DE3609986A1 - SUBSTRATE PRESSURE GAUGE - Google Patents

Description

The invention relates to an underground pressure gauge for Monitoring reservoir pressures in land and sea oil wells. In particular, the invention relates to the Pressure gauges provided clock mechanism.

Underground pressure gauges usually have a mechanical watch or clock link with a gear and a differential gear or a restlessness caused by the unwinding of a spring is operated. The unwinding movement of the spring leads to a linear / Axial movement of a drum through a leading, straight Worm or screw shaft (lead screw / straight shaft), and a diagram of paper or metal is on the inner surface provided the drum. The total length of the drum is during of the measuring cycle. The underground pressure gauge also has a Bourdon or pressure tube for operating a pen for recording the pressure on the drum. It is known that the rotation of the Bourdon tube is directly proportional to the pressure applied to it, causing the movement of the Pen matches this print. Such a pressure reading becomes time-dependent due to an axial / linear displacement of the drum recorded.

A subsurface pressure gauge with a mechanical clock for effecting an axial / linear movement of the drum has several Disadvantage. One such disadvantage is that the drum a continuous movement as opposed to a selective one Has movement. Because the spring is unwound continuously and the drum is moved by this unwinding of the spring , it is obvious that the drum is not selective or programmable movement can be granted. This results in Limitations on the quality of pressure readings on the Drum. It is also because of the continuous drum movement not possible to get sample pressure readings for the periods, which are considered useful or critical periods.  

It is well known that underground pressure gauges have a be kept under the surface for a considerable period of time. When the drum is in a constant state of motion, the pressure on the drum is recorded by the Time of introduction of the measuring device into the underground until Time of subtraction. If such a period, for example Is 200 hours and the chart length is only 127 mm (5 inches), the pressure for the full period of 200 hours pushed into such a short diagram length. Accordingly can a fine resolution of the time-dependent pressure measurements cannot be reached. Furthermore, a pressure reading is for any certain period of time not easily identifiable and retrievable. Thus, such dimensions mainly provided a pressure behavior and no pressure reading in relation to a certain one Time.

Usually the pressure values are more critical in the initial stages and more important than in the last period, if such Pressure is normally stabilized. If the drum is therefore in a continuous state of motion adequate pressure readings only for the initial period not to be scanned.

The terms sampling or trial period used here mean those periods where the pressure reading is related should have a particularly good resolution over time. The Pressure is said to be at any particular time during such Trial period easily identifiable and readable from the diagram be.

Another disadvantage is the loss of diagram space, firstly during the period when the pressure gauge is up to the required Depth is lowered, and secondly during the period, where the pressure gauge is raised to the surface. It it is obvious that during these periods a pressure measurement or - reading is not required. If the drum is in is in a constant state of motion, however, such No loss of chart space during the periods mentioned be avoided.  

Another disadvantage is the static bottom hole Pressure and then when the pressure is off by closing the duct builds up. In the known technique there is a certain time interval until a recognizable reading of the static bottom hole Pressure required. With a constant state of motion the drum is also recorded during this time interval.

The present invention has for its object an improved To create underground pressure gauges. This should be under Avoiding the disadvantages described an improved watch or have a clock element for driving the drum.

According to the invention, an underground pressure meter has a housing a moving drum with a diagram, a link for moving a pen for recording of pressing on the chart and a motor that runs over a programmable switch connectable to a supply source is, the output shaft of the motor is a selective and programmable Forms drive for the drum.

The subsurface pressure meter has a housing with one arranged therein movable drum and a registration strip attached to it or diagram. This works with a pen together, driven by a link like a Bourdon tube becomes. These features of an underground pressure gauge are in known in the art.

Programmable means are within the scope of the present invention for selectively driving the drum. These programmable Means include a microprocessor connected to a motor drive circuit connected is. The engine is through the engine drive circuit connected to a supply source.

The invention is described below with reference to the drawings explained in more detail. Show it:

Figs. 1A and 1B - pressure recordings in accordance with the prior art with the mechanical watch and according to the present invention,

Figs. 2A and 2B - respectively the beginning and the end of a record corresponding to the pressure gauge of the prior art and the present invention,

Figs. 3A and 3B - recording a pressure drop corresponding to the pressure gauge of the prior art and the present invention,

Fig. 4 - the pressure gauge of the present invention,

Fig. 5 - a block diagram of the circuit of the programmable switch,

FIGS. 6 and 7 - a sample rate with respect to the pressure gauge of the prior art and the present invention and

Fig. 8 - the switch circuit according to the present invention.

Figure 1A shows a curve plot of approximately 127 mm (5 inches) which is intended to last for 40 hours, for example. The watch is held below the surface for 40 hours, and when the drum is in a constant state of motion, the recording for the entire period is made on a graph with a length of only 127 mm (5 inches). Various known disadvantages are associated with the known construction of a watch. One such disadvantage is that due to the constant state of motion of the drum, the resolution is poor, which increases proportionately with the increase in time. Another disadvantage is that the record for the full period while the meter is below the surface is contained on a curve length of 127 mm (5 inches), which means that the readings do not have good resolution for a certain time and the pressure is not easily identifiable for this period.

Reference is now made to FIG. 1B, which shows a curve recorded by the pressure gauge of the present invention. This has the same length of 127 mm (5 inches) for a recording period of 40 hours. As shown in Fig. 1A, the pressure increases rapidly in the initial period and thereafter becomes largely constant. Thus, one of the critical periods for determining and recording the pressure is the initial period that forms the sampling period, which should have a fine resolution. Since the drum of the present invention has a selective movement, it is driven only after certain time intervals so as to provide a dwell period A and a drive period B. As shown in FIG. 1B, the readings or measured values have a fine resolution during the trial period. At the end of the trial period, the dwell period A may increase progressively, as shown in Fig. 1B.

Reference is now made to Fig. 2A which shows the beginning and end of a recording. If the drum rotates continuously according to the known technique, recording is also made during the period of insertion and removal of the measuring device. Since such recordings are not required, there is a curve reject. Such a waste of the curve space is a particular disadvantage, especially when the entire recording length is long. This disadvantage is avoided with the pressure meter of the present invention, recording only when the curve or diagram according to FIG. 2B reaches the predetermined depth. In a similar manner, the recording ends when the measuring device is pulled off, as a result of which a curve committee is eliminated.

Reference is now made to FIG. 3A, which shows a graph for a pressure draw down, which was recorded with the known measuring device. Referring to FIG. 3A, the pressure between the times Q falls to Q ₁ is fast and thereafter gradually. From the curve of Fig. 3A, the pressure at any time period during time Q through Q _{1 is} not easily identifiable. In the contrast thereto, Fig. 3B shows the curve obtained with the inventive measuring device, and the pressure may at any time during the time Q to Q ₁ identified. Furthermore, there is complete utilization of the curve space, in contrast to utilization of only 50% of the curve space from FIG. 3A. These advantages result from the pressure meter according to the present invention, since the speed of the drum is variable compared to the known drum at constant speed.

Although it is not shown in the drawings, it follows similar advantages when measuring with the measuring device according to the invention of pressure increases or any other corresponding Measuring device examinations.

The measuring device G according to the invention has an elongated housing H in which a linearly displaceable curve drum D is arranged. The measuring device G also has a Bourdon tube T , to which a pen ST is connected. The Bourdon tube T actuates the pen ST according to the pressure. These details are known in the art.

In the present invention, as shown in FIG. 4, the output shaft M _{1 of} a motor M is coupled to the drum D to drive it so that it performs a linear movement. Any suitable and known means can be provided to convert the rotational movement of the shaft M ₁ into a linear movement of the drum D. The motor M is connected to a supply source (not shown) via a programmable switch S. Thus, the motor M is connected to the supply source only in the presence of a command signal to drive the drum D. The task of the programmable switch S is to drive the motor selectively or selectively. Referring to the sample period of FIG. 1B, drum D is programmed to move only after a time interval of, for example, 10 minutes each and to be in a moving state for only a very small certain period at each interval. According to Fig. 1B is carried out during a dwell period A no movement of the drum D, and only the stylus ST is in a state of motion. After each dwell period, drum D moves and record B is made . It can be seen that for any desired period to be sampled, such as the first hour, the sample period is recorded in the manner shown in Figure 1B. This results in a clear and definite reading of the pressure for the trial period, in contrast to the illustration from FIG. 1A, in which it is not possible to obtain a reading or a measured value for the trial period.

The programmable switch S from FIG. 5 has a microprocessor MI which can receive data control signals. The microprocessor MI distinguishes and identifies the signals, decodes the probe program from the signals and generates a switching sequence for a motor drive circuit MD . If these are in an actuation state, the motor M is connected to a supply source PS . The microprocessor MI receives a command signal from a signal means SM , and depending on this signal, the motor M is connected to the supply source. The signaling means SM can have a monochromatic light source, such as a light emission diode, which is detected by a sensor SE . In the presence of such a light signal, the sensor SE is conductive and the signal reaches the microprocessor MI . This recognizes and identifies the signals and, depending on the nature of the signal, a signal reaches the microprocessor MI . This is programmed accordingly by a programmer (not shown).

After the motor M has been actuated once, the microprocessor MI changes to the next state of the motor monitoring by means of a tachometer detection circuit TD . This detects the movement of the motor M and converts it into digital level pulses which are sent to the microprocessor MI . These pulses are counted by the microprocessor MI , and when the count corresponds to the programmed count, the supply to the motor drive circuit MD is interrupted. For this purpose, in addition to the input line IL provided between the microprocessor MI and the drive circuit MD , an interrupt input line BI is provided in between. When the count values of the digital level pulses correspond to the programmed count values, an interrupt signal is thus supplied from the microprocessor MI via the interrupt line BI and the output connections of the motor drive circuit MD are short-circuited.

It can be seen that the drum D is driven by the motor M and the programmable switch S in a certain selected manner. So far, the selective drive has only been referred to in the initial period, which represents the trial period. However, this reference was made only as an example. It should be noted that the drum D can be provided with a selective drive during any other period or during the entire recording period. A typical example in this context is shown in Table 1.

The time-related sample speed is shown in FIG. 6 in connection with the measuring device of the present invention (Table 1) and with the prior art. The graphical curve for the known measuring device is a straight line, and no trial period can be provided. The curve for the test speed of the measuring device according to the invention has a quick scan in the initial period, namely after every 90 seconds. This is necessary because the pressure increases in the initial period. After that and after the pressure gradually stabilizes, sampling or sampling is only effected after every 120 seconds and finally after every 240 seconds.

Table 2 shows a continuously changing sample rate.

Fig. 7 shows the curve of the time-related sample speed of the measuring device according to the invention (Table 2) and the prior art. The curve for the known measuring device is a straight line. However, the course for the measuring device according to the invention has a curve corresponding to the diagram of the pressure in the shaft (well). Such a continuously variable sample speed is preferred, and accordingly drum D should be moved faster in the initial period than in the final period. The speed should change in such a way that the curve of the time-related sample speed resembles the curve of the pressure curve over time, and thus there is an adaptation of the reservoir behavior.

Referring now to FIG. 8. An oscillator clock or clock element 2 , which is connected in parallel to a resonance crystal 1 , forces it to oscillate at its natural frequency. The sine wave thus obtained is implemented by the oscillator 2 to digital level timer / clock pulses and via conductor 1 ' to the microprocessor 6 ( MI of Fig. 5). The programs controlling the system are stored in the non-volatile read-only memory 13 and executed by the microprocessor 6 when the clock pulses are received. When the latter is started, the program forces it to wait for sampling control data from the programmer (external). The sampling control data includes the initial delay, dwell time, drive time, drive span, and terms of samples to be taken. This is effected by the programmer who flashes the corresponding code to the phototransistor 3 , which generates pulses on the conductor 2 ' . These are detected by a communication interface 5 , which forms the pulses and converts them to digital levels and passes them via an input 3 ' to the microprocessor 6 ; finally, it is stored in a read-write memory 14 . The communication from the microprocessor 6 to and from the memories 13 and 14 takes place via the address bus 14 ' and the address data bus 15' . The latter is subjected to a demultiplexing and latching operation (is demultiplexed and latched), so that the address bytes are separated by address latching elements 11 and 12 and are passed to the memories 13 and 14 via the demultiplexing address bus 17 ' . The memory control logic 10 receives memory control signals 11 ' from the microprocessor 6 and causes a selection of the memories 13 or 14 during the execution of the control program.

The microprocessor 6 , under program control, calculates the initial delay, dwell and drive times (as a link of clock pulses) for the sampling process and waits for these cases to occur by observing an internal time. When the drive time occurs, the microprocessor 6 sends the motor drive signal to the motor drive or brake circuit 7 ( MD of FIG. 5), which then responds by connecting the supply to the geared motor M. The rotation of the motor M is monitored by a tachometer detection circuit 9 ( TD of Fig. 5); there are tachometer output pulses 10 ' generated with digital level, which are counted by the microprocessor 6 . Each pulse 10 ' corresponds to a motor increment of the geared motor M , so that the special motor of the cam drum to be driven is monitored in a defined manner. After the programmed number of pulses 10 'has been received (i.e. the diagram has been moved over the desired range), the microprocessor 6 interrupts the motor drive signal 6' , and it outputs the motor brake signal 7 ' , which forces the motor drive / brake circuit 7 to do so to switch the engine power to ground and thereby brake the engine. The rotational energy of the rotor of the motor M is thus consumed resistively and reduced until the motor stops. The microprocessor 6 thus carries out the entire test process. External communication with the external programmer is achieved via an LED element 4 . From the microprocessor 6 , an output signal 5 'is generated and passed to the communication interface 5 , which translates these into current pulses 4' which drive the LED element 4 on the output side.

Table 1

Table 2

Claims (9)

1. Underground pressure gauge for measuring pressures in an oil well, characterized by an elongated housing ( H ) which has an axially displaceable drum ( D ) with a diagram, a pen ( ST ) working together with the drum, and one for moving the pen Bourdon tube ( T ) for effecting pressure recordings on the diagram and a motor ( M ) which can be connected to a supply source via a programmable switch ( S ), the output shaft ( M ₁ ) of the motor for selective drive of the drum worries. 2. Pressure gauge according to claim 1, characterized in that the drum ( D ) can be moved after selected time intervals by the programmable switch ( S ), the time intervals in the start period being shorter than in the end period. 3. Pressure gauge according to claim 2, characterized in that the drum ( D ) is movable during varying time intervals. 4. Pressure gauge according to claim 3, characterized in that the drum ( D ) has a test speed-time curve which corresponds essentially to the pressure-time curve of the oil well. 5. Pressure gauge according to claim 1, characterized in that the programmable switch has a microprocessor ( MI ), signal means ( SM ) for conducting a signal to the microprocessor, a motor drive circuit ( MD ) for receiving a signal from the microprocessor, a supply source ( PS ) and has a speedometer detection element ( TD ) connected between the motor ( M ) and the microprocessor ( MI ). 6. Pressure gauge according to claim 5, characterized in that the motor drive circuit ( MD ) contains a brake circuit, that a brake line ( BL ) is connected between the microprocessor ( MI ) and the motor drive circuit and that in the presence of a signal in this line, the output terminals of the motor drive circuit are short-circuited. 7. Procedure for measuring subsurface pressures on a diagram by means of a pen moving from a Bourdon tube , the diagram being moved by a motor that via a programmable switch with a supply source is connected, characterized in that the diagram is moved between selective dwell periods. 8. The method according to claim 7, characterized in that the residence period shorter for the initial readings or measurements as made for the final readings or measurements becomes. 9. The method according to claim 8, characterized in that the residence period between the initial and final readings or measured values is continuously changed.