SU506823A1 - Device for rapid joint processing of data from a geophysical well measurement complex - Google Patents

Description

pulses of depth, amplifier of magnetic cable labels and outputs of signals “magnetic label of reading devices, and outputs to the inputs of reading devices. The drawing shows a block diagram of the proposed device. The device contains an analog-to-digital converter 1, a multichannel device 2 for matching data depth of one measurement cycle, a digital recorder 3, an amplifier 4 of cable magnetic tags, a depth pulse shaping unit 5, a block for controlling the start of reading devices, a processing unit 7, reading devices 8 and 9, analog recorder 10. In the drawing, the long dotted line indicates the connections between the elements of the device during the first measurement (and processing) cycle, the solid line indicates the connections during the second measurement cycle rhenium (and processing) schtrih-dotted designated communication with data processing after measurement, short chain dotted line denoted magnetic mark signal. A multichannel depth matching device included in this device is used for logging complex downhole instruments with sensors displaced relative to each other. In this case, it is necessary to coordinate the depth of the data from these sensors. This is usually achieved by the fact that the information coming from all sensors, except the lowest one, is delayed with respect to the information coming from this last sensor by values corresponding to the spacing of the sensors. For this, for example, shift registers controlled by depth pulses can be used (in this case, the information is pre-converted to digital form). In the proposed device, the functions of the depth matching device are somewhat wider. The device works as follows. Let us assume for definiteness that in the first measurement cycle, a downhole tool is used, whose distance from the lowest located sensor to the first cable magnetic mark is greater than that of the downhole tool used in the second measurement cycle. Denote the indicated distances by HI and H, respectively. At the first measurement cycle (for example, induction logging and calipers), the original analog information received from the corresponding logging panel is digitized by converter 1 and recorded in digital device 3 after depth calibration, for example, on punched tape. The synchronization of the operation of converter 1, device 2 and recorder 3 is performed by depth pulses coming from unit 5. In order to avoid blocking the communication drawing of unit 5 with converter 1 and recorder 3, are not shown. At the same time, the signals of a cable magnetic tag, received from a magnetic marker head (not shown) and amplifiable amplifiers 4, are applied in the form of a specific code on the same carrier. Magnetic marks can also be recorded by an analog recorder. In parallel, calculations can be performed in data processing unit 7 for which data from one measurement cycle is sufficient (for example, determining the formation resistance with regard to the borehole diameter and mud conductivity). The results of the calculations are recorded by the analog recorder 10. During the second measurement cycle (for example, acoustic logging and measuring the potential of the PS), the initial information is digitized and consistent in depth as in the first cycle, but in this case device 2 is not only produced the depth of the data of all sensors of the squalvish device, except for the lowest one, to this last, but also the difference in the above distances HI and N. For this, the data of all the sensors, including the lower one, are delayed in The device 2 additionally HI - HZ is by the number of steps equal to D - the magnitude of the quantization step in depth. Simultaneously with the measurement, the data recorded during the first measurement cycle is inputted by the reader 8. The triggering of the SU is performed by depth pulses generated by the block 5 and fed to the SU drive input (hereinafter, to reduce the drive input, the SU is referred to as the SU input). Unit 5 is electrically connected to a selsyn sensor mounted on a block balance or other dimensional roller. The start control is carried out using block 6, the inputs of which receive pulses from block 5 and magnetic mark signals from amplifier 4 and from the corresponding output of reader 8. Block 6 works as follows. Prior to the arrival of the first time-based magnetic tag, block 6 “allows the launch of the SU by 8 depth pulses. If the label with SU 8 arrives first, then block 6 delays further triggering of the SU until the magnetic tag arrives from amplifier 4, after which the SU continues to start with depth pulses until the next mark arrives. In case the first tag comes from amplifier 4, then unit 6 performs a fast run of the recording medium to the SU 8 until the tag is read, after which the depth pulses start. Since the discrepancy between the marks is small, the loss of information that occurs during a fast run of the recording medium is also small; practically the discrepancy of marks can be no more than one or two quantization steps in depth. If there is an inverse relationship between HI and H2, (i.e.), then the corresponding linkage is made not in the second, but in the first measurement cycle. In the data processing mode after measurements are taken, information is entered into the data processing unit from two previously registered recording media. Readers 8 and 9 are used for input. Unit 5 is activated through a resilient or other transmission by an autonomous motor, pulling the photo paper (film) in the recorder 10. In this mode, block 6 can control the launching of double readers. In the nerve version, one of the reading devices is the master and the second is the slave. In this case, operation of unit 6 is similar to that described, i.e., in the case of the arrival of the first label from the master control system, unit 6 outputs a signal for a fast carrier run by the slave SU before reading the tag, and in the case of the arrival of the first tag from the slave control unit run before the arrival of the label with the leading SS. In the second variant, both SUs are equal and block 6, on the first clickable tag, regardless of which SU it came in, issues a signal for a fast carrier run to that SU, from which the tag has not yet arrived. The described device may contain more SU. The essence of the work does not change. The technical and economic efficiency of the proposed device is determined by an increase in the accuracy of data processing and the associated increase in reliability.

determining the productivity of the studied formations, and the accuracy of determining their position. The application of the proposed device allows to reduce the number of skipped productive zones, incorrect (in depth) lumbago casing (when drilling for oil and gas), and accordingly, reduce the overhead during exploration and development of mineral deposits.

Claims (1)

Invention Formula A device for online joint processing of a geophysical wellbore complex, containing an analog-digital converter, a digital recorder, a depth imaging unit, a reader, a data processing unit, and an analog recorder, characterized in that, to enhance processing accuracy, a cable amplifier magnetic tags, a multichannel device for matching the depth of the data of one measurement cycle, the input of which is connected to analog-to-digital converter, and outputs to a digital recorder and a data processing unit, a control unit for launching readers, whose inputs are connected to a pulse shaping unit the depths, the amplifier of the cable magnetic tags and the outputs of the signals of the magnetic mark of the reading devices, and the outputs to the inputs of the reading devices.