The present invention generally relates to hydraulic rotators for use on articulated-boom excavating equipment, or the like. More particularly, it relates to a motor-driven rotator assembly having concentric tubular oil distribution channels and further preferably comprising a hydraulic pressure relief valve to decrease a low pressure side of the motor.
Mobile excavating machines are commonplace in commercial industries. These machines often have hydraulically-driven rotator assemblies for rotation of manipulating or grappling equipment secured to the end of the articulated booms. These rotator assemblies have oil pressure lines that must be displaced with the rotator assembly, as the grappling equipment is swivelled. These rotator assemblies also are capable of continuous rotation about their main shaft. However, a disadvantage of some of these rotator assemblies is that they have heavy mechanical parts.
With most prior art rotator assemblies, because the grappling equipment is connected directly to the rotator assembly, the rotor assembly parts are subjected to torque and different axial or radial loads. These loads induce stress on the collector and lead to wearing of bearings, seals and couplings. The collector eventually also can develop hydraulic fluid leaks, thereby necessitating repairs. In certain cases, replacement of the entire rotator assembly and grappling equipment is required, which increases maintenance costs.
US 2004/0168568 describes an example of a rotator found in prior art. In such a rotator design, the lower end of the load-bearing shaft is provided with annular oil distribution channels which are in communication with oil pressure line connectors, which extend through the collector jacket. These oil distribution channels communicate with supply channels which are bored into the load-bearing shaft, and oil is fed to the supply channels through oil line connectors, which connect to the oil pressure lines. However, this design is still relatively bulky in size.
U.S. Pat. No. 6,266,901 discloses another example of a rotator found in the prior art. In this case, the oil supply channels are placed in proximity of each other in symmetrical configurations within the rotator structure. Unfortunately, this design also results in a relatively bulky design which causes stresses to the rotator structure due to the rotative movement of the internal components such as the oil supply channels which have an offset with respect to the center axis of the rotator.
Thus, there is still presently a need for an improved rotator design that is small in size and incurs lower maintenance costs due to improved rotative movement of its internal components.
Additionally, there is a need for an improved hydraulic valve design. If an operator wishes to immobilise an object being held with the grappling equipment, the operator must control valves that feed the rotator hydraulic line. The rotator hydraulic line is thus theoretically isolated from the other hydraulic lines. In certain cases, the rotator axis might be immobilised in a horizontal configuration. In this configuration, the load might not be aligned with the rotator axis and consequently, the motor must act to maintain the load in place. However, internal leaks in the hydraulic system result in that a small quantity of oil is sent to the rotator hydraulic line. In this situation, the hydraulic pressure increases on both sides of the motor. This condition is problematic for the motor. It is much more efficient to maintain a load in place if the low pressure side of the motor is drained towards the hydraulic reservoir. A pressure relief valve is therefore required to decrease pressure on the low-pressure side of the motor.
Prior art relief valves include hot oil shuttle valves. In these types of valves, the flow paths are connected or isolated by means of a movable sliding member. However, these valves are susceptible to internal oil leaks which decrease the capacity of the motor to maintain a load in place.
Consequently, there is still presently a need for a new type of hydraulic valve, which can decrease this pressure surrounding the motor when the rotator is immobilising an object being manipulated.
An object of the present invention is to propose a hydraulic rotator that satisfies at least one above-mentioned need.
According to the present invention, that object is achieved with a rotator having concentrically positioned tubular oil distribution channels located within the load-bearing shaft and drive assembly.
More particularly, the present invention provides a rotator assembly for rotating and actuating an operable attachment. The rotator assembly comprises:
In accordance with a preferred aspect of the invention, the rotator assembly comprises a collector housed in the central recess of the load-bearing shaft, the collector having a body with a central alcove in a bottom end thereof, said alcove housing the upper end portion of the first tube and having an upper opening in registry with the bottom end of said first channel of the load-bearing shaft and with the top end of the first tube, said body further having a passage with an upper end in registry with the bottom end of said second channel of the load-bearing shaft and a lower end emerging in said central alcove and being in fluid communication with the upper end of said annular passage to provide said second flow path.
The invention also provides a rotator assembly linking a boom member to an operable attachment, the rotator assembly comprising:
In accordance with another preferred aspect of the invention, the actuator fixed to the load-bearing shaft is a motor comprising a hydraulic valve, which can decrease the pressure surrounding the motor used as the actuator for the rotator. This valve reduces oil leaks between the high-pressure line of the motor and a reservoir. On the other hand, the low-pressure line of the motor communicates with the reservoir and the valve helps decrease pressure on the low-pressure side of the motor.
More particularly, in accordance with a preferred embodiment, the actuator is a motor which comprises a hydraulic valve to direct fluid flow from two hydraulic lines to a reservoir. The hydraulic valve comprises:
A non-restrictive description of a preferred embodiment of the invention will now be given with reference to the appended drawings.
Referring to
In general, the rotator can be installed on the end of a machine having articulated booms. It is used to make the operable attachment 92 turn a continuous 360 degrees if necessary. The hydraulic oil pressure lines 96 that feed the actuating cylinders 98 must pass through the inside of a rotator assembly 94 to avoid becoming entangled around the rotator assembly 94.
Referring to
The assembly may also further comprise a selection valve 90 to control the fluid entering and exiting the assembly.
The rotator assembly 94 also comprises a drive assembly 37 rotatably mounted about the load-bearing shaft 38. The drive assembly 37 has a bottom body portion 39 securable to the operable attachment 92. As best viewed in
The rotator assembly 94 also comprises an actuator 50 fixed to the load-bearing shaft 38 and being operatively connected to the drive assembly 37 such that an actuation force from the actuator 50 is transmitted to the operable attachment 92 to rotate the operable attachment 92 about the load-bearing shaft 38. Preferably, and as best shown in
As best shown in
As shown in
The rotator assembly also comprises a first tube 42 having an upper end portion housed in the central recess 35 of the load-bearing shaft 38 and a lower end portion housed in the central recess 34 of the drive assembly 37. As best shown in
Preferably, the rotator assembly further comprises a collector 44 housed in the central recess 35 of the load-bearing shaft 38. As best shown in
The hydraulic fluid or oil that is used to feed the grapple cylinders is sent through the first channel 51, passes through the internal tube 42 and exits through ports 53, 54 to head towards the cylinders. The oil that returns from the cylinders penetrates through ports 55, 56, passes between the internal tube 42 and external tube 43 through the annular passage 25 and exits through the second channel 52. For the cylinders to act in an opposite direction, the oil displacement is done in the opposite direction. Consequently, at least two degrees of actuation are provided by each channel.
In another embodiment of the present invention, the collector 44 is fully integrated to the load-bearing shaft 38, and is not an independent component.
The load-bearing shaft 38 is normally in a vertical position but could also be inclined by activating a positioning piston located on the booms. The load-bearing shaft 38 does not rotate. The collector 44 is fixed such that it does not move on the load-bearing shaft 38.
The interior tube 42 and the exterior tube 43 are trapped between the collector 44 and the drive assembly 37 but are free to move. Consequently, the tubes are free to rotate or not. Preferably, on each tube, each extremity has a spherical part 61 in proximity thereof. Seals 20 and 21 press against this spherical part 61.
As shown in
Normally, the rotator assembly is positioned with a cylinder, but in another embodiment, the rotator assembly could be floating (i.e. positioned by the effect of gravity).
Consequently, the above-described rotator has the advantages of being small in size, low in cost and incurs lower maintenance due to improved rotative movement of the internal parts. Preferably, the rotator assembly has a modular design in which either the bottom body portion 39 of the drive assembly 37 or the collector 44 only have to be replaced during servicing, if required. This improves customer service as individual components of the rotator can be replaced without changing the complete rotator assembly.
This use of concentric tubes having spherical portions between the static and rotating parts of a rotator assembly can be used in several different rotator assembly designs. In another embodiment of the present invention, the rotator assembly may not have a motor driving the drive assembly which can then rotate freely. Moreover, in yet another embodiment, the rotator assembly comprises more than two concentric tubes, as several other concentric tubes linked to additional channels can be added around the first two tubes. In another embodiment of the present invention, the static and rotating parts of the rotator assembly are reversed in positioning such that the static part is mounted on the operable attachment and the rotating part is mounted on the boom member.
In another embodiment of the present invention, cabling or electronic wiring between the boom member and the operable attachment may be placed in the central first tube.
Consequently, the present invention also discloses a rotator assembly linking a boom member to an operable attachment. The rotator assembly comprises a stator mounted on one of the boom member and operable attachment. The stator has a central recess and a first and a second channel extending through the stator, each of the first and second channels being in communication with the central recess. The rotator also comprises a rotor rotatably mounted about the stator. The rotor has an interface securable to the other one of the operable attachment and boom member. The rotor also has a central recess in registry with the central recess of the stator and a first and a second channel in communication with the central recess of the rotor. Each of the first and second channels of the rotor has a port in a bottom or side wall of the rotor.
The rotator assembly also comprises a first tube having a first end portion housed in the central recess of the stator and a second end portion housed in the central recess of the rotor. The first end is in communication with said first channel of the stator and the second end is in communication with the first channel of the rotor, thereby allowing a first travel path from the boom member to the operable attachment. The rotator assembly also comprises a second tube concentrically positioned around the first tube and an annular passage between the first and second tube. The second tube has a first end in communication with the second channel of the stator and a second end in communication with the second channel of the rotor, thereby allowing a second travel path from the boom member to the operable attachment.
Preferably, the first and second travel path are flow paths for pressurized fluid.
In another preferred embodiment of the present invention, cabling is placed through the first travel path.
Preferably, the first and second tubes each comprise a first extremity and a second extremity, both extremities each having a spherical portion in proximity thereof, and the rotator assembly comprises a plurality of seals, each seal pressing against each of the spherical portions of the tubes.
Preferably, the spherical portions are pivotally connected to the stator and to the rotor.
Preferably, the rotator assembly further comprises an actuator operatively connected to the rotor such that an actuation force from the actuator is transmitted to the operable attachment to rotate the operable attachment about the stator.
Preferably, the stator comprises a load-bearing shaft and the rotor comprises a drive assembly.
In this system, a new type of hydraulic valve is also useful. If an operator wishes to immobilise an object being held with the grapple, the operator must control valves that feed the rotation hydraulic line. The rotation hydraulic line is thus theoretically isolated from the rest of the hydraulic lines. However, in certain cases, internal leaks in the hydraulic system result in that a small quantity of oil is sent to the rotation hydraulic line. In this case, the hydraulic pressure increases on both sides of the motor 50. This condition is problematic for the motor. Consequently, a hydraulic valve, which can decrease this pressure surrounding the motor 50 can eliminate this problem. As shown in
Referring to
A higher fluid pressure in the first supply port compared to the second supply port results in sealing engagement of the first ball 73 with the first sealing surface while allowing fluid flow between the second supply port and the reservoir. A higher fluid pressure in the second supply port compared to the first supply port results in sealing engagement of the second ball 74 with the second sealing surface while allowing fluid flow between the first supply port and the reservoir.
More particularly, the channel 71 is connected to the hydraulic port of the motor. The other channel 72 is connected to the other hydraulic port of the motor. The third channel 79 is directly connected to the hydraulic reservoir.
Preferably, the spring 78 presses against the shaft 77. This force is transmitted to the ball 73, which in turn presses against the central shaft 80. In a symmetrical and opposite manner, the second spring 76 presses against the second shaft 75. This force is transmitted to the second ball 74, which presses against the other side of the central shaft 80.
Preferably, the hydraulic pressure in the channel 71 comes from the motor 50 and presses against the ball 73. In a symmetrical and opposite manner, the hydraulic pressure in the channel 72 comes from the other port of the motor and presses against the ball 74.
If the hydraulic pressure of the channel 72 is greater than the hydraulic pressure in the channel 71, the resulting force will make the ball 74 press against the bottom of the opening in the block 82. In pressing against this opening in this manner, the ball 74 blocks completely the passage between the opening 72 and the channel 79. At the same time, the ball 74 presses against the central shaft 80 and displaces the ball 73, which consequently does not press against the bottom of the opening on its side. Consequently, oil from the opening 71 passes around the ball 73 and travels through the channel 79 toward the hydraulic reservoir.
If the hydraulic pressure of the opening 71 is greater than the hydraulic pressure in the opening 72, an opposite action occurs by symmetry. The ball 73 completely blocks the passage of hydraulic fluid between the opening 71 and the channel 79, and consequently fluid from the opening 72 passes around the ball 74 and travels towards the hydraulic reservoir.
Consequently, there is no oil leak between the high-pressure line of the motor and the reservoir. On the other hand, the low-pressure line of the motor communicates with the reservoir and pressure therefore decreases on this side of the motor.
Although the present invention has been explained hereinabove by way of a preferred embodiment thereof, it should be understood that the invention is not limited to this precise embodiment and that various changes and modifications may be effected therein without departing from the scope or spirit of the invention.
This application is a non-provisional application claiming priority under 35 U.S.C. § 119(e) of Provisional Application No. 60/632,977 filed Dec. 6, 2004.
Number | Date | Country | |
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60632977 | Dec 2004 | US |