Patent Grant
11480014
The present disclosure relates generally to mobile drilling machines, and more particularly, to an automatic force adjustment control system for such machines.
Mobile drilling machines, such as blasthole drilling machines, are typically used for drilling blastholes for mining, quarrying, dam construction, and road construction, among other uses. The process of excavating rock, or other material, by blasthole drilling includes using the blasthole drill machine to drill a plurality of holes into the rock and filling the holes with explosives. The explosives are detonated causing the rock to collapse and rubble of the collapse is then removed and the new surface that is formed is reinforced. Many current blasthole drilling machines utilize rotary drill rigs, mounted on a mast, that can drill blastholes anywhere from 6 inches to 22 inches in diameter and depths up to 180 feet or more.
Blasthole drilling machines may also include a hammer-type drill bit mounted on a drill string for down-the-hole drilling. During the down-the-hole drilling operation, it is desirable to maintain a load force on the drill bit within a predetermined target range while the drill bit moves down the hole for an effective hammering operation of the drill bit on the bottom surface of the hole. The target range for the load force may be determined by bit type and bit size (e.g., diameter of the drill bit). However, the target range for the load force on the drill bit may vary based on the type of ground materials (e.g., hard rock versus softer rock/dirt). For example, the hammering operation may be ineffective if the load force is not enough to maintain adequate force between the drill bit and the bottom of the hole (e.g., when the ground material is softer). Further, the drill bit or drill string may be damaged if too much load force is exerted on the drill bit, and/or the forces may inhibit the hammering motion of the drill bit (e.g., when the ground material is harder). Thus, the drill bit may wear at increased rates and the life of the drill bit may be reduced.
U.S. Pat. No. 9,279,318, issued to Hay et al. on Mar. 8, 2016 (the '318 patent), describes systems and methods for automatic weight on bit sensor calibration and regulating buckling of a drill string. The method includes taking a first survey recording at a first depth within a borehole for providing a curvature of a drill string at the first depth, and measuring a weight on a drill bit at the first depth with a senor sub arranged on a bottom hole assembly. The method calculates a predicted borehole curvature at a second depth within the borehole. The method of the '318 patent then calculates a weight correction value based on the predicted hole curvature and calibrates the sensor sub with the weight correction value. However, the method of the '318 patent may not adequately adjust the weight on the drill bit. Further, the '318 patent does not disclose automatically adjusting a force on a down-the-hole drill bit.
The automatic force adjustment control system of the present disclosure may address or solve one or more of the problems set forth above and/or other problems in the art. The scope of the current disclosure, however, is defined by the attached claims, and not by the ability to solve any specific problem.
In one aspect, a method for automatically adjusting a force on a down-the-hole drill bit of a drill string of a mobile drilling machine is disclosed. The method may include: monitoring bit air pressure of the down-the-hole drill bit during an automatic down-the-hole drilling operation; and automatically adjusting a force provided to the drill string based on the monitored bit air pressure so that the bit air pressure approaches a target air pressure value.
In another aspect, a method for automatically adjusting a force on a down-the-hole drill bit of a drill string of a mobile drilling machine is disclosed. The method may include: monitoring bit air pressure of the down-the-hole drill bit during an automatic down-the-hole drilling operation; and when the monitored bit air pressure is stabilized, automatically adjusting a force provided to the drill string based on the monitored bit air pressure so that the bit air pressure approaches a target air pressure value.
In yet another aspect, a mobile drilling machine is disclosed. The mobile drilling machine may include: a mast including a mast frame; a drill head movably mounted on the mast frame, the drill head controllable to rotate a down-the-hole drill bit mounted on a drill string; an air supply configured to supply air at a bit air pressure to the down-the-hole drill bit to provide a hammering action at the drill bit; a drill drive assembly configured to apply a force to move the drill head up and down along a length of the mast frame; and a controller configured to: monitor bit air pressure of the down-the-hole-drill bit during an automatic down-the-hole drilling operation; and automatically adjust a force provided to the drill string based on the monitored bit air pressure so that the bit air pressure approaches a target air pressure value.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate various exemplary embodiments and together with the description, serve to explain the principles of the disclosure.
Both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the features, as claimed. As used herein, the terms “comprises,” “comprising,” “having,” including,” or other variations thereof, are intended to cover a non-exclusive inclusion such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements, but may include other elements not expressly listed or inherent to such a process, method, article, or apparatus. Further, relative terms, such as, for example, “about,” “substantially,” “generally,” and “approximately” are used to indicate a possible variation of ±10% in a stated value.
As further shown in
Drilling mast 16 may further include a hydraulic feed cylinder 34 (located within mast frame 24) connected to rotary head 26 via a cable and pulley system (not shown) for moving rotary head 26 up and down along the mast frame 24. As such, when hydraulic feed cylinder 34 is extended, hydraulic feed cylinder 34 may exert a force (e.g., a pulldown force) on rotary head 26 for pulling-down rotary head 26 along mast frame 24. Likewise, when hydraulic feed cylinder 34 is retracted, hydraulic feed cylinder 34 may exert a force on rotary head 26 for hoisting up rotary head 26 along mast frame 24. Thus, hydraulic feed cylinder 34 may be controllable to control rotary head 26 to move up and down the mast frame 24 such that drill bit 30 on drill string 28 may be pulled-down towards, and into, the ground surface or hoisted up from the ground surface. As used herein, the term “feed” in the context of the feed cylinder 34 includes movement of the drill string 28 in either direction (up or down). Hydraulic feed cylinder 34 may include hydraulic fluid lines (not shown) for receiving and conveying hydraulic fluid to and from the feed cylinder 34. The hydraulic fluid may be used to actuate hydraulic cylinder 34 such that a rod of hydraulic cylinder 34 may be extended or retracted. The hydraulic fluid line of hydraulic cylinder 34 may be coupled to hydraulic valves 36 (shown schematically in
Controller 210 may be located on drilling machine 10 and embody a single microprocessor or multiple microprocessors that may include means for monitoring operation of the drilling machine 10 and issuing instructions to components of machine 10. For example, controller 210 may include a memory, a secondary storage device, a processor, such as a central processing unit or any other means for accomplishing a task consistent with the present disclosure (e.g., the methods of
Bit information input 212 may include a user input of bit type and a desired weight, or force, on the bit per diameter. Bit type may include different types (e.g., size, weight, etc.) of down-the-hole drill bits. The desired weight, or force, on the bit per diameter may be a default or nominal value for a given bit type for maintaining an effective hammering operation. For example, different types of bits may include different desired weight, or force, on the bit per diameter for maintaining the effective hammering operation. The desired weight, or force, on the bit per diameter may be determined by a user input of the diameter of the bit based on bit type. The user input may be received from an input device 40 (
Drill string weight input 214 may include a total weight of the drill string 28. The total weight of the drill string may be determined by a weight of the rotary head assembly 26, a weight of the drill pipes currently on the drill string 28, and a weight of the drill bit assembly. The weight of the rotary head assembly may be input by a user or may be pre-loaded and stored in the memory of controller 210. The weight of the drill pipes currently on the drill string may be determined based on a user input of the number of pipes currently on the drill string, or based on the system automatically tracking the number of pipes currently on the drill string. To determine the weight of the drill pipes currently on the drill string, controller 210 may calculate the input or tracked number of pipes multiplied with the weight of a single pipe. The weight of the drill bit assembly may be determined by a user input or may be pre-loaded in the memory of controller 210.
Bit air pressure input 216 may be a sensor for detecting and/or communicating a net force acting on the air supply line. Forces acting on the air supply line may include air pressure. Bit air pressure input 218 may be received from an air pressure sensor configured to communicate an air pressure signal indicative of air pressure of the air supply line on the drill bit 30 to controller 210. For example, an air pressure sensor may be located in the air supply line adjacent the air supply 32 so as to detect pressure of fluid (e.g., air) within the air supply line. It is understood that the air pressure sensor may be located anywhere along the air supply line. Bit air pressure input 216 may also derive air pressure information from other sources, including other sensors.
Pulldown force input 218 may include a sensor or other mechanism configured to detect and/or communicate a force acting on the drill string 28, and thus on the drill bit 30. In the system described in
The air pressure limits input, air pressure stable conditions, force on bit input, bit tables, and force factor input may be stored in the memory of controller 210. Air pressure limits may include maximum, or high, limits for an amount of air pressure provided for the piston of the hammer-type drill bit 30. For example, the air pressure limits may include a target air pressure value for operating the hammer-type drill bit 30. The target air pressure value may be a target value for an effective hammering operation of drill bit 30. The target air pressure value may also include a range of air pressure values. Further, the air pressure limits for bit air pressure 216 (e.g., the target air pressure value) may be configurable—adjustable based on user inputs, or may be manufacturer set values and not configurable.
The air pressure stable condition may include stored values for a stable condition and unstable condition of the bit air pressure input 216. The stable condition may include a first predetermined air pressure threshold being held for a predetermined amount of time. For example, the stable condition may be 1,000 kilopascals (KPa) per second for 2 seconds. If the bit air pressure input 216 changes by 1,000 Kpa (or less) per second for 2 seconds, the bit air pressure may be determined to be stable. Thus, the stable condition may correspond to the bit air pressure input 216 being stable (e.g., little or no change). The unstable condition may include a second predetermined air pressure threshold greater than the first threshold. For example, the unstable condition may be 1,500 KPa per second. If the bit air pressure input 216 changes by at least 1,500 KPa per second (for any amount of time), the bit air pressure may be determined to be unstable. Thus, the unstable condition may correspond to the bit air pressure input 216 being unstable. Further, the air pressure stable condition for bit air pressure 216 (e.g., the stable conditions and the unstable conditions) may be manufacturer set values.
The force on bit input may be a stored value for a current amount of force (e.g., pulldown force 218) applied to the drill string 28, and thus to the drill bit 30. The bit tables may include a desired force on bit for a given bit type and diameter of bit. For example, different bit types and sizes may each include a different desired force on bit for an effective hammering operation of drill bit 30. Thus, as an initial setting, the force on bit input may be set to the desired force on bit from the bit table. The force factor input may include a stored dimensionless factor value for multiplying to the force on bit in order to adjust the force on the drill bit 30, as detailed below.
For outputs of control system 200, controller 210 may control and/or adjust the pulldown force 218 (e.g., the net force acting on the hydraulic feed cylinder 34), as described below with reference to
The disclosed aspects of automatic force adjustment control system 100 of the present disclosure may be used in any drilling machine having a drill bit 30.
As used herein, the terms automated and automatic are used to describe functions that are done without operator intervention. The methods 300, 400 of
With reference to
In step 420, controller 210 may determine if the monitored bit air pressure is less than the target air pressure value. If the monitored bit air pressure is less than the target air pressure value (step 420: YES), controller 210 may increase the force factor (step 425). As noted above, the force factor may include a stored dimensionless factor value for multiplying to the force on bit in order to adjust the force on the drill bit 30. The force factor may correspond to a magnitude of difference between the monitored bit air pressure and the target air pressure value. As detailed above, the set desired force on bit (determined by bit type and size) may not be adequate for different ground materials. Further, the desired force on bit may not be easily and/or readily configurable by user input. Thus, the force factor may be used to adjust the desired force on bit to adjust the force on bit 30 and to provide adequate force on the drill bit 30 for an effective hammering operation, as further detailed below.
If the monitored bit air pressure is not less than the target air pressure value (step 420: NO), controller 210 may determine whether the monitored bit air pressure is greater than the target air pressure (step 430). If the monitored bit air pressure is greater than the target air pressure value (step 430: YES), controller 210 may decrease the force factor (step 435). In step 440, controller 210 may store the new force factor (e.g., the increased or decreased factor). To automatically adjust the force on the drill string 28 so that the bit air pressure approaches the target air pressure value (step 315), in step 445, controller 210 may automatically adjust the force on the drill string 28 (and thus the drill bit 30) by the force factor. Controller 210 may multiply the force on the drill string 28 by the force factor to automatically adjust the force on the drill string 28.
If the monitored bit air pressure is not greater than the target air pressure value (step 430: NO), controller 210 may determine whether the monitored bit air pressure is equal to the target air pressure value (step 450). If the monitored air pressure is equal to the target air pressure value (and/or the monitored bit air pressure is within the range of target air pressure values) (step 450: YES), controller 210 may use the stored force factor (step 455) and hold the current force on the drill string 28 (step 460). For example, the force on the drill string 28 may not need to be adjusted when the monitored bit air pressure is equal to the target air pressure value. During the automatic down-the-hole drilling operation, controller 210 may continuously monitor the bit air pressure input 216 (step 405) and automatically adjust the force on the drill string 28 by the force factor (step 445), as needed, so that the bit air pressure approaches the target air pressure.
Such an automatic force adjustment control system 100 may improve performance of drilling machine 10 and may enable a faster automatic down-the-hole drilling operation. For example, as noted above, drilling through different types of materials may vary the force on the drill bit, and thus the drill bit may wear differently. Accordingly, system 100 may help to ensure the compression load force on the drill bit 30 is adequately adjusted during the drilling operation to maintain an effective hammering operation of the drill bit 30. Such a system 100 may create a more intuitive operator control and may allow more autonomy of the drilling machine 10. Thus, the automatic force adjustment control system 100 of the present disclosure may help to improve drill bit life by reducing damage to the drill bit during the drilling operation, while decreasing overall drilling time.
It will be apparent to those skilled in the art that various modifications and variations can be made to the disclosed system without departing from the scope of the disclosure. Other embodiments of the disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. For example, different indications of force on the drill bit may be used and/or different ways of adjusting the force on the drill bit may be implemented. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.
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| Number | Date | Country | |
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| 20210180405 A1 | Jun 2021 | US |
