JP2017227337A - Shovel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a shovel capable of reducing noise generated by a swirl deceleration machine.SOLUTION: The shovel includes: an upper swirl body 3 mounted to a lower traveling body 1; a swirling motor 21 for driving the lower traveling body 3 so that the lower traveling body swirls; and a first swirl deceleration machine 24-1 connected to an output shaft of the swirling motor 21. A sun gear 42 and a planetary gear 44 of the first swirl deceleration machine 24-1 are constituted of a helical gear, while an internal gear 48 of the first swirl deceleration machine 24-1 is constituted of a helical internal gear.SELECTED DRAWING: Figure 6

Description

  The present invention relates to an excavator provided with a turning speed reducer.

  Conventionally, a turning motor, a first turning speed reducer connected to the output shaft of the turning motor, a second turning speed reducer connected to the output shaft of the first turning reducer, and the output of the second turning speed reducer There is known an excavator including a turning mechanism including a third turning speed reducer connected to a shaft and a swing circle connected to an output shaft of the third turning speed reducer (see, for example, Patent Document 1).

  In this shovel, when the turning electric motor rotates, the lubricating oil in the space in which the planetary gear mechanism constituting the first turning speed reducer is housed forms a mortar-shaped liquid surface by centrifugal force, and the first turning speed reducer It is discharged to the buffer tank through a pipe line connected to the upper part. Further, when the rotation of the turning electric motor stops, the lubricating oil discharged to the buffer tank passes through the throttle and the pipe connected to the lower portion of the first turning speed reducer due to gravity. It is gradually returned to the space.

  Therefore, in this excavator, when the turning operation is repeated intermittently, the rotational load of the gear is suppressed by maintaining a small amount of lubricating oil in the space, and the rotation of the gear during the turning operation is performed as desired. The time to rise to the number can be shortened.

JP 2008-232270 A

  However, the excavator described in Patent Document 1 does not consider noise countermeasures although energy efficiency and space saving are considered. For this reason, the excavator of Patent Document 1 cannot suppress fatigue and discomfort due to the noise of the operator in the cab. In addition, the noise causes a hindrance to not only the operator but also a worker working around the excavator.

  In view of the above points, an object of the present invention is to provide an excavator capable of reducing noise generated by a turning speed reducer.

  In order to achieve the above-mentioned object, an excavator according to an embodiment of the present invention includes an upper swing body mounted on a lower traveling body, a swing motor that drives the upper swing body to rotate, and an output of the swing motor. A first swivel reducer connected to a shaft, wherein the first swivel reducer is constituted by a planetary gear mechanism, and the sun gear and the planetary gear of the first swivel reducer are constituted by helical gears. Is done.

  With the above-described means, the present invention can provide an excavator capable of reducing noise generated by the turning speed reducer.

It is a side view of the shovel in which the turning drive device by one Embodiment of this invention is integrated. It is a block diagram which shows the structure of the drive system of the shovel shown in FIG. It is a block diagram which shows the structure of the turning drive device by one Embodiment of this invention. FIG. 4 is a top view of the turning drive device of FIG. 3. It is the VV sectional view taken on the line of FIG. FIG. 6 is a cross-sectional view taken along the line VI-VI in FIG. 4 showing a state of the turning drive device when the output shaft of the turning electric motor is stationary. FIG. 6 is a cross-sectional view taken along line VI-VI in FIG. 4, showing a state of the turning drive device when the output shaft of the turning electric motor is rotating. It is a side view of the sun gear and planetary gear in a 1st rotation reduction gear. It is sectional drawing which shows the structure of the turning drive device by another embodiment of this invention.

  First, an overall configuration of a shovel incorporating a turning drive device according to an embodiment of the present invention and a configuration of a drive system will be described. FIG. 1 is a side view showing an excavator incorporating a turning drive device according to an embodiment of the present invention. An excavator is an example of a construction machine, and a turning drive device according to an embodiment of the present invention can be incorporated in a construction machine having a mechanism for turning a turning body.

  An upper swing body 3 is mounted on a lower traveling body 1 of the shovel shown in FIG. A boom 4 is attached to the upper swing body 3. An arm 5 is attached to the tip of the boom 4, and a bucket 6 is attached to the tip of the arm 5. The boom 4, the arm 5, and the bucket 6 are hydraulically driven by a boom cylinder 7, an arm cylinder 8, and a bucket cylinder 9, respectively. The upper swing body 3 is provided with a cabin 10 and is mounted with a power source such as an engine.

  The excavator shown in FIG. 1 is an excavator having a power storage device that accumulates electric power supplied to the turning drive device. However, the present invention can be applied to, for example, an electrically driven excavator to which charging power is supplied from an external power source as long as the excavator adopts electric turning.

  FIG. 2 is a block diagram showing the configuration of the drive system of the shovel shown in FIG. In FIG. 2, the mechanical power system is indicated by a double line, the high-pressure hydraulic line is indicated by a thick solid line, the pilot line is indicated by a broken line, and the electric drive / control system is indicated by a thin solid line.

  An engine 11 as a mechanical drive unit and a motor generator 12 as an assist drive unit are respectively connected to two input shafts of a transmission 13. A main pump 14 and a pilot pump 15 are connected to the output shaft of the transmission 13 as hydraulic pumps. A control valve 17 is connected to the main pump 14 via a high pressure hydraulic line 16. An operation device 26 is connected to the pilot pump 15 via a pilot line 25.

  The control valve 17 is a control device that controls a hydraulic system in the hybrid excavator. The hydraulic motors 1A (for right) and 1B (for left), the boom cylinder 7, the arm cylinder 8, and the bucket cylinder 9 for the lower traveling body 1 are connected to the control valve 17 via a high-pressure hydraulic line.

  A power storage system (power storage device) 120 including a capacitor as a power storage is connected to the motor generator 12 via an inverter 18. The electric storage system 120 is connected to a turning electric motor 21 as an electric work element via an inverter 20. A resolver 22 and a turning speed reducer 24 are connected to the output shaft 21 b of the turning electric motor 21. A mechanical brake 23 is connected to the output shaft 24 </ b> A of the turning speed reducer 24. The turning electric motor 21, the resolver 22, the mechanical brake 23, and the turning speed reducer 24 constitute a turning drive device 40 as a load drive system. Here, the turning electric motor 21 corresponds to a turning electric motor for driving the upper turning body 3 to turn, and the mechanical brake 23 corresponds to a brake device that mechanically brakes the upper turning body 3.

  The operating device 26 includes a lever 26A, a lever 26B, and a pedal 26C. The lever 26A, the lever 26B, and the pedal 26C are connected to the control valve 17 and the pressure sensor 29 via hydraulic lines 27 and 28, respectively. The pressure sensor 29 is connected to a controller 30 that performs drive control of the electric system.

  The controller 30 is a control device as a main control unit that performs drive control of the hybrid excavator. The controller 30 is configured by an arithmetic processing unit including a CPU (Central Processing Unit) and an internal memory, and is realized by the CPU executing a drive control program stored in the internal memory.

  The controller 30 converts the signal supplied from the pressure sensor 29 into a speed command, and performs drive control of the turning electric motor 21. The signal supplied from the pressure sensor 29 corresponds to a signal indicating an operation amount when the operation device 26 is operated to turn the turning mechanism 2.

  The controller 30 performs operation control (switching between electric (assist) operation or power generation operation) of the motor generator 12 and also performs charge / discharge control of the capacitor by drivingly controlling the step-up / down converter of the power storage system 120. Based on the charging state of the capacitor, the operation state of the motor generator 12 (electric (assist) operation or power generation operation), and the operation state of the turning motor 21 (power running operation or regenerative operation), the controller 30 Switching control between the step-up / step-down operation of the step-up / step-down converter is performed, thereby performing charge / discharge control of the capacitor. The controller 30 also controls the amount of charging (charging current or charging power) of the capacitor as will be described later.

  In the work by the excavator having the above-described configuration, the turning electric motor 21 is driven by the electric power supplied via the inverter 20 in order to drive the upper turning body 3 to turn. The rotational force of the output shaft 21b of the turning electric motor 21 is transmitted to the output shaft 40A of the turning drive device 40 via the turning speed reducer 24 and the mechanical brake 23.

  FIG. 3 is a block diagram showing a configuration of the turning drive device 40 according to the embodiment of the present invention. As described above, the turning drive device 40 includes the turning electric motor 21 that is an electric motor as a drive source. A turning speed reducer 24 is connected to the output shaft side of the turning electric motor 21.

  Specifically, the turning speed reducer 24 has a three-stage configuration of a first turning speed reducer 24-1, a second turning speed reducer 24-2, and a third turning speed reducer 24-3. The first turning speed reducer 24-1, the second turning speed reducer 24-2, and the third turning speed reducer 24-3 are each constituted by a planetary speed reducer. More specifically, the first stage first turning speed reducer 24-1 is assembled to the turning electric motor 21. Further, the planetary carrier 46 serving as the output shaft of the first turning speed reducer 24-1 is provided with a disk brake as the mechanical brake 23. The second-stage second turning speed reducer 24-2 is assembled to the first turning speed reducer 24-1 with the mechanical brake 23 therebetween, and the third-stage third turning speed reducer 24-3 is It is assembled to the two-turn speed reducer 24-2. The output shaft of the third turning speed reducer 24-3 becomes the output shaft 40A of the turning drive device 40. Although not shown, the output shaft 40A of the turning drive device 40 is connected to the turning mechanism 2, and the turning mechanism 2 is driven by the rotational force of the output shaft 40A.

  Next, a specific configuration of the turning drive device 40 will be described with reference to FIGS. FIG. 4 is a top view of the turning drive device 40, and a broken line in FIG. 4 represents a hide line of main components of the first turning speed reducer 24-1. FIG. 5 is a cross-sectional view taken along line VV in FIG.

  FIG. 5 is a cross-sectional view of a portion of the turning drive device 40 that constitutes the first turning speed reducer 24-1 and the mechanical brake 23. In the present embodiment, the sun gear 42 of the planetary speed reducer constituting the first turning speed reducer 24-1 is fixed to the output shaft 21b of the turning electric motor 21. The sun gear 42 is engaged with each of the three planetary gears 44. Each of the planetary gears 44 is rotatably supported by a planetary carrier 46 that constitutes the output shaft of the first turning speed reducer 24-1 via a pin 44a. Each planetary gear 44 is engaged with an internal gear 48 formed on the inner surface of the first gear case 50.

  The first gear case 50 in which the internal gear 48 is formed is fixed to the end plate 21a of the turning electric motor 21, and cannot rotate by itself. On the other hand, the planetary carrier 46 constituting the output shaft is rotatably supported via a bearing 56 with respect to the second gear case 52 fixed to the first gear case 50.

  In the above-described first turning speed reducer 24-1, the lubricating oil for lubricating each gear is the end plate 21a, the output shaft 21b, the first gear case 50, the second gear case 52, and the planetary gear of the turning electric motor 21. The structure is hermetically sealed by the carrier 46.

  In the first turning speed reducer 24-1 configured as described above, when the output shaft 21b of the turning electric motor 21 rotates and the sun gear 42 rotates, the planetary gear 44 rotates (spins). The planetary gear 44 is engaged with an internal gear 48 formed on the inner surface of the first gear case 50, and the first gear case 50 formed with the internal gear 48 attempts to rotate by the rotational force of the planetary gear 44. However, since the first gear case 50 is fixed to the end plate 21a of the turning electric motor 21, it cannot rotate. As a result, the planet carrier 46 that is rotatably supported while supporting the planetary gear 44 rotates. The rotation of the output shaft 21b of the turning electric motor 21 is decelerated and output from the planetary carrier 46 by the gear action as described above.

  Next, the structure of the disc brake constituting the mechanical brake 23 will be described. The disc brake is formed between the second gear case 52 that is a fixed portion and the planet carrier 46 that is an output shaft. A brake disc 60 extends from the outer periphery of the planet carrier 46 toward the outer side in the rotational radial direction of the planet carrier 46. The brake disk 60 cannot be rotated with respect to the planet carrier 46, but is connected to the planet carrier 46 through a connection structure such as a spline connection in a state where it can move in the axial direction of the planet carrier 46.

  Brake plates 62 are arranged on both upper and lower sides of the brake disc 60. Although the brake plate 62 cannot rotate with respect to the second gear case 52 that is a fixed portion, the brake plate 62 can move in the axial direction of the planetary carrier 46 and is connected to the second gear case 52 via a connection structure such as a spline connection. It is connected to the inner surface side. On the upper brake plate 62, a piston 64 is arranged in a state of being movable in the axial direction of the planetary carrier 46. The piston 64 is pressed by the spring 66 and is always pressed against the upper brake plate 62. In the present embodiment, a coil spring is used as the spring 66, but a multistage disc spring that can obtain a high output with a small displacement can also be used.

  The brake plate 62 and the brake disc 60 are movable in the axial direction of the planet carrier 46. Therefore, when the upper brake plate 62 is pressed by the piston 64, the brake disc 60 is pressed between the upper and lower brake plates 62. The surfaces of the brake plate 62 and the brake disc 60 are covered with a film having a large friction coefficient. Then, when the brake disc 60 is sandwiched and pressed by the brake plate 62, a braking force for preventing the rotation of the brake disc 60 acts on the brake disc 60. The brake disc 60 is connected so as not to rotate with respect to the planet carrier 46. Therefore, the braking force acting on the brake disc 60 becomes the braking force applied to the planet carrier 46.

  A hydraulic space 68 capable of supplying hydraulic oil is formed between the piston 64 and the second gear case 52, and a brake release port 69 is connected to the hydraulic space 68. Further, a seal member 91 such as an O-ring is disposed between the piston 64 and the second gear case 52 to seal the hydraulic oil in the hydraulic space 68 from leaking out. When the hydraulic pressure is supplied from the pilot pump 15 to the hydraulic space 68 via the operating device 26, the hydraulic line 27a (see FIG. 2), and the brake release port 69, the piston 64 is pushed up by the hydraulic pressure and presses the brake plate 62. Disappears and the brake is released.

  In the first turning speed reducer 24-1 configured as described above, in the present embodiment, a ring-shaped recess is formed on the top surface of the first gear case 50, and a plurality of through holes are formed on the bottom surface of the ring-shaped recess. ing. The aforementioned spring 66 is inserted into each of the through holes. The lower end of each spring 66 protrudes from the through hole of the first gear case 50 and is in contact with the bottom surface of the hole formed in the piston 64. A spring pressing member 90 is fitted in the ring-shaped recess of the first gear case 50. The spring pressing member 90 is fastened and fixed to the first gear case 50 by a plurality of bolts 92.

  Before the spring pressing member 90 is fixed in the ring-shaped recess of the first gear case 50, the upper end of each spring 66 protrudes upward from the bottom surface of the ring-shaped recess. Therefore, when the spring pressing member 90 is fixed in the ring-shaped recess of the first gear case 50, each spring 66 is pressed and compressed by the spring pressing member 90. When the spring pressing member 90 is fixed in the ring-shaped recess of the first gear case 50, each spring 66 is sandwiched between the spring pressing member 90 and the piston 64 and compressed. The restoring force (spring force) of each spring 66 at this time is a force that presses the piston 64 (that is, the brake plate 62) against the brake disc 60, and a braking force that is applied to the planet carrier 46.

  In a state where the spring pressing member 90 is fixed in the ring-shaped recess of the first gear case 50, the entire spring pressing member 90 is accommodated in the ring-shaped recess. Therefore, the spring pressing member 90 does not protrude from the mating surface of the first gear case 50 that contacts the end plate 21a (also referred to as a flange) of the turning electric motor 21. Accordingly, only the mating surface of the first gear case 50 contacts the end plate 21 a of the turning electric motor 21. However, a seal member 93 such as an O-ring is disposed on the upper surface of the spring pressing member 90 and seals the lubricating oil for lubricating and cooling the planetary gear 44 in the first gear case 50 so as not to leak out. Further, a seal member 94 such as an O-ring is also disposed on the lower surface of the spring pressing member 90 to seal the lubricating oil filled in the portion in which the spring 66 is accommodated from leaking out. Similarly, a seal member 95 such as an O-ring is disposed between the first gear case 50 and the second gear case 52 to seal the lubricating oil filled in the portion in which the spring 66 is accommodated from leaking out. Yes.

  Next, transmission of the rotational driving force in the turning drive device 40 will be described with reference to FIGS. 6 and 7 are sectional views taken along line VI-VI in FIG. 4, and FIG. 6 shows the state of the turning drive device 40 when the output shaft 21b of the turning electric motor 21 is stationary. 7 shows the state of the turning drive device 40 when the output shaft 21b is rotating. FIG. 8 is a side view of the sun gear 42 and the planetary gear 44 in the first turning speed reducer 24-1.

  As shown in FIG. 6, the first turning speed reducer 24-1 is constituted by a planetary gear mechanism including a sun gear 42, a planetary gear 44, a planet carrier 46, and an internal gear 48. The second swivel reducer 24-2 includes a planetary gear mechanism including a sun gear 82, a planetary gear 84, a planet carrier 86, and an internal gear 88. Similarly, the third turning speed reducer 24-3 includes a planetary gear mechanism including the sun gear 102, the planetary gear 104, the planet carrier 106, and the internal gear 108.

  In the first turning speed reducer 24-1, the sun gear 42 is fixed to the output shaft 21 b of the turning electric motor 21 and is engaged with the planetary gear 44. The planetary gear 44 revolves while rotating between an internal gear 48 formed on the inner wall of the first gear case 50 and the sun gear 42. In the present embodiment, the first turning speed reducer 24-1 has three planetary gears 44. Each of the three planetary gears 44 rotates the planet carrier 46 by revolving while rotating. The planet carrier 46 constitutes the output shaft of the first turning speed reducer 24-1.

  In this embodiment, each of the sun gear 42 and the three planetary gears 44 is constituted by a helical gear (see FIG. 8), and the internal gear 48 is a helical internal gear (not shown). ). The helical gear includes a helical gear. This is because the helical gear has a configuration in which helical gears whose torsion directions are opposite are combined. The same applies to the helical internal gear. Each of the sun gear 42 and the three planetary gears 44 may be a gear other than a helical gear as long as it has a higher meshing ratio than a spur gear. The same applies to the internal gear 48. With this configuration, the turning drive device 40 can reduce noise and vibration generated by the turning speed reducer 24. This is because a plurality of teeth are always meshed and a smooth movement is realized.

  In the second turning speed reducer 24-2, the sun gear 82 is fixed to the planet carrier 46 as an output shaft of the first turning speed reducer 24-1 and engages with the planetary gear 84. The planetary gear 84 revolves while rotating between an internal gear 88 formed on the inner wall of the third gear case 54 and the sun gear 82. In the present embodiment, the second turning speed reducer 24-2 has three planetary gears 84. Each of the three planetary gears 84 is rotatably supported by the planet carrier 86 via a pin 84a, and rotates the planet carrier 86 by revolving while rotating. The planet carrier 86 constitutes the output shaft of the second turning speed reducer 24-2.

  In the present embodiment, each of the sun gear 82 and the three planetary gears 84 is constituted by a spur gear, and the internal gear 88 is constituted by an internal spur gear. This is because the gear constituting the second turning speed reducer 24-2 has a lower rotational speed and lower noise level and vibration level than the gear constituting the first turning speed reducer 24-1. However, the present invention is not limited to this configuration. For example, each of the sun gear 82 and the three planetary gears 84 may be constituted by a helical gear having a higher meshing rate than a spur gear. The same applies to the internal gear 88. With this configuration, the turning drive device 40 can further reduce noise and vibration generated by the turning speed reducer 24.

  In the third turning speed reducer 24-3, the sun gear 102 is fixed to the planet carrier 86 as the output shaft of the second turning speed reducer 24-2, and engages with the planetary gear 104. The planetary gear 104 revolves while rotating between an internal gear 108 formed on the inner wall of the third gear case 54 and the sun gear 102. In the present embodiment, the third turning speed reducer 24-3 has three planetary gears 104. Each of the three planetary gears 104 is rotatably supported by the planetary carrier 106 via a pin 104a, and rotates the planetary carrier 106 by revolving while rotating. The planet carrier 106 constitutes the output shaft 40A of the turning speed reducer 24.

  In the present embodiment, each of the sun gear 102 and the three planetary gears 104 is constituted by a spur gear, and the internal gear 108 is constituted by an internal spur gear. This is because the gear constituting the third turning speed reducer 24-3 has a lower rotational speed and lower noise level and vibration level than the gear constituting the second turning speed reducer 24-2. However, the present invention is not limited to this configuration. For example, each of the sun gear 102 and the three planetary gears 104 may be a helical gear having a higher meshing rate than the spur gear. The same applies to the internal gear 108. With this configuration, the turning drive device 40 can further reduce noise and vibration generated by the turning speed reducer 24.

  As described above, in the present embodiment, in the turning drive device 40, the first turning speed reducer 24-1 that is the high speed stage is configured by the helical gear, and the second turning speed reducer 24-2 that is the medium speed stage and The 3rd turning reduction gear which is a low speed stage is comprised with a spur gear. Therefore, the turning drive device 40 can be manufactured at a relatively low manufacturing cost while realizing a reduction in noise and vibration. Specifically, the turning drive device 40 reduces the noise and vibration by configuring the first turning speed reducer 24-1 that generates relatively large noise and vibration due to a relatively high rotational speed with a helical gear. Can be realized. And reduction of noise and vibration can reduce operator fatigue and discomfort. Further, the turning drive device 40 is configured by forming the second turning speed reducer 24-2 and the third turning speed reducer 24-3, which generate only relatively small noise and vibration due to a relatively low rotational speed, by spur gears. Compared with the case of using a helical gear, an increase in manufacturing cost can be suppressed. In order to obtain the same effect, the first turning speed reducer 24-1 which is a high speed stage and the second turning speed reducer 24-2 which is a medium speed stage are constituted by helical gears and are the first speed reduction stage which is a low speed stage. The three-turn speed reducer may be configured with a spur gear.

  With the above-described configuration, the turning drive device 40 increases the torque of the output shaft 40A by reducing the rotation speed of the output shaft 21b of the turning electric motor 21.

  Specifically, as shown in FIG. 7, the turning drive device 40 revolves clockwise while rotating the planetary gear 44 counterclockwise in response to the rotation of the output shaft 21b in the clockwise direction at high speed and low torque. The planet carrier 46 is rotated clockwise. Then, in response to the clockwise rotation of the planet carrier 46, the turning drive device 40 causes the planetary gear 84 to revolve clockwise while rotating counterclockwise, thereby rotating the planet carrier 86 clockwise. Further, in response to the clockwise rotation of the planet carrier 86, the turning drive device 40 revolves clockwise while rotating the planetary gear 104 counterclockwise to rotate the planet carrier 106, that is, the output shaft 40A clockwise. Rotate at low speed and high torque. The same applies to the case where the output shaft 21b rotates counterclockwise except that the rotation direction of each gear is reversed.

  Next, the movement of the lubricating oil in the turning drive device 40 will be described with reference to FIGS. 6 and 7.

  The turning drive device 40 has a space SP1 sealed by the output shaft 21b, the end plate 21a, the first gear case 50, the second gear case 52, and the planetary carrier 46. An oil seal (not shown) is attached to the output shaft 21b, and an oil seal 57 is attached to the planet carrier 46. The space SP1 accommodates the sun gear 42, the planetary gear 44, the planetary carrier 46, the brake disc 60, the brake plate 62, and the piston 64, and is filled with the lubricating oil LB1 represented by a fine dot pattern. The space SP1 is connected to the buffer tank 70 via a circulation path 72 including a first circulation path 72a and a second circulation path 72b.

  Further, the turning drive device 40 has a space SP <b> 2 that is sealed by the planet carrier 46, the second gear case 52, the third gear case 54, and the planet carrier 106. The planet carrier 106 is provided with an oil seal (not shown). The space SP2 accommodates the sun gears 82 and 102, the planetary gears 84 and 104, and the planetary carriers 86 and 106, and is filled with the lubricating oil LB2 represented by a coarse dot pattern. The lubricating oil LB2 is separated from the lubricating oil LB1 by the oil seal 57. The lubricating oil LB2 may be the same type of lubricating oil as the lubricating oil LB1, or may be a different type of lubricating oil. For example, the turning drive device 40 may use a high-rotation lubricant LB1 as a different type of lubricant from the low-rotation lubricant LB2.

  As shown in FIG. 6, when the output shaft 21b is stationary, the oil level L1 of the lubricating oil LB1 in the buffer tank 70 is higher than the bottom surface of the end plate 21a. That is, the space SP1 is filled with the lubricating oil LB1. The second circulation path 72b is connected to the buffer tank 70 at a position higher than the oil level L1. The connection position of the second circulation path 72b in the buffer tank 70 may be configured to be adjustable.

  On the other hand, as shown in FIG. 7, when the output shaft 21b is rotating, the lubricating oil LB1 in the space SP1 is formed in the lower part of the space SP1 by the centrifugal pump action by the rotating planetary carrier 46 and the brake disk 60. It is sent to the circulation path 72 through the inflow hole. Specifically, the lubricating oil LB1 in the space SP1 passes between the brake disk 60 and the brake plate 62, is sent to the first circulation path 72a, and is discharged to the buffer tank 70. 7 indicates the flow of the lubricating oil LB1.

  Further, the planetary carrier 46 is provided with an oil passage 74 so that the lubricating oil LB1 can be supplied from the radially inner side of the brake disc 60. With the oil passage 74, the turning drive device 40 can form a flow of the lubricating oil LB1 along the surface of the brake disc 60, and the brake disc 60 can be efficiently cooled. In the present embodiment, one brake disk 60 is disposed between the two brake plates 62, but a configuration using a plurality of brake disks 60 may be employed. Specifically, a configuration in which each of the three brake disks 60 is disposed between each of the four brake plates 62 may be employed. In this case, the turning drive device 40 can promote circulation of the lubricating oil LB1 existing in the space between the two adjacent brake disks 60 by the oil passage 74. Further, the oil passage 74 may extend near the rotation axis of the planet carrier 46 and may be connected to a part of the space SP1 below the sun gear 42 through one or a plurality of openings.

  Further, since a part of the lubricating oil LB1 is discharged to the buffer tank 70 through the first circulation path 72a, the space SP1 draws air in the buffer tank 70 through the second circulation path 72b. As a result, the lubricating oil LB1 in the space SP1 is agitated by the rotation of the output shaft 21b of the turning electric motor 21 to form a mortar-shaped oil surface L2. Note that both the first circulation path 72a and the second circulation path 72b are in a non-regulated state in which the flow of the lubricating oil is not regulated by a throttle or the like.

  Thereafter, the oil level of the lubricating oil LB1 in the buffer tank 70 reaches the level L3 above the second circulation path 72b by the lubricating oil LB1 discharged from the space SP1. In this case, the lubricating oil LB1 in the buffer tank 70 flows into the space SP1 through the second circulation path 72b and the outflow hole formed in the upper part of the space SP1. The outflow hole is formed above or inside the internal gear 48, for example. The lubricating oil LB1 flowing into the space SP1 from the buffer tank 70 lubricates the internal gear 48, the planetary gear 44, the sun gear 42, and the planet carrier 46, and then lubricates the space SP1 that forms the mortar-shaped oil surface L2. Join oil LB1.

  The buffer tank 70 is provided with a fan as an example of heat exchange means 76 for cooling the lubricating oil LB1 in the buffer tank 70. Therefore, the temperature of the lubricating oil LB1 flowing from the buffer tank 70 into the space SP1 is lower than the temperature of the lubricating oil LB1 discharged from the space SP1 to the buffer tank 70. As a result, the lubricating oil LB1 flowing into the space SP1 from the buffer tank 70 can cool the internal gear 48, the planetary gear 44, the sun gear 42, the planet carrier 46, and the lubricating oil LB1 in the space SP1. The heat exchanging means 76 may be a means other than a fan, such as a heat radiating fin formed on the outer surface of the buffer tank 70. Further, since the buffer tank 70 itself can serve as a heat exchange means, the additional heat exchange means 76 may be omitted. Further, the buffer tank 70 has a zigzag flow so that the lubricating oil LB1 flowing in from the first circulation path 72a is reliably cooled in the buffer tank 70 and then returned to the space SP1 through the second circulation path 72b. You may make it provide a path | route inside. The buffer tank 70 may include a breather device that can adjust the internal pressure.

  Thereafter, when the rotation of the output shaft 21b stops, the lubricating oil LB1 in the space SP1 that has formed the mortar-shaped oil surface L2 forms a horizontal oil surface in the space SP1. Then, the lubricating oil LB1 in the buffer tank 70 loses its centrifugal pump action due to the rotation of the planet carrier 46 and the brake disk 60, so the first circulation path 72a and the second circulation oil LB1 until the oil level becomes lower than the level L3. It returns to space SP1 through the circulation path 72b. Further, the lubricating oil LB1 in the buffer tank 70 passes through the first circulation path 72a until the oil level reaches the level L1 (see FIG. 6) after the oil level becomes lower than the level L3. Return to space SP1. When the oil level of the lubricating oil LB1 in the buffer tank 70 reaches the level L1, the space SP1 is filled with the lubricating oil LB1, and the sun gear 42, the planetary gear 44, the planetary carrier 46, and the internal gear 48 are lubricated. It will be in the state completely immersed in oil LB1.

  In this way, the turning drive device 40 reduces the amount of the lubricating oil LB1 in the space SP1 by discharging the lubricating oil LB1 in the space SP1 to the buffer tank 70 when the output shaft 21b of the turning electric motor 21 rotates. . As a result, the turning drive device 40 can reduce the stirring resistance of the lubricating oil LB1 and reduce the rotational loads of the output shaft 21b, the sun gear 42, the planetary gear 44, and the planet carrier 46.

  Further, the turning drive device 40 discharges the lubricating oil LB1 at the lower part of the space SP1 to the buffer tank 70 by the centrifugal pump action by the rotation of the planetary carrier 46 and the brake disk 60. Then, the turning drive device 40 returns the lubricating oil LB1 in the buffer tank 70 to the upper part of the space SP1. As a result, the turning drive device 40 can reliably lubricate the sun gear 42, the planetary gear 44, the planetary carrier 46, and the internal gear 48 without excessively reducing the amount of the lubricating oil LB1 in the space SP1.

  Further, the turning drive device 40 cools the lubricating oil LB1 in the buffer tank 70 by the heat exchange means 76. As a result, the turning drive device 40 can cool the lubricating oil LB1 heated by the rotation of each gear in the space SP1 by the buffer tank 70 and then return it to the space SP1, and overheat the gears and the lubricating oil LB1. Can be suppressed.

  On the other hand, the lubricating oil LB2 in the space SP2 does not circulate in the space SP2 from the lower part to the upper part even when the output shaft 21b of the turning electric motor 21 rotates. This is because the rotational speed of each gear is lower than the rotational speed of the output shaft 21b of the turning electric motor 21, and therefore the necessity for reducing the rotational load of each gear and cooling the lubricating oil LB2 is relatively low. However, the present invention is not limited to this configuration. For example, the turning drive device 40 is provided with another buffer connected to the space SP2 similar to the buffer tank 70 in order to circulate the lubricating oil LB2 in the space SP2 and to suppress overheating of the lubricating oil LB2. A tank may be provided.

  Next, a configuration example of a turning drive device 40X according to another embodiment of the present invention will be described with reference to FIG. 9 is a cross-sectional view showing a state when the output shaft 21b of the turning electric motor 21 is rotating, and corresponds to FIG.

  The turning drive device 40X is different from the turning drive device 40 in that a circulation path 72M is provided instead of the combination of the buffer tank 70, the first circulation path 72a, and the second circulation path 72b, but is common in other points. Therefore, the differences will be described in detail while omitting the description of the common points.

  The circulation path 72M is an oil path formed in each of the first gear case 50 and the second gear case 52, and fills the lubricating oil LB1 even when the output shaft 21b of the turning electric motor 21 is stationary. Has been. That is, the space SP1 and the circulation path 72M are always filled with the lubricating oil LB1.

  As shown in FIG. 9, when the output shaft 21b is rotating, the lubricating oil LB1 in the space SP1 is formed in the lower part in the space SP1 by the centrifugal pump action by the rotating planetary carrier 46 and the brake disk 60. It is sent to the circulation path 72M through the made inflow hole. Specifically, the lubricating oil LB1 in the space SP1 passes through between the brake disk 60 and the brake plate 62 and is sent to the circulation path 72M. The lubricating oil LB1 fed into the circulation path 72M is pushed by the newly fed lubricating oil LB1 and is sent vertically upward while being cooled by the heat exchange means 76. Thereafter, the lubricating oil LB1 moving vertically upward in the circulation path 72M is pushed by the newly fed lubricating oil LB1, and toward the outflow hole formed in the upper portion of the space SP1, that is, in the direction approaching the rotation axis. Sent. At this time, the lubricating oil LB1 in the space SP1 is about to be separated from the rotating shaft by centrifugal force. Therefore, the lubricating oil LB1 that moves in the circulation path 72M in the direction approaching the rotating shaft pushes the lubricating oil LB1 that is about to move away from the rotating shaft back in the direction approaching the rotating shaft, and is formed in the upper portion of the space SP1. Is pushed out into the space SP1. 9 represents the flow of the lubricating oil LB1 that moves in the circulation path 72M.

  Thus, the space SP1 receives the lubricating oil LB1 from the circulating path 72M by the amount of the lubricating oil LB1 fed into the circulating path 72M. Therefore, the space SP1 is always filled with the lubricating oil LB1 and is stirred by the rotation of the output shaft 21b of the turning electric motor 21, but does not form a mortar-shaped oil surface.

  Thereafter, when the rotation of the output shaft 21b stops, the lubricating oil LB1 in the circulation path 72M stops its movement. Also in this case, the state in which the space SP1 is filled with the lubricating oil LB1 does not change.

  In this way, the turning drive device 40X circulates the lubricating oil LB1 in the space SP1 from below to above when the output shaft 21b of the turning electric motor 21 rotates. Specifically, the turning drive device 40 has a circulation path 72M that connects the inflow hole in the lower part of the space SP1 and the outflow hole in the upper part of the space SP1 by a centrifugal pump action by the rotation of the planetary carrier 46 and the brake disk 60. Used to circulate the lubricating oil LB1. Further, the turning drive device 40X cools the lubricating oil LB1 in the circulation path 72M by the heat exchange means 76. As a result, the turning drive device 40X can cool the lubricating oil LB1 heated by the rotation of each gear in the space SP1 in the circulation path 72M and then return the lubricating oil LB1 to the space SP1. Overheating can be suppressed.

  On the other hand, the lubricating oil LB2 in the space SP2 does not circulate in the space SP2 from the lower part to the upper part even when the output shaft 21b of the turning electric motor 21 rotates. This is because the rotational speed of each gear is lower than the rotational speed of the output shaft 21b of the turning electric motor 21, and therefore the necessity for reducing the rotational load of each gear and cooling the lubricating oil LB2 is relatively low. However, the present invention is not limited to this configuration. For example, the turning drive device 40X has another circulation connected to the space SP2 similar to the circulation path 72M in order to circulate the lubricating oil LB2 in the space SP2 and to suppress overheating of the lubricating oil LB2. A road may be provided.

  Further, the turning drive device 40X is configured to always fill the space SP1 with the lubricating oil LB1 regardless of whether the output shaft 21b of the turning electric motor 21 is rotating or stationary. Therefore, the turning drive device 40X can reliably lubricate the sun gear 42, the planetary gear 44, the planetary carrier 46, and the internal gear 48 regardless of the inclination of the excavator body.

  The preferred embodiments of the present invention have been described in detail above, but the present invention is not limited to the above-described embodiments, and various modifications and substitutions can be made to the above-described embodiments without departing from the scope of the present invention. Can be added.

  For example, in the above-described embodiment, the turning drive device 40 includes a set of circulation paths 72 (a combination of the first circulation path 72a and the second circulation path 72b) connected to one buffer tank 70. However, the present invention is not limited to this configuration. For example, the turning drive device 40 may include a plurality of sets of circulation paths connected to one buffer tank, or may include a plurality of sets of circulation paths connected to a plurality of buffer tanks. Further, the turning drive device 40 may include one second circulation path 72b corresponding to the plurality of first circulation paths 72a, and may include a plurality of second circulation paths 72b corresponding to one first circulation path 72a. You may have.

  In the above-described embodiment, the turning drive device 40X includes one circulation path 72M, but may include a plurality of circulation paths 72M.

  In the above-described embodiment, the turning drive device 40 includes the buffer tank 70 and the circulation path 72 connected to the space SP1, but additionally or alternatively, the buffer tank 70 and the circulation connected to the space SP2. A path 72 may be provided. Similarly, the turning drive device 40X includes the circulation path 72M connected to the space SP1, but may additionally or alternatively include the circulation path 72M connected to the space SP2.

  Further, in the swivel drive devices 40 and 40X, the circulation paths 72 and 72M are formed inside the first gear case 50 and the second gear case 52, respectively, but the inner surfaces of the first gear case 50 and the second gear case 52, respectively. A circulation groove may be included.

  Further, in the turning drive devices 40 and 40X, the space for accommodating the spring 66, the brake release port 69, and the circulation paths 72 and 72M are formed offset in the circumferential direction, respectively. However, the present invention is not limited to this configuration. For example, at least two of the space for accommodating the spring 66, the brake release port 69, and the circulation paths 72 and 72M may be formed at the same circumferential position.

  Further, in the swivel drive devices 40 and 40X, the outflow holes of the circulation paths 72 and 72M are formed on the inner wall of the first gear case 50 so that the lubricating oil LB1 enters the upper part of the space SP1 from the side. However, the present invention is not limited to this configuration. For example, the circulation path may be formed in the end plate 21a so that the lubricating oil LB1 enters the space SP1 from above, and the outflow hole of the circulation path may be formed in the bottom surface of the end plate 21a. May be formed on the bottom surface of the end plate 21a. In this case, for example, the turning drive devices 40 and 40X can directly supply the lubricating oil LB1 to the sun gear 42 exposed from the oil surface L2 when the output shaft 21b of the turning electric motor 21 is rotating.

  Further, the turning drive devices 40 and 40X are configured such that the space SP1 and the space SP2 are separated by the oil seal 57, and the lubricating oil LB1 and the lubricating oil LB2 are not mixed. However, the present invention is not limited to this configuration. For example, each gear in the space SP1 and each gear in the space SP2 may be lubricated with the same type of lubricating oil. Further, the space SP2 may be divided into a space that accommodates the planetary gear mechanism that constitutes the second turning speed reducer 24-2 and a space that accommodates the planetary gear mechanism that constitutes the third turning speed reducer 24-3. Good. The lubricating oil that lubricates the planetary gear mechanism that constitutes the second turning speed reducer 24-2 is separated from the lubricating oil that lubricates the planetary gear mechanism that constitutes the third turning speed reducer 24-3, and separate lubricating oils are used. This is to make it available.

  In the turning drive devices 40 and 40X, the planet carrier 46 of the first turning speed reducer 24-1 is used as the output shaft of the first turning speed reducer 24-1 and the input shaft of the second turning speed reducer 24-2. It is comprised and the sun gear 82 of the 2nd turning speed reducer 24-2 is fixed. However, the present invention is not limited to this configuration. For example, the output shaft of the first turning speed reducer 24-1 may be detachably connected to the input shaft of the second turning speed reducer 24-2. That is, the first turning speed reducer 24-1 may be configured to be removable from the remaining portion of the turning speed reducer 24. In this case, the space SP2 is sealed by a top plate (not shown) serving as a substitute for the second gear case, the input shaft of the second turning speed reducer 24-2, the third gear case 54, and the planet carrier 106. An oil seal (not shown) is attached to the input shaft of the second turning speed reducer 24-2 and the planetary carrier 106. With this configuration, the turning drive devices 40 and 40X can combine various first turning speed reducers with different specifications with the remaining portion of the turning speed reduction 24, and adapt characteristics such as the reduction ratio to various applications. it can.

  DESCRIPTION OF SYMBOLS 1 ... Lower traveling body 1A, 1B ... Hydraulic motor 2 ... Turning mechanism 3 ... Upper turning body 4 ... Boom 5 ... Arm 6 ... Bucket 7 ... Boom cylinder 8 ... arm cylinder 9 ... bucket cylinder 10 ... cabin 11 ... engine 12 ... motor generator 13 ... transmission 14 ... main pump 15 ... pilot pump 16 ... High pressure hydraulic line 17 ... Control valve 18, 20 ... Inverter 21 ... Rotating motor 21a ... End plate 21b ... Output shaft 22 ... Resolver 23 ... Mechanical brake 24 ... Turning reducer 24-1 ... First turning reducer 24-2 ... Second turning reducer 24-3 ... Third turning reducer 25 ... Pilot light 26 ... Operating device 26A, 26B ... Lever 26C ... Pedal 27, 27a, 28 ... Hydraulic line 29 ... Pressure sensor 30 ... Controller 40, 40X ... Swivel drive device 40A .... Output shafts 42, 82, 102 ... Sun gears 44, 84, 104 ... Planetary gears 44a, 84a, 104a ... Pins 46, 86, 106 ... Planetary carriers 48, 88, 108 ... Internal gear 50 ... 1st gear case 52 ... 2nd gear case 54 ... 3rd gear case 56 ... Bearing 57 ... Oil seal 60 ... Brake disc 62 ... Brake plate 64 ..Piston 66 ... Spring 68 ... Hydraulic space 69 ... Brake release port 70 ... Buffer tank 72 72M ... circulation path 72a ... first circulation path 72b ... second circulation path 74 ... oil path 76 ... heat exchange means 90 ... spring holding member 91, 93, 94, 95 ..Seal member 92 ... Bolt 120 ... Power storage system

Claims (6)

An upper swing body mounted on the lower traveling body,
A turning electric motor for turning the upper turning body;
A first turning speed reducer connected to the output shaft of the turning electric motor,
The first swivel reducer is composed of a planetary gear mechanism,
The sun gear and the planetary gear of the first swivel reducer are composed of helical gears,
Excavator. The internal gear of the first swivel reducer is composed of a helical internal gear.
The excavator according to claim 1. A second turning speed reducer connected to the output shaft of the first turning speed reducer;
The second swivel reducer is composed of a planetary gear mechanism,
The shovel according to claim 1 or 2. The second swivel reducer is constituted by a spur gear.
The excavator according to any one of claims 1 to 3. A circulation path for circulating lubricating oil for lubricating the first turning speed reducer from a lower part of the first turning speed reducer to an upper part of the first turning speed reducer;
The lubricating oil circulating in the circulation path passes through a space in which a brake is disposed;
The excavator according to any one of claims 1 to 4. A disc brake for braking the rotation of the first turning speed reducer;
The brake disc of the disc brake is attached to the planetary carrier of the first swivel reducer,
The lubricating oil flows from a radially inner side to a radially outer side along a surface of the brake disc through a hole formed in the planet carrier.
The excavator according to claim 5.

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