the radiator fan 94a for cooling the radiator 94, and the radiator fan 94a. It is equipped with a fan 30a. According to the above configuration, the radiator fan 94a and the oil cooler fan 30a can be driven individually.

Further, the swivel work machine 1 includes a control device 120 that controls the drive of the radiator fan 94a and the drive of the oil cooler fan 30a, and the control device 120 independently controls the radiator fan 94a and the oil cooler fan 30a. To do. According to the above configuration, the cooling of the radiator 94 and the cooling of the oil cooler 30 can be performed by different controls.
Further, the turning work machine 1 includes a water temperature detecting unit 126 for detecting the temperature of the cooling water and an oil temperature detecting unit 127 for detecting the temperature of the hydraulic oil, and the control device 120 is detected by the water temperature detecting unit 126. The drive of the radiator fan 94a is controlled based on the temperature of the cooling water, and the drive of the oil cooler fan 30a is controlled based on the temperature of the hydraulic oil detected by the oil temperature detection unit 127. According to the above configuration, the radiator fan 94a can be driven according to the temperature of the cooling water, and the oil cooler fan 30a can be driven according to the temperature of the hydraulic oil. Therefore, when one of the radiator 94 and the oil cooler 30 has a low temperature and does not require cooling, and the other temperature is high and requires cooling, cooling can be performed according to the respective temperatures. Further, since the radiator fan 94a and the oil cooler fan 30a can be controlled independently, it is possible to reduce the noise caused by driving the radiator fan 94a and the oil cooler fan 30a when cooling is not required.

Further, the control device 120 stops the driving of the oil cooler fan 30a when the temperature of the hydraulic oil detected by the oil temperature detecting unit 127 is less than a predetermined temperature. According to the above configuration, when the temperature of the hydraulic oil is low and it is necessary to warm up the hydraulic oil, the rotation of the fan of the oil cooler 30 is stopped to prevent the oil cooler 30 from interfering with the warming up. Warm-up can be promoted.
Further, the swivel work machine 1 includes a shroud 110 that surrounds and supports both the radiator fan 94a and the oil cooler fan 30a. According to the above configuration, the relative positions of the radiator fan 94a and the oil cooler fan 30a can be fixed, and interference between the radiator fan 94a and the oil cooler fan 30a and other members can be suppressed.

Further, the shroud 110 supports the radiator fan 94a and the oil cooler fan 30a so as to be aligned in the front-rear direction. According to the above configuration, since the warm air moves upward, by arranging the radiator fan 94a and the oil cooler fan 30a in the front-rear direction, it is possible to suppress the heat of one of the radiator 94 and the oil cooler 30 from reaching the other, which is efficient. Can be cooled.

Further, the shroud 110 extends from the front portion of the fixed portion 111 surrounding the radiator fan 94a and the oil cooler fan 30a to the rear and outward in the width direction, and the cooling air generated by driving the radiator fan 94a and the cooling air. It has a guide portion 112 that guides at least one of the cooling air generated by driving the oil cooler fan 30a. According to the above configuration, it is possible to prevent air from staying in the surroundings of the radiator fan 94a and the oil cooler fan 30a by guiding the cooling air by the guide unit 112. Thereby, the efficiency of heat removal of the radiator fan 94a and the oil cooler fan 30a can be improved.

Further, the turning work machine 1 includes a battery unit 90, an electric motor 91 driven by the electric power output from the battery unit 90, and a hydraulic pump P for discharging hydraulic oil by driving the electric motor 91. The 91 and the hydraulic pump P are arranged on the side of the battery unit 90, and the radiator fan 94a and the oil cooler fan 30a are arranged on the side of the battery unit 90 and above the hydraulic pump P and the electric motor 91. According to the above configuration, the radiator fan 94a and the oil cooler fan 30a can be located in the surplus space of the battery unit 90, the hydraulic pump P, and the electric motor 91.

Further, the swivel work machine 1 includes a battery unit 90, an electric motor 91, and a cover 70 that covers the hydraulic pump P, and the radiator fan 94a and the oil cooler fan 30a allow air to flow outward in the width direction from the space formed by the cover 70. Discharge. According to the above configuration, the radiator fan 94a and the oil cooler fan 30a discharge the heat released laterally from the battery unit 90 and the heat released upward from the electric motor 91 and the hydraulic pump P to the outside of the cover 70. it can.

The electric work machine (swivel work machine) 1 according to one aspect of the present invention includes an electric motor 91, a battery unit 90 that supplies power to the electric motor 91, and a hydraulic pump that is driven by the electric motor 91 to discharge hydraulic oil. A swivel work machine 1 including a P, a hydraulic device M driven by hydraulic oil, and a work device 20 operated by the hydraulic device M, and the battery unit 90 has a plurality of batteries 90a connected in parallel to each other. A control device 120 for setting an output battery that supplies power to the electric motor 91 from among a plurality of batteries 90a, and a power supply path 132 from the battery 90a to the electric motor 91 are connected and disconnected for each battery. The control device 120 includes a connection switching unit 131 for switching to and, and when the output battery switching process is performed, the control device 120 has a first process of shutting down each battery 90a and a battery 90a set as an output battery after the first process. The second process of making the connection state and the third process of starting the power supply from the battery 90a set as the output battery to the electric motor 91 after the second process are performed. According to the above configuration, it is possible to surely prevent an excessive current from flowing when the output battery is switched, and to extend the driving time of the swivel work machine 1 by the plurality of batteries 90a.

Further, the swivel work machine 1 includes a selector 122 that receives a selection instruction of the battery 90a as the output battery from the operator, and the control device 120 uses the battery 90a that is selected and instructed via the selector 122 as the output battery. Set. According to the above configuration, the operator can easily switch the battery 90a as the output battery by the selector 122.
Further, the swivel work machine 1 includes a capacity detection unit 123 that detects the remaining capacity of the plurality of batteries 90a, and the control device 120 selects the battery 90a that can be selected as the output battery by the selector 122, and the remaining capacity is the first threshold value. The battery 90a is limited to the above. According to the above configuration, it is possible to prevent the battery 90a having a remaining capacity of less than a predetermined value from being selected as the output battery, and to preferentially use the battery 90a having a sufficient remaining capacity.

Further, the turning work machine 1 includes a notification device 124 for notifying the decrease in the capacity of the battery 90a, and the control device 120 receives when the remaining capacity of the battery 90a selected as the output battery decreases to less than the first threshold value. The notification device 124 is made to perform notification prompting the switching of the output battery. According to the above configuration, it is possible to prevent the turning work machine 1 from stopping due to the remaining capacity of the output battery becoming zero during the work.

Further, in the control device 120, when the remaining capacity of the battery 90a selected as the output battery is reduced to less than the first threshold value, and there is no battery 90a among the other batteries 90a having the remaining capacity of the first threshold value or more. Is made to notify the notification device 124 to urge charging. According to the above configuration, the plurality of batteries 90a can be charged at an appropriate timing, and the work can be performed efficiently.

Further, when the remaining capacity of the battery 90a selected as the output battery drops to less than the second threshold value smaller than the first threshold value, the control device 120 causes the notification device 124 to give a warning notification of the remaining capacity running out. According to the above configuration, the operator can recognize that it is difficult to continue the work and it is necessary to take prompt action because the remaining capacity of the battery 90a is exhausted by the warning notification.

Further, the notification device 124 is any one or more of the display device 124a, the audio output device 124b, and the light emitting device 124c. According to the above configuration, the operator can recognize the remaining capacity of the battery 90a relatively easily and immediately by sight or hearing.
The control device 120 determines that the remaining capacity of the battery 90a selected as the output battery drops below the first threshold value, and there is a battery 90a among the other batteries 90a whose remaining capacity is equal to or higher than the first threshold value. The output battery is switched to one of the batteries 90a whose remaining capacity is equal to or greater than the first threshold value. According to the above configuration, the output battery can be switched to the battery 90a having a sufficient remaining capacity before the remaining capacity of the output battery becomes zero without any operation by the operator. As a result, it is possible to achieve both the extension of the driving time of the turning work machine 1 and the convenience.

Further, the control device 120 stops supplying electric power to the electric motor 91 due to insufficient remaining capacity of the battery 90a selected as the output battery, and supplies electric power to the electric motor 91 in another battery 90a. When there is a battery 90a having a remaining capacity capable of supplying power to the electric motor 91, the output battery is switched to one of the batteries 90a having a remaining capacity capable of supplying power to the electric motor 91. According to the above configuration, when the output battery stops supplying electric power to the electric motor 91 without any operation by an operator, another battery 90a can supply electric power to the electric motor 91. As a result, it is possible to achieve both the extension of the driving time of the turning work machine 1 and the convenience.

Further, a drive limiting device 47 for prohibiting or limiting the driving of the working device 20 is provided, and the control device 120 performs the process of switching the output battery after the driving of the working device 20 is prohibited or restricted by the drive limiting device 47. According to the above configuration, it is possible to prevent the power supply from the battery 90a from being interrupted while the working device 20 is being driven.
Further, the drive limiting device 47 prohibits or limits the driving of the hydraulic device M by shutting off the supply of hydraulic oil from the hydraulic pump P to the hydraulic device M. According to the above configuration, it is possible to reliably prevent the hydraulic device M from operating when the output battery is switched.

Further, the drive limiting device 47 prohibits or limits the driving of the hydraulic device M by restraining the operation of the operating member for the operator to operate the hydraulic device M. According to the above configuration, it is possible to reliably prevent the hydraulic device M from operating when the output battery is switched by the operator unexpectedly touching the operating member or inadvertently operating the operating member.
Further, an inverter 92b provided in the power supply path 132 and adjusting the power output to the electric motor 91 is provided, and the control device 120 connects the battery 90a selected as the output battery in the second process and the inverter 92b. To do. According to the above configuration, the connection between the battery 90a and the electric motor 91 is more reliably switched in order to connect to and disconnect from the battery 90a on the upstream side of the inverter 92b that adjusts the power output to the electric motor 91. be able to.

It includes a swivel table 2 on which a battery unit 90, an electric motor 91, and a work device 20 are mounted, and a swivel device (swivel motor) MT that swivels the swivel table 2. It is possible to realize a turning work machine 1 such as a backhoe that exhibits the above-mentioned excellent effects.
Further, the swivel work machine 1 includes a swivel table 2, a protection mechanism 80 provided on the swivel table 2 to protect the driver's seat 8, a work device 20 provided on the swivel table 2, a battery unit 90, and a battery unit. A hydraulic circuit having an electric motor 91 driven by electric power output by 90, a hydraulic pump P for discharging hydraulic oil by driving the electric motor 91, and a hydraulic device M driven by hydraulic oil discharged by the hydraulic pump P. And a heating device 130 that heats the inside of the protection mechanism 80 by the heat of the hydraulic oil. According to the above configuration, since the heating device 130 heats the inside of the protection mechanism 80 by the heat of the hydraulic oil, the power of the battery unit 90 is not consumed and energy saving can be achieved.

Further, the hydraulic circuit has an oil passage 40 through which hydraulic oil flows, and the heating device 130 is provided in the oil passage 40 and is inside the protection mechanism 80 by the heat of the hydraulic oil flowing through the oil passage 40. Perform heating. According to the above configuration, the heating device 130 can acquire the heat of the hydraulic oil through the oil passage 40. As a result, the heating device 130 can easily exchange heat.
Further, the oil passage 40 includes a first pipeline 41 for flowing the hydraulic oil discharged from the hydraulic pump P toward the hydraulic device M, and a second pipeline 42 for flowing the hydraulic oil discharged from the hydraulic device M. The heating device 130 is provided in either the first pipe line 41 or the second pipe line 42 in the hydraulic system circuit. According to the above configuration, since the heating device 130 is provided in the portion of the oil passage 40 through which the hydraulic oil having a relatively high temperature flows, the heating device 130 can efficiently exchange heat.

Further, the hydraulic circuit has an oil cooler 30 which is connected to the second pipeline 42 and drives the oil cooler fan 30a to cool the hydraulic oil flowing through the second pipeline 42, and the oil passage 40 has an oil cooler 30. It includes a third pipeline 44 that connects the oil cooler 30 and the hydraulic pump P and allows hydraulic oil to flow from the oil cooler 30 to the hydraulic pump P. According to the above configuration, the heating device 130 is provided in the first line 41 different from the third line 44 in which the oil cooler 30 is provided, and at least the heating device 130 is discharged from the hydraulic pump P. Since heat exchange is performed with the hydraulic oil or the hydraulic oil discharged from the hydraulic device M, heat exchange is not performed with the cooled hydraulic oil discharged from the oil cooler 30. Therefore, it is possible to prevent the heating device 130 from exchanging heat with the hydraulic oil having a relatively low temperature.

Further, the swivel work machine 1 includes a control device 120 for controlling the drive of the oil cooler fan 30a and an oil temperature detection unit 127 for detecting the temperature of the hydraulic oil, and the control device 120 includes an oil temperature detection unit 127 for the control device 120. If the detected oil temperature is less than a predetermined value, the drive of the oil cooler fan 30a is stopped. According to the above configuration, the oil cooler fan 30a stops driving when the temperature of the hydraulic oil is lower than a predetermined temperature, that is, when the temperature is relatively low, so that the oil cooler 30 prevents the oil cooler 30 from hindering warm-up. You can warm up quickly. Therefore, the heating device 130 can perform heating at an early stage by using the warmed hydraulic oil.

Further, the heating device 130 is provided around the first pipe line 41 or the second pipe line 42, and has a blower fan 130b that blows air toward the inside of the protection mechanism 80. According to the above configuration, the blower fan 130b can send out the surrounding air warmed by the hydraulic oil flowing inside the first pipe line 41 or the second pipe line 42 inside the protection mechanism 80. As a result, the heating device 130 can heat the inside of the protection mechanism 80 with a simple configuration.

Further, at least one of the first pipeline 41 and the second pipeline 42 is arranged by the protection mechanism 80. According to the above configuration, of the oil passages 40, at least one of the first pipeline 41 and the second pipeline 42, in which the temperature of the flowing hydraulic oil is relatively high, is arranged in the protection mechanism 80, so that heat exchange occurs. The warm air created can warm the inside of the protection mechanism 80 while maintaining the temperature.
Further, the working machine 1 is connected to the battery unit 90, the electric motor 91 driven by the power output by the battery unit 90, the battery unit 90 and the electric motor 91, and is an inverter that adjusts the power output to the electric motor 91. 92b, a hydraulic pump P driven by an electric motor 91 to discharge hydraulic oil, a hydraulic device M driven by the hydraulic oil discharged by the hydraulic pump P, and hydraulic oil output from the hydraulic pump P to the hydraulic device M. The control valves V1 to V8 to be adjusted, the operating device 5 to operate the hydraulic device M by adjusting the pilot oil acting on the control valves V1 to V8 to control the control valves V1 to V8, and the motor rotation of the electric motor 91. The control device 120 includes a control device 120 for controlling the number and a current detection unit (BMU123) for detecting the current value output from the battery unit 90 or the inverter 92b. The control device 120 has a current value detected by the BMU 123 or more than a predetermined value. If, the motor rotation speed of the electric motor 91 is set according to the current value that changes according to the operation of the operating device 5, and if the current value detected by the BMU 123 is less than a predetermined value, the motor of the electric motor 91. Set the rotation speed to a predetermined idling rotation speed. According to the above configuration, by detecting the current value output from the battery unit 90 or the inverter 92b, the load on the electric motor 91, that is, the driving state of the hydraulic pump P and the hydraulic device M can be detected. As a result, when the hydraulic device M is stopped or does not require a large amount of hydraulic oil, the motor rotation speed can be temporarily reduced. Therefore, with a relatively simple configuration of detecting the current of the electric power output from the battery unit 90 or the inverter 92b, the motor rotation speed can be automatically changed, and energy saving of the electric motor 91 can be realized.

Further, when the current value detected by the BMU 123 is less than the predetermined value, the control device 120 corresponds to the current value that changes according to the operation of the operating device 5 for a predetermined time after the current value becomes less than the predetermined value. The motor rotation speed of the electric motor 91 is set, and after a predetermined time elapses, the motor rotation speed of the electric motor 91 is set to a predetermined idling rotation speed. According to the above configuration, when the current value detected by the BMU 123 is less than a predetermined value, that is, when the hydraulic device M is stopped or does not require a large amount of hydraulic oil, the motor rotation speed of the electric motor 91 is maintained for a predetermined time. Therefore, the responsiveness of the hydraulic device M can be improved.

Further, the working machine 1 sets the range of the motor rotation speed of the electric motor 91 when the motor rotation speed of the electric motor 91 is set according to the current value that changes according to the operation of the operating device 5. The control device 120 includes the tool 5c, and when the current value detected by the BMU 123 is equal to or higher than a predetermined value, the motor rotation speed of the electric motor 91 is within a range according to the current value that changes according to the operation of the operating device 5. It is set and the idling rotation speed is set to a rotation speed lower than the lower limit value of the range of the motor rotation speed that can be set by using the rotation speed control tool 5c. According to the above configuration, when the hydraulic device M is driven and the load on the electric motor 91 is increased, the electric motor 91 is driven at a motor rotation speed arbitrarily set by the rotation speed operating tool 5c, and the hydraulic device is driven. When M is stopped or does not require a large amount of hydraulic oil, the rotation speed can be set lower than the range of the motor rotation speed set by the rotation speed operating tool 5c without any special operation. Therefore, the idling speed can be easily set without increasing the operation load of the operator.

Further, in the control device 120, when the current value detected by the BMU 123 is less than the predetermined value, the motor rotation speed of the electric motor 91 is set by the rotation speed operating tool 5c for a predetermined time after the current value becomes less than the predetermined value. The lower limit of the motor rotation speed in the above range is set, and after a predetermined time elapses, the motor rotation speed of the electric motor 91 is set to the idling rotation speed. According to the above configuration, when the hydraulic device M is driven and the load on the electric motor 91 is increased, the electric motor 91 is driven at a motor rotation speed arbitrarily set by the rotation speed operating tool 5c, and the hydraulic device is driven. When M is stopped or does not require a large amount of hydraulic oil, the control device 120 first sets the motor rotation speed to the lower limit value in the range set by the rotation speed operation tool 5c, and after a lapse of a predetermined time, the lower limit value is set. Set to a lower idling speed. As a result, further energy saving of the electric motor 91 can be realized by gradually reducing the motor rotation speed.

Further, the current detection unit is provided in the battery unit 90. According to the above configuration, energy saving of the electric motor 91 can be realized at a lower cost.
Further, the work machine 1 includes a swivel table 2 and a work device 20 mounted on the swivel table 2 and operated by the hydraulic device M. According to the above configuration, it is possible to realize a work machine (swivel work machine) 1 such as a backhoe that exhibits the above-mentioned excellent effects.

Although the present invention has been described above, it should be considered that the embodiments disclosed this time are exemplary in all respects and are not restrictive. The scope of the present invention is shown by the scope of claims rather than the above description, and it is intended to include all modifications within the meaning and scope equivalent to the scope of claims.
In the above-described embodiment, an example in which the present invention is applied to a turning work machine such as a backhoe has been described, but the application target of the present invention is not limited to this, for example, a wheel loader, a compact truck loader, a skid steer loader, and the like. It may be applied to other construction machines, and may be applied to agricultural machines such as tractors, combines, rice transplanters, and lawnmowers.

1 Swivel work machine 2 Swivel stand 20 Work equipment 30 Oil cooler 30a Oil cooler fan 70 Exterior cover (cover)
90 Battery unit 91 Electric motor 94 Radiator 94a Radiator fan 110 Shroud 111 Fixed part 112 Guide part 120 Control device 126 Water temperature detection part 127 Oil temperature detection part P Hydraulic pump

Claims (9)

With a swivel
The work device provided on the swivel table and
With a radiator fan that cools the radiator,
In addition to the radiator fan, an oil cooler fan that cools the oil cooler and
A swivel work machine equipped with. A control device for controlling the drive of the radiator fan and the drive of the oil cooler fan is provided.
The swivel work machine according to claim 1, wherein the control device controls the radiator fan and the oil cooler fan independently. A water temperature detector that detects the temperature of the cooling water,
An oil temperature detector that detects the temperature of hydraulic oil, and
With
The control device is
The drive of the radiator fan is controlled based on the temperature of the cooling water detected by the water temperature detection unit.
The swivel working machine according to claim 2, wherein the driving of the oil cooler fan is controlled based on the temperature of the hydraulic oil detected by the oil temperature detecting unit. The swivel working machine according to claim 3, wherein the control device stops driving the oil cooler fan when the temperature of the hydraulic oil detected by the oil temperature detecting unit is less than a predetermined temperature. The swivel working machine according to any one of claims 1 to 4, further comprising a shroud that surrounds and supports both the radiator fan and the oil cooler fan. The swivel work machine according to claim 5, wherein the shroud supports the radiator fan and the oil cooler fan so as to be lined up in the front-rear direction. The shroud
A fixed portion surrounding the radiator fan and the oil cooler fan,
A guide portion extending rearward and outward in the width direction from the front portion of the fixed portion to guide the cooling air generated by driving the radiator fan and the cooling air generated by driving the oil cooler fan.
The swivel work machine according to claim 5 or 6. Battery unit and
An electric motor driven by the electric power output from the battery unit and
A hydraulic pump that discharges hydraulic oil by driving the electric motor,
With
The electric motor and the hydraulic pump are arranged on the side of the battery unit.
The swivel work machine according to any one of claims 1 to 7, wherein the radiator fan and the oil cooler fan are arranged on the side of the battery unit and above the hydraulic pump and the electric motor. The radiator fan and the oil cooler fan provided with a cover covering the battery unit, the electric motor, and the hydraulic pump are any of claims 1 to 8 for discharging air outward in the width direction from the space formed by the cover. The turning work machine according to item 1.

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