The present invention relates to a method and a device for controlling drill parameters when drilling in rock, as set forth in the preamble of Claims 1 and 6, respectively.
Rock drilling is often carried out by percussion drilling, where a percussion piston, which is often operated hydraulically, is used to create a shock wave with the aid of an impact force that is generated by hydraulic pressure (percussion pressure), the shock wave being transmitted to the drill bit and hence to the rock through the drill steel (drill string). On contact with the rock, pins made of a hard alloy of the drill bit contacting the rock is pushed into the rock, generating a strong enough force to fragment the rock.
In rock drilling of this kind, it is important that the start of the drilling is performed correctly and that drilling is done with care during normal drilling (i.e.
drilling with high impact force) in order to ensure that the drilling takes place in a manner that does not damage the drilling machine/drilling rig.
It applies in general, and especially in the case of drilling under difficult rock conditions and with a strong impact force, that the drill bit should have as good a contact with the rock as possible. A common way of achieving this is to use a piston which works against the drill steel (drill string) and which is usually in the form of a damping piston, which is also used to damp reflexes from the impact of the shock waves against the rock. During drilling, the damping piston is pressed against the drill steel, and the drill steel is thus pressed against the rock, by pressurization of a pressure chamber working against the damping piston. The damping piston is also usually arranged such that, if the damping piston advances too far, i.e. the area in front of the drill steel is soft enough for the impact of the percussion piston to cause the drill steel, and thus the damping piston, to move forwards and past a normal position, an outlet for said pressure chamber is completely or partially opened, resulting in a pressure decrease in the pressure chamber. By detecting this decrease in pressure, the status of the contact with the rock can be determined, and suitable measures can thus be taken.
For example, the percussion pressure can be increased to a normal drilling level when the damping pressure exceeds a defined pressure level, which, for example, can be a pressure level that has been determined as being desirable during normal drilling. Moreover, the percussion pressure can be arranged to be kept at the normal drilling level as long as the damping pressure does not fall below a low-pressure level, which, for example, can be a level that involves lost or poor contact with the rock. If the damping pressure falls below this level, the percussion pressure can be decreased to the start-up drilling level or can be completely shut off. However, this type of control has a number of disadvantages.
For example, there is a considerable risk of idle percussion, i.e. percussion where most of the shock wave is reflected in the drill bit instead of the rock, which leads to a large amount of damaging energy being returned to the drilling machine.
There is therefore a need for an improved method and device for controlling drill parameters, specifically a method and device that at least partially alleviate the problems of the prior art.
One object of the present invention is to provide a method for controlling at least one drill parameter in order to solve the above problems.
Another object of the present invention is to provide a device for controlling at least one drill parameter in order to solve the above problems.
These and other objects are achieved, according to the present invention, by a method for controlling at least one drill parameter, as defined in Claim 1, and by a device according to Claim 6.
According to the present invention, the abovementioned aims are achieved by a method for controlling at least one drill parameter when drilling in rock with a drilling machine. During the drilling, an impulse-generating device, using an impact means, induce shock waves in a tool working against the rock, whereby a pressure level for a shock-wave-generating pressure is controlled during the drilling, and where said drilling machine includes a damping chamber that can be pressurized. The contact of the drilling machine against the rock is at least partially affected by the prevailing pressure in said damping chamber. The method includes the step in which, when the pressure in said damping chamber exceeds a first level and is below a second level, the percussion pressure is controlled as a function of the pressure in said damping chamber.
This has the advantage that, by controlling the percussion pressure as a function of the pressure in a damping chamber, it is possible to ensure in every situation that a correct percussion pressure is used in relation to the damping pressure. This in turn means that damaging reflexes can be avoided both during start-up drilling and during normal drilling.
In said control, the percussion pressure can, for example, be controlled between a first level, which substantially corresponds to a start-up drilling level, and a second level, which substantially corresponds to a normal drilling level.
The first level can, for example, substantially correspond to a level at which the percussion pressure is substantially shut off.
Said function can, for example, be one or a combination of several of the following: proportional to the damping pressure, inversely proportional to the damping pressure, exponential to the damping pressure, logarithmic to the damping pressure, a defined relationship to the damping pressure.
The control can, for example, be obtained with the aid of a mathematical relation between damping pressure and percussion pressure and/or by reference to a table containing a relationship between damping pressure and percussion pressure.
The method can further include the step in which, when the pressure in said damping chamber exceeds said second level, the percussion pressure is controlled in such a way that it is maintained substantially at a pressure corresponding to the percussion pressure for said second level.
The method can further include the step in which, when the pressure in said pressure chamber falls below said first level, the percussion pressure is controlled in such a way that it is maintained substantially at a pressure corresponding to the percussion pressure for said first level.
Said pressure in said damping chamber can be determined by determining a parameter value representing a mean value of the damping pressure in the damping chamber. The parameter value representing a mean value of the damping pressure in the damping chamber can, for example, be determined with the aid of the pressure in a pressure feed line for said damping chamber.
The damping pressure can, for example, be determined continuously and/or at certain intervals by sensoring, monitoring, measurement or calculation.
The mean value can, for example, be determined based on a plurality of impulse cycles.
The method can further include the step in which, when said damping pressure exceeds a third level higher than said second level, the percussion pressure is controlled as a function of said damping pressure, with said percussion pressure exceeding said second percussion pressure level.
The method can further include the step of controlling the percussion pressure in such a way that the time for an increase of said percussion pressure from the first level to the second level exceeds a threshold value.
The feed rate of the drilling machine can also be used in controlling the percussion pressure. In this case, the dependency of the percussion pressure on the damping pressure can be made to depend partly on the feed rate.
The present invention also relates to a device by means of which advantages corresponding to those described above are obtained with corresponding device features.
Other advantages are obtained by various aspects of the invention and will become clear from the following
The present invention will now be explained by way of example with reference to a rock-drilling rig of the type shown in
In addition to said function of pressing the drill string against the rock, the damping piston also has a damping function. When an impact gives rise to reflexes from the rock, these are damped by means of the damping piston 34 being pressed into a second damping chamber 38, whereupon fluid in the second damping chamber 38 is pressed into the first damping chamber 37 through a small slit, formed between the damping piston 34 and the chamber wall 35, when the damping piston 34 is pressed into the second damping chamber 38. This results in a braking pressure increase in the second damping chamber 38.
In the prior art, the pressure in said damping chamber 37, or in a feed line to the damping chamber 37, is used to obtain certain control over the percussion pressure of the drilling machine.
At the start of drilling, the percussion pressure is held at a collaring (start-up drilling) level S1 as long as the damping pressure is below the higher level D2. When the damping pressure at a time t1 exceeds the pressure level D2, the percussion pressure is increased to normal drilling pressure S2, where the percussion pressure is then held as long as the damping pressure dries not fall below the lower pressure level D1. If, at a later time t3, the damping pressure falls below the pressure level D1, the percussion pressure is decreased, as shown, to the start-up drilling level. Alternatively, the percussion pressure can be arranged to be completely shut off if the damping pressure falls below the pressure level D1. However, the control system shown in
For example, as is shown, the percussion device can continue impacting at high force despite the fact that contact with the rock is in the process of being lost or is poor, i.e. the damping pressure is below the level D2, for example between the times t2 and t3 in
The system shown in
The present invention at least alleviates the disadvantages of the current systems and will now be described in more detail with reference to
The present invention affords a number of advantages. For example, the useful life of the drill bits, drill steel (drill string) and shank adapter is increased. This advantage is obtained by virtue of the harmful reflexes being reduced, since the percussion pressure is already lowered when the damping pressure begins to indicate that the drill bit has poor/worsening contact with the rock. Another advantage of the present invention is that a considerably more sensitive system is obtained, which reduces the risk of the self-oscillation mentioned above.
The present invention has been illustrated above in the case of linear control. However, the percussion pressure can of course be controlled also according to any function of the damping pressure. For example, the percussion pressure can be arranged to increase exponentially or logarithmically to the damping pressure. It is advantageous to use a well-known mathematical function that is easy to program in, e.g. into the control unit 16, and which is used for the control. Alternatively, the function can be a table function, i.e. the percussion pressure corresponding to each damping pressure is looked up in a table. Moreover, proportionality constants and exponents (and also factors checked in a table) can be determined at least partially based on the feed rate of the drilling machine, i.e. if the feed rate is high, the proportionality constant/exponent can be set lower, such that the percussion pressure increases more slowly compared with the case when the feed speed is low.
In an alternative embodiment, the percussion pressure is increased in steps, where a certain increase (or decrease) in the damping pressure results in a step up (or down). However, each step is small in relation to the total difference between the first level (S1) and the second level (S2).
As regards the damping pressure in the damping chamber 37, this can be determined as mentioned above, for example by measurement/sensoring by means of a pressure sensor arranged in or near the damping chamber. The damping pressure is determined sufficiently often, for example continuously or at regular intervals, to be able to obtain the variation of the damping pressure at the stroke of the percussion tool, i.e. such that the pressure increase pulses that occur upon reflections from the rock can be detected, after which a mean value of the damping pressure during a percussion cycle can be determined. For example, the pressure sensor can be designed such that it comprises means for calculating said mean value and then, at each percussion cycle, for emitting a representation of the mean value. The pressure sensor can alternatively be designed to emit signals continuously or at certain intervals (depending on the percussion frequency of the drilling machine; a drilling machine operating with a percussion frequency of several hundreds of hertz, or even in the kHz range, requires considerably closer intervals compared with a drilling machine that operates with a percussion frequency of the order of 30-50 Hz), which signals are then used by an external element to determine a mean value of the damping pressure for a percussion cycle. Instead of determining the mean value for one percussion cycle, it is possible to determine the mean value for a plurality of percussion cycles. Instead of measuring the damping pressure in a damping chamber, it is possible, for example, to measure the pressure on the feed line to the damping chamber. This has the advantage that the pressure measurement can take place on the carrier, for example, with reduced routing of cables as a result.
As has been shown above, the present invention can be used both in start-up drilling and normal drilling. The invention is particularly advantageous in conditions where the rock contains numerous fissures and/or the hardness of the rock varies greatly, such that the drill steel occasionally loses contact with the rock ahead, in which case the risk of harmful reflexes can be reduced.
Nor does the control have to take place throughout the interval between start-up drilling level (S1) and normal drilling level (S2), and instead it can be arranged to be carried out only in part of the interval, for example in half this interval, or in that part of the interval where there is greatest risk of contact with the rock being lost.
Furthermore, the present invention has been described in connection with a percussion drilling machine that comprises a percussion piston, where the energy of the percussion pulse in principle consists of the kinetic energy of the percussion piston, which energy is transmitted to the drill steel. However, the present invention can also be used with other types of pulse-generating devices, for example devices in which the shock-wave energy is instead generated as pressure pulses that are transmitted to the drill string from an energy storage through a impact means that executes only a very small movement. In these types of impulse-generating devices too, a damping pressure can be measured in a damping chamber, which can in fact be any chamber, as long as the desired damping function is achieved.
As will be readily appreciated, although it will still be mentioned here for the sake of clarity, the expression “control of a pressure as a function of another pressure”, as used according to the present invention, does not include the type of control in which the percussion pressure is suddenly reduced from the normal drilling pressure to, for example, the start-up drilling pressure as soon as the damping pressure passes a threshold value.
Number | Date | Country | Kind |
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0700884-0 | Apr 2007 | SE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/SE2008/000256 | 4/9/2008 | WO | 00 | 10/6/2009 |