SE531086C2 - Device for rock drilling - Google Patents

Description

25 30 35 53'1 085 2 the shockwave movement takes place in both directions, a primary wave due to a piston stroke and a secondary wave a little later due to. a mountain reflex in the other direction. This causes local damage that easily initiates a break in the neck adapter because the stresses are so high. The problem is especially noticeable when drilling with high stroke frequencies. In this document, the word "front" indicates the part of the flush hole that is closest to the rock that is drilled in when drilling, and "rear" means the part of the flush hole that is furthest from the rock that is drilled in drilling.

SUMMARY OF THE INVENTION The object of the present invention is to provide a neck adapter with improved strength.

This object is achieved by a neck adapter in a rock drilling device.

The neck adapter is cylindrical and includes a mantle surface, a front end surface, a central axial passage opening at the front end surface, and a radial side coil hole extending from the central axial passage and mouthing the mantle surface. The side coil hole has an elongate cross section extending along a central axis from a front end of the side coil hole cross section to a rear end of the side coil hole cross section. The central axis is substantially parallel to the central axial passage. The front end faces the front end face of the neck adapter.

The cross-section of the side-coil hole is wing-shaped. The wing profile cross-section is divided into two partial cross-sections perpendicular to the central axis, so that each of the two partial cross-sections has a substantially equal part of the central axis. The two partial cross-sections comprise a front partial cross-section comprising the front end of the side coil hole cross-section, which front partial cross-section has a front cross-sectional area, and a rear partial cross-section comprising the rear end of the side coil hole cross-section, which rear partial cross-section has a rear cross-section. The wing profile cross-section is designed so that the front cross-sectional area is smaller than the rear cross-sectional area.

Since the cross-section of the side coil hole is wing profile-shaped and the wing profile-shaped cross-section is designed so that the front cross-sectional area is smaller than the rear cross-sectional area, the shock wave passage around the side coil hole in the neck adapter is facilitated. This means that the strength of the neck adapter is improved.

An advantage of the present invention is that it is easy to manufacture. 10 15 20 25 30 35 531 NOTE A further advantage of the present invention is that it enables a design of the cross-section of the side coil hole so that a large flow area for the coil medium is obtained.

An advantage of an embodiment according to the present invention is that more cavitation bubbles implode before they reach the area around the sensitive front and also the rear end of the side coil hole cross section in the neck adapter. BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic side view of a rock drilling device.

Figure 2 is a schematic view showing an axial cross section of a neck adapter according to the present invention.

Figure 3 is a schematic view showing a three-dimensional view of a neck adapter according to the present invention.

Figure 4 is a schematic view showing a radial cross-section of a side coil hole in a prior art neck adapter.

Figure 5 is a schematic view showing a radial cross-section of a side coil hole in a neck adapter according to the present invention.

Figure 6 is a schematic view showing a radial cross-section of a side coil hole in a neck adapter according to an embodiment of the present invention.

Figure 7 is a schematic view showing a radial cross-section of a side coil hole in a neck adapter according to a further embodiment of the present invention.

Figure 8 is a schematic view showing a radial cross-section of a side coil hole in a neck adapter according to a further embodiment of the present invention.

Figure 9 is a schematic view showing a radial cross-section of a side coil hole in a neck adapter according to a further embodiment of the present invention. 10 15 20 25 30 35 531 NOTE 4 Figure 10 is a schematic view showing a radial cross-section of a side coil hole in a neck adapter according to a further embodiment of the present invention.

Figure 11 is a schematic view showing a radial cross-section of a side coil hole in a neck adapter according to a further embodiment of the present invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS A number of embodiments of the invention will now be described with reference to the figures. The present invention is not limited to these embodiments. Different variants, equivalents and modifications can be used. Therefore, these embodiments are not to be construed as limiting the scope of the invention, the scope of which is defined by the appended claims.

Figure 1 shows a device for rock drilling 10. The rock drilling device 10 comprises a drilling machine 20, a number of drill rods 30, which are joined together and form a drilling string 40.

One end of the drill string culminates in a drill bit 50 which drills inwardly into the rock 52 as it strikes and rotates, thus forming a borehole 55. The other end of the drill string 40 is connected to the drill 20 via a neck adapter 60. The drill string 40 strikes, with reciprocating movements, and rotates during operation, driven by the drill 20.

To remove drill cuttings from the bottom of the borehole 55, the drilling machine comprises a spool device 70. A spool medium, e.g. water or air, is flushed with a flushing medium supply device 80 into via the flushing device 70 into a central axial passage in the neck adapter 60 and further through a central hole in the drill string 40 and out through the drill bit 50 to the bottom of the borehole 55. The drill cuttings mixed with the flushing medium are then forced out through the borehole 55 between the drill string 40 and the borehole wall.

Figure 2 shows a schematic cross-section of the neck adapter 60 seen from the side and Figure 3 shows a schematic three-dimensional and transparent sketch of the neck adapter 60.

The neck adapter 60 is cylindrical and includes a sheath surface 110, a front end surface 115 and the central axial passage 120 which opens at the front end surface 115. The front end surface 115 is adapted to connect the central axial passage 120 to the central hole in the drill string 40, t .ex. by threading the drill string 40 to the front of the neck adapter 60. The neck adapter 60 also includes a radial side coil hole 130 extending from the central axial passage 120 and opening into the jacket surface 110. A coil medium is coiled through the side coil hole 130, the arrow 140 shows the coil medium movement 10 15 20 25 30 35 531 086 5 the side coil hole 130. When a shock wave propagates after a blow fl, the neck adapter 60, ie. each cross-section of the neck adapter 60, rapidly a short distance 150, a so-called shockwave displacement 150 in axial direction along the center axis 160 of the neck adapter 60. The shockwave displacement is normally of the order of about 1 mm. The dashed lines in Figure 2 show the neck adapter 60 in the position before it has been moved the short distance 150, the distance is drawn here excessively large for better visibility. The neck adapter 60 is made of a suitable material, preferably of steel.

Part of the invention of the present invention lies in analyzing and understanding the problem. The cavitation bubbles in particular have a tendency to accumulate at the front part of the coil hole and implode there, the number of damages is also greatest at the front part. To analyze the problem by looking at the voltage picture in the neck adapter, Figure 4 shows a cross section of a known neck adapter 400 comprising a central shaft 405. The neck adapter 400 has a side coil hole with a conventional elongate cross section 410 extending along a center axis 415, which center axis is parallel to the central axis 405 of the neck adapter 400.

The cross-section of the side-coil hole 410 has a length L along its central axis and a width w which is partly constant and partly varies along the central axis 415 of the side-coil hole cross-section. The rock 420 to be drilled is shown on the right in Figure 4, which means that the drill and the neck adapter 400 strike in that direction during percussion drilling in the rock 420, i.e. to the right in Figure 4.

The shock wave displacement formed during impact drilling fl moves the neck adapter 400 in the same direction, ie. to the right in Figure 4.

The shock wave gives rise to a voltage flow in the neck adapter material. The pillars, i.a. arrows 430, 440 and 450 in the neck adapter 400, represent the magnitude and direction of the voltage flow in the neck adapter 400 during a shockwave movement. o = F / A [1] where c is the voltage, F is the force of the blow and A is the area, ie. the neck adapter's 400 cross-sectional area. o = E * e [2] where E is the modulus of elasticity of the material of which the neck adapter 60 is made and a is the elongation of the material.

The propagation speed c of the shock wave in the neck adapter can be calculated from the equation c2 = E / p [3] where p is the density of the material that the neck adapter 60 is made of.

The propagation speed c of the shock wave in the neck adapter 60 if it is made of steel is e 5100 m / s.

The duration of the shock wave is in the order of a few tenths of a millisecond.

The shock wave causes the neck adapter 400 to be compressed, which gives rise to a voltage field in the neck adapter 400, see equation [2]. A good distance to the left of the side coil hole 410 is the voltages compressive voltages which are homogeneous over the entire cross section of the neck adapter, see e.g. arrow 430. Closer to the left side of the side coil hole 410, the voltage flow is forced around the side coil hole 410, see e.g. arrow 440. There, the cross-sectional area of the neck adapter 400 decreases and thus the compressive stress cs increases, see equation [1] and arrow 445. However, increased compressive stress usually does not cause any major problem and is therefore not so harmful. To the right of the side coil hole 410, the cross-sectional area of the neck adapter increases and the voltage cs decreases again, see equation [1]. During a transition distance, however, similar to the water vortices that form behind e.g. a sailboat traveling through the water, "voltage vortices" locally closest to the side coil hole 410, i.e. closest to the right of the side coil hole 410, which is because the cross-sectional area of the neck adapter 400 increases very sharply to the right of the side coil hole 410. This in turn is due to 410 cross-section has a transverse end towards the rock side, i.e. the side coil hole 410 which is elongated has a constant width W along a large central portion of its length L, but the width W decreases sharply during a very short part of the length L. These stress vortices mean that the compressive stresses exceed to tensile stresses, which is shown in Figure 4 by the arrows bending in the opposite direction, see for example arrow 450. Ie compressive stress means that the tension arrow is directed to the right in Figure 4 and tensile stress means that the tension arrow points to the left in Figure 4. Tensile stresses carry a greater risk of damage to the neck adapter, especially if the area is already weakened by cavitation damage. that the material particles to the right of the side coil hole 410 cannot get a push of particles to the left because there are holes there, instead they are dragged into the shockwave displacement of their “neighbor particles” above, below and to the right. Pulls from the surrounding particles of course give a tensile stress in the neck adapter material. Since water lacks tensile strength, water vortices are formed in the boat likeness instead of tensile stresses.

Therefore, in order to improve the strength of the neck adapter, the cross-section of the side coil hole in the neck adapter should be designed so that "vortex formation" is minimized, ie so that as little tensile stresses occur as possible. Since draft from the surrounding particles gives a tensile stress in the neck adapter material similar to a vortex in the water behind a boat according to the above reasoning, special care should be taken in the design of the "stern" on the hole. wing profile means a streamlined shape, formed as the cross-section of a wing which is more blunt against the current and sharper with the current. lecture ongoing recovery. The neck adapter 60 comprises a front part 515 which, when drilling, faces the rock 520 to be drilled. The rock 520 to be drilled is thus shown on the right in Figure 5, which means that the drill and the neck adapter 60 strike in that direction during percussion drilling in the rock 520, i.e. to the right Figure 5. The shockwave displacement that is formed during impact during drilling, moves the neck adapter in the same direction, ie. to the right in Figure 5. As mentioned above, the shock wave gives rise to a voltage flow in the steel. Pilama, b.a. arrows 530, 540, 545 and 550 in the neck adapter 60 represent the voltage output of the neck adapter 60 at a shockwave passage.

By designing the cross-sectional hole 510 of the side-coil hole, on the side of the maximum width W of the cross-section 510 facing the rock 520, i.e. with a long and tapered shape with a sharper finish, ie. with a smaller radius than W / 2 in the end, the zone with stress vortices with associated tensile stresses becomes smaller, see the area to the right of the cross-section of the side coil hole 510, e.g. arrow 550. In the reasoning with the boat analogy, the rock side of the cross-pole hole cross-section 510 is that which corresponds to the stern. When the side coil hole 130 has a wing profile shaped cross-section 510, the increase in the cross-sectional area of the neck adapter to the right of the maximum width W of the coil hole is not so abrupt, which means that the compressive stress can decrease in a controlled manner along the side coil hole 130. tensile stresses, compared to the conventional neck adapter 400. This is favorable for the strength of the neck adapter 60. To facilitate the manufacture of the side coil hole 130, it is advantageous if the cross section 510 of the side coil hole 130 is rounded and not too pointed at its outermost end 550 facing the rock. This means that the cross-sectional area of the neck adapter 60 will admittedly increase sharply on the side of the front end 510 of the side coil hole 510 facing the rock, but even if the increase is transverse, it is not particularly large. in the zone after, i.e. to the right of the tapered cross-sectional shape 510 of the side-coil hole 130, the same high compressive stress level is no longer left as in the known neck adapter in Figure 4, thus the harmful tensile stresses are greatly reduced. Testing of the neck adapter with this wing profile shape shows that the damage is significantly reduced.

The cross-section 510 of the wing profile-shaped side coil hole is shown in Figure 6 and can be described as follows. The cross-section 510 is elongate and extends along a central axis 610 from the front end 560 of the cross-section 510 facing the front part of the neck adapter 60 (515 in Figure 5) towards the rock side, to a rear end 630 of the cross-section 510 facing from 53 35! constantly and partially vary along the center axis cross section 610 of the side coil hole. In a description model of the side coil hole cross section 510, the cross section 510 is divided into two partial cross sections, perpendicular to the center axis 610 The 510 can also be divided into more than two partial cross-sections, as in embodiments later in this document.The at least two parts include a front partial cross-section 640 and a ba The front sub-section 640 includes the front end 560 of the side coil hole cross-section 51, and the rear sub-cross section 650 includes the rear end 630 of the side hole cross-section 510. The front sub-cross section 640 has a front cross-sectional area 650 cross-section, and the rear sub-section 650 has a cross-section. a rear cross-sectional area 670. The wing-shaped cross-section 510 is designed so that the front cross-sectional area 660 is smaller than the rear cross-sectional area 670, i.e. so that the front cross-sectional area 660 is more pointed in the direction of the rock and the rear cross-sectional area 670 is more obtuse in the direction from the rock.

The wing profile-shaped cross-section 510 of the side coil hole can be manufactured in a number of different embodiments. The cross-section of the side coil hole 510 has a length L extending along the central axis 610 of the coil hole cross section and a width w which is perpendicular to the length L and which varies wholly or partly along the length L. In some embodiments as in the example shown in Figure 6, length L is more than or twice as long as the maximum width W at the widest point along length L. This is advantageous as it provides low stress concentrations around the side coil hole and a large flow area for the coil medium if the long length can be allowed with regard to surrounding construction.

Some embodiments, such as e.g. the one shown in Figure 7, may have a side coil hole having a wing profile shaped cross section 510 with a short length L, e.g. a length L which is less than twice as long as the width w at the widest point along the length L. If a short side coil hole is desired, this shape is advantageous because it gives the side coil hole cross section 510 a large flow area for the coil medium, despite a side coil hole with small axial extent .

In some embodiments such as e.g. the one shown in Figure 6, Figure 7 and Figure 8 decreases the width w of the wing coil-shaped cross-section 510 of the side coil hole successively over a large part of the length L of the cross coil hole 510 on the side comprising the front end 560 ÜBB 9 end 560, for example under more than half of the side coil hole cross section 510 length L, which gives a very favorable voltage position with very little vortex formation, ie. very little tensile stresses.

The wing coil-shaped cross-section 510 of the side coil hole can, in order to describe some embodiments in a simple manner, such as e.g. those shown in Figure 7, Figure 8, Figure 9, Figure 10 and Flgur11, include a center portion M along the center axis 510 of the side coil hole 510. The center portion M extends along the length L of the side coil hole 510 from a front point 710 at a distance from the front end 560 to a rear point 720 at a distance from the rear end 630.

The width w of the center portion is in some embodiments designed so that it gradually decreases along the center portion M the closer to the front end 560 it comes, from a first width w, at the rear point 720 along the center axis 610 of the side coil hole to a second width w2 at the front point 710, where the second width w; is smaller than the first width w1.

In some embodiments, the decreasing width is from w1 to w; along the central portion M, convexly shaped such as e.g. the embodiment shown in Figure 7. Such an embodiment of a side coil hole 130 provides the advantage of relatively low voltage concentrations around the side coil hole as well as a large flow area for the coil medium. In some embodiments, the decreasing width from w1 to w2 along the central portion M is rectilinearly shaped such as e.g. the embodiment shown in Figure 8. This is an advantage because a side coil hole 130 with such an embodiment is easy to manufacture. In some embodiments, the decreasing width from w1 to wz along the center portion M, is concavely shaped such as e.g. the embodiment shown in Figure 9. Such an embodiment of a side coil hole 130 provides the advantage that a larger portion of the resulting cavitation bubbles more easily strike the inside of the side coil hole 130 because the inside folds inwardly into the side coil hole 130. When the cavitation bubbles strike an inner wall, the probability increases that they implode due to the impact before reaching the far end of the cross-section of the side-coil hole 560.

This further reduces the risk of injury at the area of the neck adapter 60 around the sensitive front end of the side coil hole cross section 510.

The middle portion M is in some other embodiments, such as e.g. the embodiments shown in Figure 10 and in Figure 11, designed so that the width w is constant W along the central portion M from the rear point 720 along the center axis 610 of the side coil hole to the front point 710. Making the side coil hole cross section 510 in such a manner the advantage that it is easy to manufacture and also provides a large flow area for the rinsing medium. In order to describe some embodiments, such as e.g. those shown in Figure 10 and Figure 11, simply include a front portion F along the center axis cross-section of the side coil hole 610. The front portion F extends along the length L of the side coil hole 510 from the front point 710 to the front end 560.

Since the cross-section 510 of the side coil hole is wing-shaped, the width w of the front portion, in all embodiments, is designed to gradually decrease along the front portion F the closer to the front end 560 it comes, from a third width w, at the front point 710 along the center axis (610) of the side coil hole up to a fi fourth width w., at the front end 560, which fourth width w., is zero and is therefore not visible in Figures 10 and 11. The fourth width w, is thus less than the third width w3.

In some embodiments, the decreasing width from wa to w., Along the front portion F, is convexly shaped such as e.g. the one shown in Figure 10. Such an embodiment of a side coil hole 130 provides the advantage of a large flow area for the coil medium.

In some embodiments, the decreasing width from wa to w., Along the front portion F, is rectilinearly shaped such as e.g. the one shown in Figure 11. Such an embodiment of a side coil hole 130 provides the advantage of simple manufacture.

The decreasing width from w, to w., Along the front portion F can also be concavely shaped (not shown).

The cross-section of the side coil hole 510 can, to describe some embodiments, such as e.g. those shown in Figure 11, simply include a rear portion B along the center axis 610 of the side coil hole, with a length LB. The rear portion B extends along the length L10 of the side coil hole 510 from the rear point 720 to the rear end 630.

It is advantageous to also take into account the voltage waves that propagate in the other direction, ie. in the direction from the rock 420, due to the fact that the original voltage waves can be at least partially re-reflected towards the rock. In that case, it is the rear part B that is the "stern of the boat". It still applies that the front cross-sectional area is smaller than the rear cross-sectional area because it is most advantageous in the normal load case which occurs at each piston stroke. It is thus advantageous to design the rear portion B so that it does not end too abruptly, e.g. by designing the rear portion B so that its length LB is greater than half the cross-sectional width 510 W of the side coil hole, i.e. LB is greater than W / 2. in the center axis of the side coil hole 130 may be perpendicular to the center axis 160 of the neck adapter 60 or angled forward or backward along the center axis 160 of the neck adapter at an angle which is preferably between 45 ° and 90 ° forward or backward. To further reduce the cavitation 1031, the edges of the radial side coil hole 130 of some embodiments are angled so that the cross section 510 of the side coil hole is larger or smaller at its mouth on the jacket surface 110 than at the connection to the central axial passage 120.

In the above reasoning, reference has only been made to figures showing that the cross section 510 of the side coil hole is symmetrical with respect to the center axis 610, but the present invention also includes the alternative that the cross section 510 is asymmetrical with respect to the center axis 610.

Claims (1)

1. 0 15 20 25 30 35 531 088 12 PATE NTKRAV Neck neck adapter (60) in rock drilling device, which neck adapter (60) is cylindrical and comprises a jacket surface (110), a front end surface (115), a central axial passage (120). ) opening at the front end face (110), and a radial lateral bore (130) extending from the central axial passage (120) and opening into the shell surface (110), said lateral bore (60) having an elongate cross-section (510) which extends along a central axis (610) from a front end (560) of the side coil hole cross section (510) to a rear end (630) of the side coil hole cross section (510), which center axis (610) is substantially parallel to the central axial passage ( 120), and where the front end (560) faces the front end surface (115) of the neck adapter, characterized in that the cross section (510) is wing profile shaped, that the wing profile shaped cross section (510) is divided into two partial cross sections perpendicular to the center axis (610), that each of the two sub-sections has essentially the same long part of the central shaft (610), which two partial cross-sections comprise a front partial cross-section (640) comprising the front end (560) of the cross-section of the side coil hole (510), which front partial cross-section (640) has a front cross-sectional area (660), and a rear partial cross-section (650) comprising the rear end (630) of the cross-section of the side coil hole (510), which rear partial cross-section (650) has a rear cross-sectional area (670), and that the wing profile-shaped cross-section (510) is designed so that the front cross-sectional area (660) is smaller than the rear cross-sectional area (670). . The neck adapter (60) of claim 1, wherein the cross-section of the side coil hole (510) comprises a length (L) extending along the center axis (610) of the coil hole cross section and a width (w) perpendicular to the length (L) and partially varying along the length (L), and where the length (L) is more than or twice as long as the width (w) at the widest point along the length (L). . The neck adapter (60) of claim 1, wherein the cross-section of the side coil hole (510) comprises a length (L) extending along the center axis (610) of the coil hole cross section and a width (w) perpendicular to the length (L) and partially varying along the length (L), and where the length (L) is less than twice the width (w) of the widest point along the length (L) - 10 15 20 25 30 35 10. 11. 531 BBB 13 Neck adapter (60) according to any of claims 2-3, wherein the width (w) of the side coil hole cross section (510) gradually decreases along a part of the side coil hole cross section length (L,) on the side of the lumbar (L) including the front end (560) Neck adapter (60) according to claim 4, wherein the width (w) of the side coil hole cross section (510) gradually decreases along more than half the length of the side coil hole cross section (510) (L) - Neck adapter (60) according to any one of claims 1-5 wherein the side coil hole cross section (510) comprises a central portion (M) along the central axis (610) of the side coil hole, which center portion (M) extends along side coil holes the length (L) of the cross-section (510) from a front point (710) at a distance from the front end (560) corresponding to the radius of curvature of the cross-section of the front coil hole, to a rear point (720) at a distance from the rear the end (630) corresponding to the radius of curvature at the rear end of the cross-section of the side-coil hole. The neck adapter (60) of claim 6, wherein the width (w) of the side coil hole cross section (510) at the center portion (M) is formed so that the width (w) gradually decreases along the center portion (M) the closer the front end (560) the width (w). ) is, from a first width (w,) at the rear point (720) along the center axis (610) of the side coil hole to a second width (w2) at the front point (710), where the second width (wz) is less than the first width (w,). in Neck adapter (60) according to claim 7, wherein the decreasing width (w1-w2) along the middle portion (M) is convexly shaped. Neck adapter (60) according to claim 7, wherein the decreasing width (w1-w2) along the middle portion (M) is rectilinearly shaped. Neck adapter (60) according to claim 7, wherein the decreasing width (w1-w2) along the middle portion (M) is concavely shaped. The neck adapter (60) of claim 6, wherein the width (w) of the center portion is designed so that the width (w) is constant along the center portion (M) from the rear point (720) along the center axis (610) of the side coil hole to the front point (710) . A neck adapter (60) according to any one of claims 1-5, wherein the cross section of the side coil hole (510) comprises a central portion (M) along the center axis (610) of the side coil hole of the side coil hole. , which middle portion (M) extends along the length of the side coil hole (510) (L) from a front point (710) at a distance from the front end (560) corresponding to one third of the length (L) of the side coil hole, to a rear point (720) at a distance from the rear end (630) corresponding to the radius of curvature of the rear end of the side coil hole cross section, and where the side coil hole cross section (510) includes a front portion (F) along the center coil cross section (610) of the side coil hole, (F) extends along the cross-sectional length (L) of the side coil hole from the front point (710) to a point just before the front end (560). The neck adapter (60) of claim 12, wherein the width (w) of the side coil hole in the front portion (F) is formed so that the width (w) gradually decreases along the center axis (610) of the side coil hole in the front portion (F) the closer to the point just before the front end (560) the width (w) comes, from a third width (wa) at the front point (710) along the center axis (610) of the side coil hole to a fourth width (w4) at the point just before the front end (710) 560), where the fourth width (w4) is less than the third width (ws). Neck adapter (60) according to claim 13, wherein the decreasing width (w3-w4) along the front portion (F) is convexly shaped. The neck adapter (60) of claim 13, wherein the decreasing width (w3-w4) along the front portion (F) is rectilinearly shaped. Neck adapter (60) according to claim 13, wherein the decreasing width (w3-w4) along the front portion (F) is concavely shaped. . Neck adapter (60) according to any one of claims 1-16, wherein the cross-section of the side coil hole (510) comprises a rear portion (B) along the central axis (610) of the side coil hole, with a length (LB), where the rear portion (B) extends along the length (L) of the side coil hole (510) from the rear point (720) to the rear end (630), and where the rear portion is formed with a length (LB) greater than half the width of the side coil hole (W). A neck adapter (60) according to any one of claims 1-17, wherein the edges of the radial side coil hole (130) are designed so that the cross section (510) of the side coil hole is larger at its mouth on the casing surface (110) than at the connection to the central axielia passagen (120). A neck adapter (60) according to any one of claims 1-18, wherein a center axis of the side coil hole 130 has an angle to the center axis (160) of the neck adapter (60) that is between 45 ° and 90 ° forward or backward along the center axis (160) of the neck adapter. . Drilling device (10) for rock drilling, which drilling device (10) is characterized in that it comprises a neck adapter (60) according to any one of claims 1-19.