Patent Grant
11131145
This application claims priority under 35 U.S.C. § 119 to EP Patent Application No. 18170127.7, filed on Apr. 30, 2018, which the entirety thereof is incorporated herein by reference.
The present invention relates to a drilling boom of a rock drilling rig. The drilling boom is provided with a feed beam assembly including a rock drilling machine for drilling blast holes or bolting holes to rock surfaces. The boom has several joints allowing the rock drilling machine to be positioned into planned drilling positions. The invention further relates to a rock drilling rig.
In mines and at other work sites different type of rock drilling rigs are used. The rock drilling rigs are provided with one or more booms and rock drilling units are arranged at distal ends of the booms. The rock drilling unit includes a feed beam along which a rock drilling machine is configured to be moved during the drilling procedure. The drilling boom includes several joints allowing the rock drilling machine to be positioned to a desired drilling point for drilling drill holes for blasting or support purposes. However, the present drilling booms contain some disadvantages regarding their kinematics and ability to reach the desired drilling positions.
An object of the invention is to provide a novel and improved drilling boom and a rock drilling rig equipped with such drilling boom.
The drilling boom of a rock drilling rig includes an elongated basic boom part having a first end, which is connectable movably to a carrier of the rock drilling rig and a distal second end. A feed beam assembly includes a feed beam for supporting a rock drilling machine, which feed beam assembly is located at the second end of the basic boom part. A front joint arrangement, which is located between the second end of the basic boom part and the feed beam assembly, comprises three successive and proximate front joints, a first front joint connected to the basic boom part, a third front joint connected to the feed beam assembly and a second front joint being located between the first and third joint. Several boom actuators are arranged for moving the drilling boom and the feed beam assembly. The first front joint is a roll-over joint, the turning axis of which is parallel to longitudinal axis of the basic boom part. The second front joint is a feed tilt joint, the turning axis of which is perpendicular to the turning axis of the roll-over joint. The third front joint is a feed swing joint having a turning axis of which is perpendicular to the turning axis (20) of the feed tilt joint.
The rock drilling rig includes a movable carrier, at least one drilling boom connected movably to the carrier and equipped with a feed beam assembly with a feed beam. A rock drilling machine is supported by the feed beam. The drilling boom includes several boom joints and boom actuators arranged for orientating and positioning a drilling tool are connectable to the rock drilling machine to drilling points at a drilling site. The drilling boom includes the aforementioned front joint arrangement having three successive joints: the roll-over joint, the feed tilt joint and the feed swing joint.
An aspect of the disclosed solution is that the drilling boom includes a basic boom part or arm, which is an elongated object, a first end of which is connectable to a carrier of a rock drilling rig. At a second end of the arm is a front joint arrangement or wrist, which connects a feed beam assembly to the arm. The feed beam assembly may be a face drilling unit or a bolting head and includes at least a feed beam and a rock drilling machine supported on the feed beam. The drilling boom includes several joints and boom actuators for positioning the drilling machine and a drilling tool connectable to it into the planned drilling positions and directions. The wrist has three successive joints, which are located proximate to each other. The joints are arranged in a certain order. A roll-over joint is closest to the arm and is followed by a feed tilt joint. A feed swing joint is closest to the feed beam assembly. Thus, executable movements of the wrist are arranged in an optimized order: roll-over tilt swing.
Another aspect of the disclosed solution is that the front joint assembly or wrist offers improved reach properties. The feed beam assembly, which may be a face drilling unit or a bolting head, may be positioned to challenging blast hole and rock bolt hole positions which are located close to walls, roof and floor of a tunnel or rock cavity.
The wrist also allows new movements and drilling orientations for the face drilling unit and also for the bolter head. The face drilling unit may be directed perpendicular relative to driving direction of the rock drilling rig, whereby it allows drilling crosscuts. Regarding the bolting implementation, the wrist solution allows directing the bolting head also directly forward i.e. in the driving direction, whereby face bolting is also possible. Thanks to these new allowed drilling directions the drilling boom may be utilized in a more effective way.
One additional use enabled by the disclosed wrist is that the face drilling unit and the bolting head may be turned backwards towards a carrier of a drilling jumbo or bolting rig. Then drill bits and other drilling tools, as well as bolting equipment, can be changed and loaded in a convenient and safe manner close to the carrier.
A further aspect of the disclosed solution is that the same front joint assembly or wrist is suitable for face drilling booms intended for tunneling and for fan drilling booms intended for rock bolting. Thus, the present boom and wrist solution may be implemented for carrying face drilling units of tunneling jumbos as well as bolting heads of bolters. This is of course beneficial for the manufacture, service and overall cost-efficiency.
According to an embodiment, the first end of the basic boom part or arm is provided with a rear joint assembly. The assembly includes a swing joint for turning the drilling boom laterally relative to the rock drilling rig. The assembly further includes a lift joint for turning the drilling boom vertically. Thus, the rear joint assembly provides the drilling boom with 2 degrees of freedom (2DOF).
According to an embodiment, the first end of the drilling boom is connected to a mounting plate by means of the rear joint assembly. The mounting plate is provided with fastening elements for fastening it to the carrier of the rock drilling rig. The mounting plate facilitates mounting of the drilling booms to different kind carriers and provides proper support for the drilling boom.
According to an embodiment, between the first and second end of the basic boom part or arm is a linear joint whereby the basic boom part is extendable in the longitudinal direction. The linear joint is the only joint between the first and second end of the basic boom part. In other words, the arm is without any turnable or rotational joints between the first and second end. Thus, the basic boom part may have a relatively simple, durable and light weight structure between its end portions, and still, the joint arrangements at its both ends and the linear zoom joint between them ensure good reach and versatile drilling positions and directions. The arm has totally three degrees of freedom (3DOF), namely the swing, lift and zoom.
According to an embodiment, the turning axis of the roll-over joint is located on the longitudinal axis of the basic boom part. In other words, the turning axis and the longitudinal axis are concentric. Thanks to this embodiment, mounting of the roll-over joint is facilitated and loadings directed to the joint are well controlled.
According to an embodiment, the turning axis of the feed tilt joint is located closer to the roll over joint than the feed swing joint when seen in longitudinal direction of the basic boom part. In other words, the distance between the turning axis of the feed tilt joint and the roll over joint is minor than distance between the turning axis of the feed tilt joint and the feed swing joint. It has been noted that when the feed tilt joint is located proximate to the roll-over joint, improved reach properties can be achieved and collisions between the basic boom part and the feed beam assembly can be better avoided.
According to an embodiment, extensions of the turning axis of the feed tilt joint and the turning axis of the feed swing joint do not cross. Between the feed tilt joint and the feed swing joint may be a physical connecting element, whereby the joints are at a distance from each other.
The distance between the turning axis of the feed tilt joint and the turning axis of the feed swing joint may be 200-300 mm Between the feed tilt joint and the feed swing joint may be a physical connecting element, whereby the joints are at a distance from each other.
According to an embodiment, the feed tilt joint and the feed swing joint are located on opposite sides of the turning axis of the roll-over joint. When the drilling boom is in its normal position the turning axis of the feed tilt joint is located vertically below the turning axis of the roll-over joint.
According to an embodiment, orientation of the feed beam of the feed beam assembly is parallel to the turning axis of the feed swing joint. In other words, drilling direction of the drilling machine supported to the feed beam is parallel to the axis of the last joint of the front joint arrangement. This embodiment is a main implementation in bolting.
According to an embodiment, orientation of the feed beam of the feed beam assembly is perpendicular to the turning axis of the feed swing joint. In other words, drilling direction of the drilling machine supported to the feed beam is perpendicular to axis of the last joint of the front joint arrangement. This embodiment is a main implementation for face drilling jumbos and tunneling.
According to an embodiment, magnitudes of angles of movements of both the roll-over joint and the feed swing joint can be 360°. The feed tilt joint is turnable at least 180°.
According to an embodiment, the structure of the front joint arrangement is symmetric relative to the longitudinal axis of the basic boom part. An advantage of this feature is that the same drilling boom is usable either as a left or a right hand boom of the rock drilling rig.
According to an embodiment, the boom actuators are hydraulic actuators such as hydraulic cylinders and motors. The hydraulic actuators are advantageous since they allow great forces and still provide accurate movement control.
According to an embodiment, boom actuators of the roll-over joint and the feed swing joint are hydraulic motors and the feed tilt joint is moved by means of one or more hydraulic cylinders.
According to an embodiment, the rock drilling machine defines a drill center, which is parallel to the longitudinal direction of the feed beam and on which drill center a drilling tool is rotated during drilling. The drill center has a drill center height which is a transverse distance measured to the turning axis of the roll-over joint. The drill center height is at least 1,000 mm. This provides improved reach properties and prevents collisions between a rear end of the feed beam and the basic boom part.
According to an embodiment, in a bolting implementation the feed beam assembly may include a handling device for moving reinforcing bolts between a bolt storage and drilling axis of a rock drilling machine. Further, when the bolting head is turnable backwards the bolt storage may be located at a front part of the carrier.
Further, present disclosure may also relate to a method of controlling boom kinematics enabled by the disclosed new boom configuration. The method according to the invention is characterized by the features and steps disclosed herein.
The above disclosed embodiments may be combined in order to form suitable solutions having those of the above features that are needed.
The foregoing summary, as well as the following detailed description of the embodiments, will be better understood when read in conjunction with the appended drawings. It should be understood that the embodiments depicted are not limited to the precise arrangements and instrumentalities shown.
For the sake of clarity, the figures show some embodiments of the disclosed solution in a simplified manner. In the figures, like reference numerals identify like elements.
The rock drilling machine 6 may have a shank at a front end therof for connecting a tool 7. The feed beam assembly FBA is connected to the second end of the basic beam part BB2 by means of a front joint arrangement 8, which may be also called as a wrist. As it is shown in
At the first end BB1 of the basic boom part BB may be a vertical swing joint 9 so that the entire drilling boom 3 may be turned laterally, i.e. allowing first swing movement S1. The first end BB1 may further have a horizontal lift joint 10 for lifting L the drilling boom 3. The basic boom part BB may also be provided with a linear joint 12 for extending and shortening purpose. In other words, the basic boom part BB may have a so-called zoom movement Z. Thus, the basic boom part BB may have the above-mentioned three joints 9, 10 and 12.
At the first end BB1 may be a rear joint assembly 13 including a mounting plate 13a and the joints 9 and 10. The drilling boom 3 may be connected to the carrier 2 by means of the mounting plate 13a provided with fastening elements. The basic boom part BB may be without any turnable or rotational joints between the rear joint assembly 13 and the front joint assembly 8. In other words, the linear joint 12 may be the only joint between the end portions of the basic boom part BB.
Typically, the rock drilling machine 6 and actuators of the drilling boom 3 are hydraulically operable. For simplicity reasons only one boom actuator 14 is shown in
The front joint arrangement 8 or wrist includes three successive joints, which are located between the second end BB2 of the basic boom BB and the feed beam assembly FBA. This means that the three successive joints are physically close to each other. The front joint arrangement 8 is thereby a compact joint system allowing roll-over movement RO, tilt movement T and swing movement S2. Respective joints of the front joint arrangement 8 are arranged in the corresponding order RO-T-S2 as it is disclosed more specifically in the following figures.
Turning axis 18 of the roll over joint 15 may be concentric with longitudinal axis 19 of the basic boom part BB. The input link 15a of the roll over joint 15 may be connected directly on extension of the basic boom part BB. Turning axis 20 of the following feed tilt joint 16 is perpendicular to the turning axis 18 of the roll over joint 15, and further, turning axis 21 of the feed swing joint 17 is perpendicular to the turning axis 20 of the feed tilt joint 16. The turning axis 18, 20, 21 are illustrated in
Although the present embodiment(s) has been described in relation to particular aspects thereof, many other variations and modifications and other uses will become apparent to those skilled in the art. It is preferred therefore, that the present embodiment(s) be limited not by the specific disclosure herein, but only by the appended claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 18170127 | Apr 2018 | EP | regional |
| Number | Name | Date | Kind |
|---|---|---|---|
| 4364540 | Montabert | Dec 1982 | A |
| 5937952 | Bigoney | Aug 1999 | A |
| 20140110168 | Pursimo | Apr 2014 | A1 |
| 20160123146 | Makela | May 2016 | A1 |
| Number | Date | Country |
|---|---|---|
| 3159474 | Apr 2017 | EP |
| 3159474 | Apr 2017 | EP |
| 2189724 | May 1990 | GB |
| 2007073327 | Jun 2007 | WO |
| WO-2007073327 | Jun 2007 | WO |
| 2007100287 | Sep 2007 | WO |
| Number | Date | Country | |
|---|---|---|---|
| 20190352968 A1 | Nov 2019 | US |
