DE1102612B - Device for measuring and monitoring the speed of the on-site hydraulic drive motor of a deep drilling device - Google Patents

Description

The invention relates to a device for measuring and monitoring the speed of the before Locally arranged hydraulic drive motor of a deep drilling device.

In deep drilling technology, drilling turbines are now used, which are acted upon by the flushing fluid will. The turbine is located directly above the drill, i.e. deep down in the borehole. The rinsing liquid, which also serves as working fluid, is through the tubular drill rod of the Pumps standing above the surface are fed to the drilling turbines. Once this working fluid has its energy delivered to the drilling turbine, it rises in the annulus between the tubular drill pipe and the borehole wall back up, is cleaned there and sucked in again by the pumps.

Drilling deep in the ground is a very complicated job. The running characteristics of a drilling turbine is highly dependent on the speed. From this it can be seen that with a reliable speed indicator the operation in the borehole can be controlled in such a way that the best efficiency is always achieved.

The display has become known by electrical means. However, this display method is not very Reliable.

According to the invention, a significant improvement is achieved in that with the drive motor a known hydraulic pulse generator is connected, whose frequency depends on the speed the drive motor-dependent impulses applied to a monitoring device via the working fluid, which is connected to the hydraulic line outside the borehole.

The transmission of sound pulses through strands of water is known per se, e.g. B. in ship command systems. Electric sound transmitters and sound receivers are also known, the electrical currents in Convert sound and, conversely, convert sound back into electrical currents. These latter plants are also used on ships. In the case of deep drilling devices, however, this is hydraulic impulses not yet proposed. But it is particularly useful for this area because at the depth of the bores, the great speed of propagation can be used particularly well by sound waves in the liquid of around 1400m / sec can. The impulses arrive very quickly after days where they are sufficiently sensitive Receiving apparatus are included.

The turbine speed is always set according to the turbine power and the drilling pressure. The turbine power is proportional to the pump energy and is normally kept constant. The drilling pressure

Device for measuring and monitoring the speed of rotation of the on-site

hydraulic drive motor

a deep drilling device

Applicant:

Salzgitter machines
Aktiengesellschaft, Salzgitter-Bad

Eli Abow, Vladimir Schulgin

and Vladimir Varlamov, Moscow,

have been named as inventors

on the other hand, the drilling progress, which is not immediately recognizable, is subject to constant changes and must are continuously adjusted.

In the. Drawings the invention has been shown as an example.

Fig. 1 shows a side view or a longitudinal section through the turbine part;

Fig. 2 is a longitudinal section through a detail of the turbine;

3 is a section also through a component part of the turbine;

Fig. 4 is also a section through an individual part of the turbine.

Fig. 5 shows part of the apparatus above ground, namely a tongue rate meter, which is connected to the hydraulic line is connected;

Figure 6 illustrates another surface display device.

First, the drilling turbine itself will be described; that known machine for on-site propulsion of the drill in deep earth boreholes equipped with the measuring apparatus according to the present invention is or is regulated with the control equipment connected to it.

According to FIG. 1, the drilling turbine consists of the rotor with its shaft α and the stator with its housing b. The shaft α is supported several times. Only the upper bearing, which serves as both a transverse bearing and a longitudinal bearing, and the lower bearing, which is only designed as a transverse bearing, are shown.

The upper bearing consists of disks e, which are fixed in the housing b and disks f, which are on the

109 530/339

Shaft α sit. The disks e are reinforced with rubber or another elastic material r so that the disks / do not run on the steel disks e , but on this cladding. As can be seen from the drawing, the shaft σ can move neither in the axial nor in the radial direction, since the casing r rests against the corresponding parts of the shaft α in both directions. The lower bearing, an Ouer-bearing, consists of the one which is also designed to be elastic. Lining s in which the liner t, which is tightly seated on the shaft, is supported.

The turbine stages u and v sit between the upper bearing and the lower bearing. Here u are the guide vane rings, which are fastened to the housing b , undz 'the rotor blade rings, which sit on the shaft a. The working fluid flowing through the turbine, coming from above in the direction of the arrow, is controlled by the guide vanes. 11 deflected so that they enter the underlying rotor blades ν with one flow direction at a certain angle. The rotor blades ν are again curved in such a way that the working fluid flowing through gives off part of its energy here and with an exit direction precisely determined by the position of the rotor blades ν passes into the next below guide vanes u .

In the usual drilling turbines there are up to 100 such turbine stages, each of which consists of a guide vane ring and a rotor blade ring, connected in series.

If the working fluid has given its mechanical energy to the rotor blades, it emerges from the last rotor blade ring ν at the bottom of the turbine blading and flows in the direction of the arrow into the turbine shaft a, which is hollow at the bottom at w , in order to get from here into the drill bit, which follows χ is screwed to the turbine shaft α. In the drill bit, the working fluid then only serves as a flushing fluid for flushing the borehole clean. It flows upward in the borehole outside the turbine housing b.

The drill pipe is screwed on at the upper end of the turbine housing at y.

It is a special character of the drilling turbine, that the drill string is stationary while only the Türbinenwelle α with the bolted at χ drill bit rotates, so that α in this manner, the turbine shaft on the bottom hole makes the actual drilling operation.

Fig. 2 shows the head of a drilling turbine which operates in the borehole directly above the bottom of the borehole. α is the turbine shaft that carries the drill below, b is the turbine housing, c are built-in components in the turbine housing, which at d allow the flushing and working fluid to pass in the direction of the arrow and at e have inwardly protruding disks which serve to support the turbine shaft seated disks / and thus take over the pressure of the drill and the turbine blades (not shown below ) arising in the longitudinal direction of the shaft a, g is the fixed perforated disk of the pulse generator, h is the disk of the pulse generator that rotates with the turbine shaft α .

Fig. 3 shows a ring section through the disks of the pulse generator. In the fixed disk g are the openings! mounted in the axial direction so that the liquid can pull straight through. The openings k are provided obliquely in the rotary disk h so that the liquid flowing through is not carried along or carried along only by a small amount in the direction of rotation (arrow).

Fig. 4 shows the corresponding pulse generator disks, designed as a turbine stage, namely h as an impeller and g as a stator. Here, too, the blades, corresponding to the movement of the liquid and the rotating disk, are directed obliquely and curved in order to act as a turbine stage, ie to generate torque.

In FIGS. 5 and 6, the apparatuses above ground are shown on a smaller scale in a diagram. The flushing and working fluid flows through the pipeline in the direction of the arrow. 1 is the membrane that has to absorb the impulses from the liquid. In Fig. 5 this membrane is directly connected to the mechanical reed frequency meter m . In Fig. 6, the telephone-like apparatus is housed in the housing η , which converts the mechanical vibrations of the membrane 1 in a known manner into electrical voltage surges. These electrical surges are amplified in the amplifier 0 in a known manner and then transmitted to the display instruments p, q and ζ , p is the mentioned pointer instrument of known design, q is an acoustic instrument, such as a buzzer or a loudspeaker of known design, and 3 is a reed frequency meter in which, however, the measuring reeds are excited electromagnetically. Either of these indicators can be used alone or in any combination.

Claims (8)

Patent claims: 1. Device for measuring and monitoring the speed of the on-site hydraulic Drive motor of a deep drilling device, characterized in that with the drive motor a known hydraulic pulse generator is connected, the frequency of which of the Speed of the drive motor dependent impulses via the working fluid a monitoring device act on, which is connected to the hydraulic line outside the borehole. 2. Apparatus according to claim 1, characterized in that the hydraulic pulse generator is designed as a sound generator Qi ₃ g) . 3. Apparatus according to claim 2, characterized in that the pulse generator Qi, g) formed as a sound generator consists of two or more perforated disks which can be moved relative to one another and are arranged coaxially close to one another. 4. Apparatus according to claim 3 with two perforated disks, characterized in that the one Perforated disk attached to the stator of the drive motor and the other perforated disk to its rotor is. 5. Apparatus according to claim 4, characterized in that the axes of the holes of the one Disc are arranged obliquely to the holes of the other disc (Fig. 3). 6. Apparatus according to claim 5, characterized in that the disc parts between the Holes are designed as blades. 7. Device according to claims 1 to 6, characterized in that the monitoring device is designed as a membrane-controlled tongue frequency meter (m) . 8. Device according to claims 1 to 7, characterized in that the monitoring device from a membrane that absorbs the sound impulses, one the membrane deflections in electrical device converting magnetic shocks, an amplifier and a downstream device, the frequencies visible or audible indicator or an indicator that responds to the frequencies Control device for the drill consists. Considered publications: German Patent Nos. 918 473, 703156; "Electricity in Mining", Issue 2/3, March 1943, 5 pp. 18/19. 1 sheet of drawings © 109 530/339 3.61