JPH01290895A - Sprinkler for drilling machine - Google Patents

Abstract

PURPOSE:To prevent the flooding into a speed reducer by watertightly and rotatably inserting a rotary seal shaft communicated to an injection nozzle into a rotary seal casing and providing a drain waterway inlet in contact with the seal shaft. CONSTITUTION:A pressure waterway 4 in a carrier 3 is connected to a rotary seal casing 21 via an O-ring 22, a rotary seal shaft 5a is rotatably inserted into the opening tube section 21b of a vacant chamber 21a. The water hole 5b of the shaft 5a is communicated to an injection nozzle 10 via the waterway 24, the inlet of a drain waterway 25 is opened in contact with the shaft 5a. Pressure water is sprayed through the nozzle 10 while a drilling drum 6a is rotated via a solar gear 14 or the like in the carrier 3, on the other and the leakage water from the rotary contact face of the shaft is discharged through a drain port 25d via the waterway 25. The leakage water into the drum 6a of a speed reducer or the like can be prevented.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a water sprinkling device for a twin-drum excavator that cuts rocks with high efficiency by combining cutting with a bump and cutting with pressure water. In particular, the present invention relates to an improvement in a water sprinkling device for an excavator that can prevent drain water from entering the inside of a planetary reducer.

[Conventional technology]

In conventional twin-drum excavators that have rotating drums on both sides of the tip of the cutting boom, a water channel for supplying pressurized water to the injection nozzle is installed in a carrier fixed within the frame at the tip of the boom, and a water channel is installed in the rotating drum body. Japanese Patent Publication No. 60-27359 proposes an excavation head that requires a watertight rotary seal shaft to supply pressurized water to a large number of injection nozzles. In this system, a water supply pipe integrally provided on the shaft of the carrier is opened to the supply chamber, and the water supply pipe is sealed and continuous to the supply chamber of the rotatably supported drilling head body, and extends in the axial direction of the drilling head. An annular cavity is provided in the drilling head body and is connected to the feed chamber through a passageway. This passage opens into an annular gap communicating with the cooling water nozzle.

In addition, as shown in FIG. 4, in the conventional excavator, a cylindrical carrier 3 with a built-in planetary reducer 2 is fixed on both sides of the frame 1 at the tip of the boom, and a pressure water channel 4 is installed inside the carrier 3.
This waterway 4 is connected to a rotary seal shaft 5 fixed to the tip 3a of the carrier 3, and a waterway 8 and An injection nozzle 11 that injects pressurized water to the cutting edge of the excavation big 10 via the water channel 9 of the drum body.
is connected to.

In this excavator, when the knocking gear 12 in the frame 1 is rotated by the drive motor, the planetary gear IS meshing with the sun gear 14 of the planetary reducer 2 is rotated through the shaft 13 of the gear 12. , the internally toothed casing 16 meshing with the planetary gear 15 is driven at a reduced speed.

Therefore, the friction clutch 1 is attached to this internal tooth casing 16.
The drum main body 6, which is fitted and fixed by the inner tooth casing 16, is rotated together with the internal tooth casing 16. Therefore, the rotary seal shaft 5 fixed to the center of the carrier tip 3a and the drum cover 7 slide through the rotary seal (backing) 18, which is supplied to the injection nozzle 11 during excavation. When pressure water is supplied from the pressure water inlet 19 of the frame 1, water leaks from the rotating part.

Drain water from the rotary seal 18 accumulates in a gap 21 in the drum 6, and is finally drained from a drain outlet 2o formed in the drum cover 7.

[Problem to be solved by the invention]

However, in the above-mentioned twin-drum excavator equipped with rotating drums for excavation on both sides of the tip of the cutting boom, the water channel that supplies pressurized water to the injection nozzle always has a connection part with the rotating part, and water leaks from that part. is unavoidable.

Therefore, in the excavation head 6 described in the above publication, one end of the central pipe 29 fixed to the carrier 11 is connected to the central cavity 28.
and the other end is connected to the supply chamber 3 located within the insert 24.
0 and is hermetically guided into the insert 24 by a sealing body 31. However, since this insert body 24 rotates around this fixed water supply pipe 29 together with the excavation head 6, water leaks from that part, accumulates in a cavity 37, and is discharged from a passage 41 that opens to the outside of the drum. There was a problem that the drain water outlet opened on the surface could become blocked by sand and sand, and water could eventually enter the planetary gear part from the lubricating oil circuit, causing an accident.

Furthermore, in the drilling head described in this publication, both sides of the planetary gear device are fixed with bearings, and the diameter of the bearings is large.
This had the disadvantage that the internal tooth casing was large and the external shape of the drum was also large.

Furthermore, in the conventional twin drum excavator shown in FIG. 4, drain water leaking from the rotary seal 18 between the rotary seal shaft 5 and the drum cover 7 is discharged from the gap 21 to the drain outlet 20. Since the discharge port 20 is open to the outer surface of the drum cover, it is easily blocked by excavated earth and sand and has the disadvantage that water accumulates inside. Further, since the drum body 6 and the internal tooth casing 16 are fixed by a friction clutch 17, it takes time to disassemble and assemble the drum body 6, and furthermore, the drum body 6 has to be divided into two parts, which has the disadvantage of increasing costs.

The present invention was completed in view of the above circumstances, and uses a rotary seal casing with a simple structure to prevent water from leaking from the rotating part of the water channel, and allows a small amount of drain water to flow from the base of the carrier through the frame. It is an object of the present invention to provide a water sprinkling device for an excavator that can completely prevent drain water from entering the inside of a planetary reducer by being drained.

[Means to solve the problem]

In order to achieve the above object, the present invention fixes a carrier with a built-in planetary reducer inside the cutting drum at the tip of the cutting boom,
A twin-drum excavator equipped with a rotary drum that rotatably supports an internal toothed casing with the carrier, and is provided with a large number of picks and an injection nozzle for jetting pressurized water on the outer periphery of the internal toothed casing. In the water sprinkling device, a water channel for supplying pressurized water to the injection nozzle is provided inside the carrier, and the water channel is communicated with a rotary seal casing that is removably provided at the tip of the carrier, and the water is injected into the rotary seal casing. The rotary seal shaft communicating with the nozzle is watertightly and rotatably fitted, and the drain waterway inlet is provided in contact with the rotary seal shaft in the rotary seal casing, and the waterway and the rotary seal are The invention is characterized in that a rotary seal or a switchable rotary seal is provided at the connection part with the casing, and furthermore, a rotary seal or a switchable rotary seal is provided on both sides of the drain waterway inlet provided in contact with the rotary seal shaft, and one It is characterized in that a water channel passes through the carrier and its outlet is provided in the frame of the cutting boom.

Furthermore, the present invention is characterized in that the rotating drum main body is removably fixed to the internal tooth casing via a pin.

[Effect]

Next, the operation of the present invention will be explained.

The drive unit rotates the sun gear of the planetary gear reducer in the carrier fixed in the cutting drum at the tip of the cutting boom.
The internal toothed casing is rotated at a reduced speed via a planetary gear, and the excavation face is excavated by a large number of picks on an integrated excavation drum. At this time, pressurized water is injected from an injection nozzle at a position close to the cutting edge of the pick, and the pressure water is fed from the water channel in the carrier into the rotary seal shaft via the rotary seal casing, and then into the excavation drum body. is supplied to the injection nozzle through the water channel.

On the other hand, the inlet of the drain water channel is provided in contact with the rotary seal shaft and opens between the pair of rotary seals, and the drain water passes through the drain channel in the carrier, from its base to the inside of the frame, and flows into the cutting boom. It is discharged from the drain hole provided in the frame.

Further, since the excavation drum body is removably fixed to the carrier via a pin with a bolt, the drum body can be removed together with the rotary seal shaft by removing the bolt.

〔Example〕

Next, embodiments of the present invention will be described with reference to the drawings.

This embodiment is shown in FIGS. 1 to 3, and in the figures, the same or equivalent parts as in the conventional example shown in FIG.

One of the features of this embodiment is that the pressure water channel 4 provided in the carrier 3 is joined to the rotary seal casing 21 fixed to the carrier tip 3a via an O ring 22, and this rotary seal casing 21 is There is a vacant chamber 21a, which has a cylindrical shape with one end open, and the open cylindrical portion 21
b, a rotary seal shaft 5a fixed to the drum body 6a via a pair of backings 23 is rotatably fitted.

The water passage hole 5b of the rotary seal shaft 5a is provided so as to communicate with a water channel 24 in the drum body 6a, and the water channel 24 communicates with a number of injection nozzles that spray pressurized water near a number of pick cutting edges. has been done.

On the other hand, an inlet 25a of a drain water channel 25 provided inside the carrier is opened at an intermediate portion of the pair of backings 23 in contact with the rotary seal shaft 5a, and the drain water channel 25 is opened from an opening 25b at the base of the carrier 3 to the cutting boom. The water enters the water channel 25c in the frame 1 and is drained from the discharge port 25d.

To drive the drum 6a of the twin excavator P of this embodiment, a gear 12 is rotated by a drive device in the frame 1 (not shown), and the sun gear 14 of the planetary reducer 2 in the carrier 3 is rotated by this rotational force. This rotational force is applied to carrier 3.
The internal tooth 16a of the internal tooth casing 16 meshes with the tooth via the planetary gear 15 rotatably mounted on the internal tooth casing 16.
is transmitted to cause the internal tooth casing 16 to rotate at a reduced speed.

The inner periphery of the internally toothed casing 16 is rotatably supported by the carrier tip 3a by a bearing 26, while the drum main body 6a is integrally fitted to the outer periphery via a pin 27. Therefore, the drum main body 6a equipped with a large number of picks 10 is rotated at a reduced speed by the rotational driving force of the gear 12, and digging by the picks 10 is performed.

At this time, the pressurized water supplied to the injection nozzle 11 that injects high-pressure water to a position close to the cutting edge of the pick 1o is supplied from a pressure water source (not shown) to the pressure water inlet 19 of the frame 1, and flows through the water channel 28 of the frame 1. Channel 4 in carrier 3 through
and enters the empty chamber 21a of the rotary seal casing 21 fixed to the tip end 3a of the carrier 3.

Then, the pressurized water in this chamber 21a passes through the water passage hole 5b of the rotary seal shaft 5a, which is rotatably fitted into the open cylindrical portion 21b of the rotary seal casing 21, and is injected from the water channel 24 of the drum body 6a. Water is sent to the nozzle 11.

On the other hand, the open cylindrical portion 21b of the rotary seal casing 21
Drain water leaking from the rotating contact surface between the rotary seal shaft 5a and the rotary seal shaft 5a is collected by a pair of backings 23 provided on this contact surface.
From the inlet 25a of the drain waterway 25 opened in contact with the rotary seal shaft 5a between the drain waterway 25 in the carrier 3
The water passes through the opening 25b at the base of the carrier 3, passes through the water channel 25c in the frame 1 of the cutting boom, and is drained to the outside from the outlet 25d.

In this embodiment with such a structure, drain water does not flood into the inside of the planetary reducer 2 in the carrier 3, and since the drain water outlet is not opened on the outside of the drum body, there is no possibility that the drain water will enter the inside of the planetary reducer 2 in the carrier 3. There is no blockage.

Further, since the drum body 6a of this embodiment is fitted to the carrier 3 via the pin 27 and fixed with bolts 29, by removing the bolts 29, the drum body 6a
can be easily extracted from the carrier 3 together with the rotary seal shaft 5a, and can be easily divided and assembled.
Further, the rotary seal casing 21 fixed to the tip 3a of the carrier 3 by bolts 30 can also be easily removed and the backing 23 can be easily replaced.

Note that the shapes and structures of the drum body, internal tooth casing, rotary seal portion, etc. are not limited to those shown in the drawings, and may be applied to any shape that does not go against the spirit of the present invention. A switching type rotary seal and a switching valve may be used to inject water only to a limited area around the outer circumference of the drum, and in this case, a plurality of separate and independent water channels may be used.

〔Effect of the invention〕

According to the present invention, the rotary seal casing and the rotary seal shaft are provided in the carrier of the twin drum excavator in a mutually rotatable and watertight manner, and the drain waterway inlet is provided in contact with the rotary seal shaft. At this time, a small amount of drain water from the rotating sliding surface is discharged through the drain waterway, completely preventing water from entering the inside of the drum of the planetary reducer, etc., and the drain water provided in the carrier can be removed by cutting. It communicates with the inside of the boom frame, and since the discharge port is not provided on the outer circumferential surface of the drum, it will not be blocked by excavated earth and sand.

In addition, since the internal tooth casing and the rotating drum body are removably fixed via pins, the drum body can be easily removed together with the rotary seal shaft, allowing assembly and
It is easy to separate, and it is also easy to replace rotary seals, etc.

[Brief explanation of the drawing]

FIG. 1(a) is a sectional view of the excavation drum of this embodiment, and FIG. 1(b)
is an enlarged half-sectional view of the main parts, Figure 2 is a side view of the entire excavator,
FIG. 3 is a plan view of FIG. 2, and FIG. 4 is a sectional view of the conventional excavation drum. 1... Frame, 2... Planetary reducer, 3...
Carrier, 4...pressure waterway. 5.5a... Rotary seal shaft, 5b... Water hole, 6.6a... Drum body, 11... Injection nozzle, 14... Sun gear, 15... Planetary gear. 16... Internal tooth casing, 21... Rotary seal casing, 24...
Pressure waterway in the drum body, 25... Drain waterway. 25a... Drain waterway inlet, 25d... Outlet, 27... Pin, 28... Frame pressure waterway, 29... Bolt.

Claims (5)

[Claims] (1) A carrier with a built-in planetary reducer is fixed in the cutting drum at the tip of the cutting boom, the internal tooth casing is rotatably supported by the carrier, and a large number of picks and pressurized water are sprayed on the outer circumference of the internal tooth casing. In a water sprinkler system for a twin-drum excavator equipped with a rotating drum provided with an injection nozzle, a water channel for supplying pressurized water to the injection nozzle is provided inside the carrier, and the water channel is connected to the tip of the carrier. The rotary seal shaft connected to the injection nozzle is watertightly and rotatably inserted into the rotary seal casing, and the drain waterway inlet is connected to the rotary seal casing. A water sprinkler device for an excavator, characterized in that it is installed in contact with the rotary seal shaft of the excavator. (2) The water sprinkler for an excavator according to claim 1, characterized in that a rotary seal or a switchable rotary seal is provided inside the rotary seal casing. (3) A water sprinkler system for an excavator according to claim 1 or 2, characterized in that the drain waterway of the rotary seal or the switchable rotary seal passes through the carrier, and its discharge port is provided in the frame of the cutting boom. . (4) The water sprinkling device for an excavator according to any one of claims 1 to 3, characterized in that a rotary drum body is removably fixed to the internal tooth casing via a pin. (5) The water sprinkling device for an excavator according to claim 1, wherein the internal tooth casing is rotatable at the distal end portion of the carrier.