This application claims priority under 35 U.S.C. §119 to Swedish patent application 0901268-3 filed 5 Oct. 2009 and is the national phase under 35 U.S.C. §371 of PCT/SE2010/051053 filed 1 Oct. 2010.
The present invention concerns a hard metal insert, a drill bit comprising at least one hard metal insert and a method for regrinding a worn insert.
Drill bits comprising a number of hard metal inserts are used for percussion drilling. The task of the hard metal inserts is to achieve during repeated blows against the drill bit the formation of cracks in the rock in which holes are to be drilled.
A hard metal insert consists of a cap, a cylindrical part and a bottom. The cap constitutes a part that is worn, while the cylindrical part together with the bottom constitutes the contact surface of the insert with the drill bit. The cap may have any one of several forms, such as spherical, semiballistic or fully ballistic. The orientation of the hard metal insert relative to the axis of symmetry of the drill bit differs, depending on the location of the insert in the drill bit.
The cap of the insert is worn during drilling, and in this way its shape is changed. The region of the insert that is worn during drilling forms a surface that will be referred to below as the “wear phase”. The region of the insert that protrudes from the drill bit and that is exposed to wear will be referred to below as the “wear surface”.
When the wear has progressed until the area of the wear phase is of the order of 25% of the cross-sectional area of the cylindrical part of the insert, it is appropriate to restore the insert to its original capped form by grinding. The cap part of the insert is consumed in height during drilling through wear, and the total length of the insert thus becomes less during each drilling stage.
There is a direct correlation between the depth of penetration and the size of the contact surface between the insert and the rock. There is a direct correlation also between the depth of penetration and the magnitude of the force in the shock wave.
For an insert that has the same original form, more power is required to hammer in a comparatively more worn insert a given distance into rock than is required to hammer in a less worn hard metal insert. This means that it takes comparatively more time and requires more force to drill a hole of a given stretch with a drill bit that comprises worn hard metal inserts.
This means that the drill bit is pressed into the rock to different depths, depending on how worn the component inserts are, i.e. depending on the size of the contact surface between insert and rock. A larger contact area gives a lower penetration into the rock. Thus the drilling rate, which is here defined as the length of hole drilled per unit time, will fall during a drilling stage that is carried out with the same drill bit and inserts. One of the reasons that the insert is reground is thus to ensure a relatively high drilling rate during the complete lifetime of the bit.
A hard metal insert can be reground several times to its original cap form. The number of times that an insert can be reground depends on many factors, including the length of the insert, the height of the cap and the required size of the contact surface between the insert and the drill bit.
The lifetime of the drill bit depends on the rate of wear of the hard metal insert, measured as the reduction in length of the insert per drilled meter of hole. The production costs for drilling holes in rock depend on the lifetime of the drill bit, and thus in turn on the reduction in length of the inserts that are components of the bit per drilled meter of hole.
There is a need for hard metal inserts that can be reground, that optimise the production costs for percussion drilling of holes in rock.
One purpose of the invention is to offer a hard metal insert the use of which is economically advantageous for percussion drilling. A second purpose of the invention is to offer a method for the regrinding to the required form of hard metal inserts for percussion drilling in rock.
According to a first aspect of the invention, this purpose is achieved by offering a hard metal insert intended to be mounted in a drill bit for percussion drilling. The hard metal insert comprises a cap, which constitutes a wear part comprising a wear surface and a cylindrical part, which constitutes a mount with a cross-sectional area A and a diameter D. The cap comprises a front part with an extension H along the axis of symmetry x of the insert from a first point on the wear surface of the cap to a second point in the cap. The front part constitutes a volume Vf between a first plane I, which intersects at right angle to the axis of symmetry at the first point, and a second plane II, which intersects at right angle to the axis of symmetry at the second point.
The front part 4 constitutes a volume Vf between a first plane I, which intersects at right angle to the axis of symmetry x at a first point a, and a second plane H, which intersects at right angle to the axis of symmetry x at a second point b.
The magnitude of the cylindrical volume V, which describes the front part 4, can be expressed as follows:
V=Af×H
where
Af is the cross-sectional area of the front part at the second plane II, and
H is the distance along the axis of symmetry x between the first point a and the second point b.
The ratio Vf/V is a volume ratio that specifies how large a part of the volume of the surrounding cylinder is occupied by the front part.
The solution according to the invention specifies an insert that has a front part with a certain extent along the axis of symmetry of the insert and furthermore has a certain volume. The volume ratio defined above according to the invention gives a front part that defines a comparatively blunt wear surface.
An insert designed to have the volume ratio defined above greater than or equal to 0.6 has a comparatively large volume of hard metal material in the front part of the cap, i.e. the part that penetrates into the rock and breaks it.
This is the case under the condition that the cross-sectional area Df of the front part in the second plane II has a certain length relative to the diameter D of the mount, as follows:
0.5×D≦Df≦0.6×D
where Df is the cross-sectional diameter of the front part.
Each individual insert in a drill bit has a contact surface with rock during drilling.
The total contact surface between the insert in a drill bit and rock defines the distance to which the bit can be pressed into the rock for a certain force. The requirements for strength of the inserts and the resistance to wear of the inserts principally depend on the distance to which the inserts are pressed into the rock and how far out along any particular insert the contact surface is located.
A comparatively large contact surface for an insert in a drill bit, defined as described above, gives a comparatively longer lifetime during drilling. A point-formed contact surface, thus, is worn more than a contact surface that has a certain extent.
The contact surface described above initiates a zone of crushing in the rock. It is the aim when drilling that the zone of crushing in the rock be larger than the volume or contact area of the insert that is pressed into the rock. The zone of crushing in this way depends partially on the contact area.
The purpose of the design of a drill bit according to the invention is, among other purposes, that the total zone of crushing in the rock that is achieved by the insert according to the invention shall lead to crushing of a hole with a larger diameter than the maximum diameter of the drill bit.
The zone of crushing depends, naturally, on whether the rock type under consideration is, for example, hard, soft, ductile, brittle or permeated by cracks, or has a combination of the these properties.
A comparatively large zone of crushing results in a larger volume of processed rock for each blow or shock wave. This, in turn, makes it possible to drill a higher number of meters of hole with the insert and drill bit.
Inserts designed according to the volume ratio, Vf/V, defined above make possible an essentially constant contact surface between the insert and rock during a drilling operation. This results in comparatively low variation in the depth of penetration into the rock, and thus it results in also the drilling rate, i.e. the length of hole drilled per unit time, varying only insignificantly.
A greater amount of hard metal in the front part of the cap ensures a longer operating time for the inserts between regrinding operations, and thus longer lifetime. This in turn gives a drill bit with comparatively longer lifetime, which reduces the cost per meter of drilled hole.
Furthermore, a greater amount of hard metal in the front part of the cap gives the possibility of replacing currently available inserts by an insert with a smaller diameter, thus obtaining more space for each insert, which will increase the drilling rate and shorten the time required to produce boreholes.
An alternative according to the invention specifies a front part with a wear surface comprising a first and a second spherical part. A second alternative according to the invention specifies a front part with a wear surface comprising an essentially plane front part and a spherical part. A further alternative according to the invention specifies a front part with a wear surface comprising an essentially plane front part and a conical part.
All alternative designs within the innovative concept of the invention result in a lower wear in the height of the insert according to the invention for a given volume of hard metal material worn away from an insert during drilling than was the case for previously known inserts. The term “wear in the height” is in this context used to denote a reduction in the extent of the front part that is a component of the cap along the axis of symmetry of the insert.
In one design of the invention, the said diameter Df of the front part is 0.5 times or, alternatively, 0.6 times the diameter D of the mount.
According to a second aspect of the invention, its purpose is achieved by offering a method to grind an insert for percussion drilling in which the insert comprises not only a cap, which constitutes a wear part comprising a wear surface, but also a cylindrical part, which constitutes a mount with a cross-sectional area A and a diameter D. The method comprises grinding the cap and forming a front part with an extension H along the axis of symmetry of the insert from a first point on the wear surface of the cap to a second point in the cap such that the front part constitutes a volume between a first plane, which intersects at right angle to the axis of symmetry at the first point, and a second plane, which intersects at right angle to the axis of symmetry at the second point. The magnitude of the volume is equal to 0.6 times the cross-sectional area Af of the front part in the second plane II times the distance H along the axis of symmetry between the first point a and the second point b. The diameter Df of the front part in the second plane is greater than or equal to 0.5 times the diameter D of the mount and less than or equal to 0.6 times the diameter D of the mount, where the volume Vf of the front part corresponds to the lowest possible volume of hard metal that it is intended should be worn away during drilling before the insert is reground.
which intersects at right angle to the axis of symmetry at a first point
which intersects at right angle to the axis of symmetry at a second point
The bluntness, as defined above, of the front part of the cap contributes to it being necessary to grind away a lower mass when the insert is reground such that its form is restored. In comparison with previously known inserts, such as spherical, fully ballistic and semiballistic inserts, the insert according to the invention is designed such that there is more volume of hard metal available to be worn away before it requires regrinding. The length H of the insert that must or can be worn before a regrinding operation is comparatively shorter than the corresponding length of, for example, a semiballistic or standard insert. An insert according to the invention will be shortened during each regrinding operation comparatively less than a traditional insert is shortened. The drill bit in which the insert is located will, thus, have a longer lifetime.
The factor that limits the number of regrinding operations is the minimum length of the insert that is required for a functional mounting into a drill bit. The height of the cap is also a limiting factor for the number of regrinding operations possible.
It should be pointed out that the drawings have not been drawn to scale.
A hard metal insert 1 according to the invention (
The plane II in
The ideal insert is a cylindrical insert, i.e. an insert that has a front part with a volume ratio Vf/V, as defined above, that is equal to 1. Such an insert does not need to be reground since it has a constant depth of penetration. The problem is that the diameter of the insert then must be half of the insert diameter currently used such that the area does not become too large, since the shock wave must have sufficient force to press the insert into the rock. Such a cylindrical insert would not be able to withstand the mechanical load.
The orientation of a hard metal insert in a drill bit differs greatly, depending on the type and size of the drill bit and the location of the insert in the drill bit. One method of describing the orientation is to specify an angle V2, which is the angle that the axis of symmetry/longitudinal axis of the insert has relative to the axis of symmetry/longitudinal axis of the drill bit.
The hard metal insert according to the present invention is intended to be arranged with an angle V2 that lies in the interval 0 to 45 degrees.
One advantage of the present invention is that a hard metal insert according to
It has already been pointed out that the length of the insert should not be affected by the regrinding operation, while a fraction of the working volume of the insert is ground away in order to re-attain the desired form of the insert.
Calculation of the volume ratio according to the invention for the insert 14 gives a comparatively low value. The front part of the insert 14 thus contains a comparatively lower volume of hard metal material to be worn away before regrinding. The distance along the axis of symmetry x between the first point a and the second point b is comparatively greater. The insert can thus be described as an insert that is to be reground after a lower volume of hard metal has been worn away, i.e. more often than the insert according to the present invention.
Number | Date | Country | Kind |
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0901268 | Oct 2009 | SE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/SE2010/051053 | 10/1/2010 | WO | 00 | 3/23/2012 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2011/043717 | 4/14/2011 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4271917 | Sahley | Jun 1981 | A |
4607712 | Larsson | Aug 1986 | A |
4776413 | Forsberg | Oct 1988 | A |
5794728 | Palmberg | Aug 1998 | A |
20010040053 | Beuershausen | Nov 2001 | A1 |
20050109546 | Stowe et al. | May 2005 | A1 |
20080149399 | Koch et al. | Jun 2008 | A1 |
Number | Date | Country |
---|---|---|
56126563 | Oct 1981 | JP |
07-293173 | Nov 1995 | JP |
2002-242577 | Aug 2002 | JP |
2100561 | Dec 1997 | RU |
526 439 | Sep 2004 | SE |
531596 | Apr 2009 | SE |
WO-9612086 | Apr 1996 | WO |
WO-0229198 | Apr 2002 | WO |
WO-2004080651 | Sep 2004 | WO |
WO-2009045142 | Apr 2009 | WO |
Entry |
---|
PCT/ISA/210—International Search Report—Dec. 22, 2010. |
PCT/ISA/237—Written Opinion of the International Searching Authority—Dec. 22, 2010. |
Chinese Patent Office—First Office Action W/ Translation—May 14, 2014 (Issued in Counterpart Application No. 201080044592.7). |
Japanese First Office Action (With Translation) (Issued in Japanese Patent Application No. 2012-533114)—Jan. 7, 2015. |
Number | Date | Country | |
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20130048387 A1 | Feb 2013 | US |