SE432280B - Coupling member for percussion drill line - Google Patents

Abstract

A coupling member is arranged to connect two successive elements 11, 13 in a percussion drill line. To achieve the best possible energy transfer through the coupling member 12, its impedance function is optimized. <IMAGE>

Description

80001384: 2 The transmission of shock wave energy through wave transmission systems has therefore been studied for a system which comprises an input element with constant impedance, a coupling means with variable impedance and an output element with constant impedance. The efficiency of the energy transfer, which is defined as the ratio between transmitted to incident wave energy, is maximized by optimizing the impedance function of the coupling means, ie the optimal distribution of the coupling means's mass over its length is determined.

This and other objects of the invention have been achieved in that it has obtained the features stated in the appended claims.

The invention is described in more detail in the following with reference to the accompanying drawings, in which various embodiments are schematically shown for exemplary purposes. These embodiments are intended only to illustrate the invention, which may be modified within the scope of the claims.

In the drawings, Fig. 1 seematically shows a shockwave transmission system in a percussion drill string.

Fig. 2 shows the shock wave generated by a cylindrical percussion piston.

Fig. 3 illustrates the impedance of the coupling member in a generally divided form.

Figs. 4 and 5 schematically illustrate conventional coupling means.

Figs. 6 - 12 schematically illustrate different embodiments of a coupling member according to the invention.

Fig. 13 shows an element included in a drill string. 8000458 ~ 3 3 Figs. 14 and 15 show coupling means corresponding to the embodiments schematically shown in Fig. 6 and Fig. 8.

The shock wave transmission system generally designated 10 in Fig. 1 comprises an input element 11, a coupling member 12 and an output element 13. A percussion piston 14 of a rock drilling machine emits an impact against the element 11. This can consist of an adapter included in the rock drilling machine or of the first splice rod 1 of a percussion drill string. When the invention is applied to splice drill rods, the coupling means 12 can be used to connect any of two successive drill rods.

When the percussion piston 14 hits the coupling member 11, the kinetic energy of the percussion piston is converted into shock wave energy. In hydraulic rock drills, the percussion piston 14 is usually cylindrical. Even in pneumatic rock drilling machines, the percussion piston can be considered as substantially equivalent to a cylindrical piston, since its enlarged funnel-shaped main portion is usually formed with a recess. A substantially rectangular shock wave 22, Fig. 2, is thus generated by the blow. If the length of the percussion piston 14 is LK, the length of the generated shock wave becomes 2 Lk.

The shock wave propagates through the road transmission system at the local speed of sound. Losses in the energy transfer occur due to reflections at inner surfaces 1 of the coupling member 12. The present invention intends to make these losses as small as possible by optimizing the shape of the coupling member.

In this optimization, the length and mass of the coupling member 12 are kept unchanged.

In conventional hydraulic rock drills, the ratio Lk: Lh 1 is of the order of 2.5. Lh denotes the length of a conventional splice sleeve. This ratio has therefore been used in the optimization of the shape of the coupling member 12. When shock waves propagate through rods, it has been found that the influence of variations in the cross-sectional area A, the modulus of elasticity E and the density f can be combined into a single parameter called impedance. The impedance Z is equal to A f C = AE / C, where C = (E / f F is the velocity of the shock wave. Any combinations of A, \ f and E corresponding to a certain value of the impedance Z should thus give the same result When the coupling means 12 is used to connect two identical successive drill rods, the impedances of the drill rods 11, 13 are the same.

As previously mentioned, the object of the present invention is to maximize the efficiency of the energy transfer / 2, whereby q is defined as the ratio between transferred to incident energy. If the impedance of the coupling member 12 were equal, well, like the impedances of the elements 11, 13, the efficiency / 2 would, at least in theory, be equal to 1. In practice, however, some minor losses are caused by the threaded connections between the coupling member 12. and elements ll, 13. The efficiency / I decreases for impedances above and below Z0. In conventional splice sleeves, their impedance is always greater than Zo.

The efficiency of energy transfer? is maximized according to the invention by seeking the optimal distribution of the mass of the coupling member over its length. This length is therefore divided into N segments and the impedance of the coupling means is thus divided into N constant impedances. Fig. 3 generally illustrates the impedance division.

The impedances 15, 16 of the elements 11, 13 are equal when two identical drill rods are connected to each other. If the element ll is an adapter in the rock drilling machine, the impedances 15, 16 can of course be different sizes, and are probably also so. The impedances of the segments of the coupling member 12 are denoted by the numbers 17-21.

The problem of determining the optimal impedance function is formulated as a non-linear programming problem, which is then solved numerically for arbitrary values of N by using the reduced gradient method. According to the invention, it has been found that the value of N affects the optimal shapes in a clear and regular manner.

Coupling means 12 have been studied for N = 1 to 9. The efficiencies corresponding to optimally trained coupling means have been compared with the efficiencies of coupling means with the same mass and with a constant impedance along the length. The ratio between the impedance of the studied coupling means and the previously mentioned impedance Zo is = 5. J Figs. 4 - 12 show the optimal mass distribution for N = 1 to 9. This is shown below in tabular form. This table also shows the ratio between the largest and the smallest impedance in each coupling means.

Fig.nr N I? Zmax / Zmin 4 1 0.620 1 5 2 0.620 1 6 3 0.804 52.8 7 4 0.803 29.3 8 5 0.855 50.2 9 6 0.879 70.3 10 7 0.89 60.0 ll 8 0.879 44.5 12 9 0.911 89, 2 It is remarkable that the optimal impedance distributions (or mass distributions when the coupling member is of the same material along its length) turn out to vary greatly between adjacent segments. Instead of a smooth transition, a marked large-small-large impedance distribution is obtained. It is also a common feature that large impedances always appear at the ends. In addition, the optimal shapes do not appear to converge towards a single shape for increasing N. This may be a result of the division itself. Due to the scope of the required calculations, there is a practical upper limit for N. 8000458-3 6 As can be seen from the table above, the efficiency increases with increasing N, with the exception of N = Y and N = 8, where the values are smaller than for N = 3 and N = 7, respectively. For N = 4 and 8, two equally small impedances are adjacent to each other.

It can also be seen from the above table that the ratio between the largest and the smallest impedance in the coupling means 12 is in the order of 30 to 90 for N = 3 to 9.

Experiments have been performed to verify some theoretical results regarding joints that are optimally designed with regard to the transmission of shock wave energy. The experimentally obtained results support the validity of the model used to obtain the theoretical results. The input and output rods used were identical. Such a rod 23 is shown in Fig. 13. The rod 23 is formed with a threaded end portion 24. In Fig. 14 a coupling member 25 is shown, which corresponds to that illustrated in Fig. 6. The coupling member 25 has two end portions 26, 27 with a large impedance and an intermediate portion with a considerably smaller impedance. The end portions 26, 27 are provided with threaded bottom holes 29, 30, which are arranged to receive the end portion 24 of the rod 23. Fig. 15 shows a coupling member 31, which corresponds to that illustrated in Fig. 8.

The coupling member 31 has two end portions 32, 33 and an intermediate portion 34 with large impedances and intermediate portions 35, 36 with small impedances.

According to the invention, it has also been found that the large and small impedances should preferably be equal to each other.

In the illustrated embodiments, the coupling means are made of the same material along their lengths, i.e. E are constant. As previously mentioned, the efficiency of the impedance Z is determined. It is thus possible within the scope of the inventive concept to form the coupling member with a constant diameter along its length and to vary the impedance by manufacturing the axially separated segments of the coupling member of different materials. , ie materials with different densities and modulus of elasticity E.

Due to the large diameter of a coupling member according to the invention, this can be used to advantage in splice drilling equipment for centering and guiding the drill string 1 in order to improve the straightness of the borehole. In this case, the coupling means can of course be used together with conventional splice sleeves.

It is to be understood that the schematically illustrated shapes of the coupling means may be varied within the scope of the claims.

It is only required that they be trained with a shape which has a mass distribution equivalent to the illustrated shapes.

Claims (10)

8300458 - 3 Patent claims Coupling means for connecting two successive elements (11, 13) in a percussion string, characterized in that the coupling means, when it is part of the percussion string, (25; 31), is formed with at least a large impedance change along its length, comprising at least a first portion (28; 35) having a lower impedance than the impedance of at least one of the elements and at least one second portion (26; 32) having a shaft axially separated from the first portion impedance than the impedance of said one element. Coupling means according to claim 1, characterized in that it comprises a third portion (27, 33) axially separated from the first and second portions, the third portion (27; 33) having a higher impedance than the impedance of said one element and wherein the first portion (28; 35) is arranged between the second (26; 32) and the third (27; 33) portion. Coupling means according to claim 2, characterized in that the second (26; 32) and third (27; 33) portions are arranged at axially opposite outer ends of the coupling means (25; 31). Coupling means according to one of the preceding claims, characterized in that the impedance changes along the length of the coupling means (25; 31) are sharp. Coupling means according to one of Claims 2 to 4, characterized in that the impedances of the second (26; 32) and third (27; 33) portions are substantially equal. Coupling means according to any one of claims 2-5, characterized in that it comprises a fourth portion (36) with a lower impedance than the impedance of said one element, wherein the fourth portion (36) and the first portion (35) ) are separated by a fifth portion (34) having a higher impedance than the impedance of said one element, preferably the first (35) and fourth (36) portions have substantially equal impedances and the second (32), third ( 33) and the fifth (34) party have substantially equal impedances. Coupling means according to claim 6, characterized in that the second (26, 32) and third (27; 33) portions are substantially equal in length, the first portion (28; 35) preferably also having the same length. Coupling means according to one of the preceding claims, characterized in that the portions included in the coupling means are made of different materials, they preferably having the same outer diameter. Coupling means according to one of the preceding claims, characterized in that portions with large and small impedances are arranged alternately along the length of the coupling means (31). Coupling means according to one of the preceding claims, characterized in that the ratio between the largest impedance in one of the parts of the coupling means and the smallest impedance in any of the portions is greater than 30, with preference for values greater than 40.