CN112256609B - Device for realizing source driving equipment compatibility - Google Patents

Abstract

The invention provides a device for realizing source drive equipment compatibility, which comprises: the COM1 module is used for receiving and transmitting SGDS READY protocol character strings in ASIIC code format, ignition instruction character strings in ASIIC code format of SGDS exploders and SGDS REF protocol character strings in ASIIC code format; the COM2 module is used for receiving and transmitting a 16-system format READY signal character string, a 16-system format ignition protocol character string and a 16-system format REF signal character string; the protocol conversion module is used for converting the READY signal character string into an SGDS READY protocol character string; converting the ASIIC code format ignition instruction character string of the SGDS exploder into a 16-system format ignition protocol character string; the REF signal string is converted to an SGDS REF protocol string. The invention can realize the compatibility of the source driving equipment and the explosive machine.

Description

Device for realizing source driving equipment compatibility

Technical Field

The invention relates to the technical field of equipment compatibility, in particular to a device for realizing source drive equipment compatibility.

Background

In the process of oil exploration, two kinds of exploders, namely Shot Pr and BOOM BOX, are mainly used in the well-Shot construction. The BOOM BOX explosive device has the advantages of light relative weight, portability, simple operation, no external button, direct setting of parameters by instrument personnel, and no random setting and modification of explosive workers. The BOOM BOX exploder has better wide temperature display, does not have the advantages of being incapable of working normally in a cooler or hotter environment and the like, and is popular with users.

With the development of science and technology, the requirements of seismic exploration on new technologies are more and more urgent. The conventional well gun blasting method is limited by poor communication, dialect use, personal hearing and the like, so that the phenomena of gun mistake, gun leakage and the like are easy to occur, and the blasting efficiency is low. Due to the advantages of accurate shot point positioning, high construction efficiency and the like, the well shot source drive is widely applied to production. The well gun source driving needs to be used for an explosive machine and a source driving device at the same time, but the BOOM BOX explosive machine does not have a 428XL instrument source driving protocol and a built-in GPS function, needs to receive GPS signals from the outside and sends the signals to the BOOM BOX explosive machine, and therefore the source driving device (such as a 428XL instrument) cannot realize source driving construction.

Disclosure of Invention

The embodiment of the invention provides a device for realizing compatibility of source driving equipment, which is used for realizing compatibility of the source driving equipment and an explosive machine, and comprises the following components:

a first socket, a second socket and a protocol converter, wherein, the protocol converter comprises a serial communication port COM1 module, a serial communication port COM2 module and a protocol conversion module,

the COM1 module is connected with the LCI of the source driving equipment through a first socket and is used for sending SGDS READY protocol character strings in an ASIIC code format to the LCI; receiving an ignition instruction character string in an ASIIC code format of the SGDS explosive machine sent by the LCI and sending the ignition instruction character string to a protocol conversion module; sending the SGDS REF protocol character string in the ASIIC code format to the LCI;

the COM2 module is connected with an encoder of the explosive machine through a second socket and is used for receiving a 16-system format READY signal character string sent by the encoder and sending the READY signal character string to the protocol conversion module; sending a 16-ary format firing protocol string to the encoder; receiving a 16-system format REF signal character string sent by the encoder and sending the character string to a protocol conversion module;

the protocol conversion module is used for converting the 16-system format READY signal character string into an SGDS READY protocol character string in an ASIIC code format and sending the SGDS READY protocol character string to the COM1 module; converting the ASIIC code format ignition instruction character string of the SGDS exploder into a 16-system format ignition protocol character string and sending the 16-system format ignition protocol character string to a COM2 module; and converting the REF signal character string in the 16-system format into an SGDS REF protocol character string in an ASIIC code format and sending the character string to a COM1 module.

In the embodiment of the invention, the COM1 module is connected to the LCI of the source driver through the first socket, and is configured to send a SGDS READY protocol string in an ASIIC code format to the LCI; receiving an ignition instruction character string in an ASIIC code format of the SGDS explosive machine sent by the LCI and sending the ignition instruction character string to a protocol conversion module; sending the SGDS REF protocol character string in the ASIIC code format to the LCI; the COM2 module is connected with an encoder of the explosive machine through a second socket and is used for receiving a 16-system format READY signal character string sent by the encoder and sending the READY signal character string to the protocol conversion module; sending a 16-ary format firing protocol string to the encoder; receiving a 16-system format REF signal character string sent by the encoder and sending the character string to a protocol conversion module; the protocol conversion module is used for converting the 16-system format READY signal character string into an SGDS READY protocol character string in an ASIIC code format and sending the SGDS READY protocol character string to the COM1 module; converting the ASIIC code format ignition instruction character string of the SGDS exploder into a 16-system format ignition protocol character string and sending the 16-system format ignition protocol character string to a COM2 module; and converting the REF signal character string in the 16-system format into an SGDS REF protocol character string in an ASIIC code format and sending the character string to a COM1 module. Through the conversion of the first socket, the second socket, the serial communication port COM1 module, the serial communication port COM2 module and the protocol conversion module to data, the problems that an explosive machine does not have a source driving protocol and cannot realize source driving construction on source driving equipment can be fundamentally solved, additional GPS equipment is not needed, and the source driving construction cost of the explosive machine is greatly reduced.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts. In the drawings:

fig. 1 is a schematic diagram of an apparatus for implementing source driver compatibility according to an embodiment of the present invention;

fig. 2 is a detailed structural diagram of an apparatus for implementing source driver compatibility according to an embodiment of the present invention;

FIG. 3 is another schematic diagram of an apparatus for implementing source driver compatibility according to an embodiment of the present invention;

fig. 4 is a detailed flowchart of an apparatus for implementing source driver device compatibility according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the embodiments of the present invention are further described in detail below with reference to the accompanying drawings. The exemplary embodiments and descriptions of the present invention are provided to explain the present invention, but not to limit the present invention.

In the description of the present specification, the terms "comprising," "including," "having," "containing," and the like are used in an open-ended fashion, i.e., to mean including, but not limited to. Reference to the description of the terms "one embodiment," "a particular embodiment," "some embodiments," "for example," etc., means that a particular feature, structure, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the application. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. The sequence of steps involved in the embodiments is for illustrative purposes to illustrate the implementation of the present application, and the sequence of steps is not limited and can be adjusted as needed.

Fig. 1 is a schematic diagram of an apparatus for implementing source driver compatibility according to an embodiment of the present invention, as shown in fig. 1, the apparatus includes:

a first socket 101, a second socket 102 and a protocol converter 103, wherein the protocol converter 103 comprises a serial communication port COM1 module 1031, a serial communication port COM2 module 1032 and a protocol conversion module 1033,

the COM1 module 1031 is connected to the LCI of the source driver through the first socket 101, and is configured to send a SGDS READY protocol character string in an ASIIC code format to the LCI; receiving the ignition instruction character string in the ASIIC code format of the SGDS explosive sent by the LCI and sending the ignition instruction character string to the protocol conversion module 1033; sending the SGDS REF protocol character string in the ASIIC code format to the LCI;

the COM2 module 1032 is connected to an encoder of the explosive through the second socket 102, and is configured to receive a 16-ary format READY signal character string sent by the encoder and send the received signal character string to the protocol conversion module; sending a 16-ary format firing protocol string to the encoder; receiving the REF signal character string in 16-system format sent by the encoder and sending the REF signal character string to the protocol conversion module 1033;

the protocol conversion module 1033 is configured to convert the 16-system format READY signal character string into an SGDS READY protocol character string in an ASIIC code format and send the SGDS READY protocol character string to the COM1 module 1031; the ASIIC code format ignition instruction character string of the SGDS exploder is converted into a 16-system format ignition protocol character string and sent to a COM2 module 1032; the REF signal string in the 16-ary format is converted into an SGDS REF protocol string in the ASIIC code format and sent to the COM1 module 1031.

Through the conversion of the first socket, the second socket, the serial communication port COM1 module, the serial communication port COM2 module and the protocol conversion module to data, the problems that an explosive machine does not have a source driving protocol and cannot realize source driving construction on source driving equipment can be fundamentally solved, additional GPS equipment is not needed, and the explosive machine source driving construction cost is greatly reduced.

In one embodiment, the source drive device is a 428XL instrument.

In one embodiment, the explosive machine is a BOOM BOX explosive machine.

Of course, it is understood that the source driving device and the explosive device may be other types of devices as long as the above communication and conversion can be performed with the protocol converter, and all the related modifications are within the scope of the present invention.

In one embodiment, the first socket is a 6-core socket and the second socket is a 19-core socket.

Fig. 2 is a detailed structural diagram of an apparatus for implementing source driver compatibility according to an embodiment of the present invention, where the first socket is a 6-core socket, the second socket is a 19-core socket, the source driver is a 428XL instrument, and the exploder is a BOOM BOX exploder, as shown in fig. 2, the 1-pin TXD of the first socket is connected to the 2-pin RXD of the COM1 module, the 2-pin RXD of the first socket is connected to the 3-pin TXD of the COM1 module, the 3-pin of the first socket is connected to the K-pin of the second socket, the 4-pin of the first socket is connected to the L-pin of the second socket, the 5-pin of the first socket is connected to the M-pin of the second socket, and the 6-pin of the first socket is connected to the N-pin of the second socket. Wherein the 1 pin TXD of the first jack is used to transmit data and the 2 pin RXD of the COM1 module is used to receive data; the 2-pin RXD of the first jack is used to receive data and the 3-pin TXD of the COM1 module is used to transmit data.

The C pin RXD of the second socket is connected with the 3 pin TXD of the COM2 module, the D pin TXD of the second socket is connected with the 2 pin RXD of the COM2 module, the L pin and the R pin of the second socket are respectively connected with the 5 pin of the COM1 module, the L pin and the R pin of the second socket are respectively connected with the 5 pin of the COM2 module, and the COM1 module and the COM2 module are grounded. The C pin RXD of the second socket is used for receiving data, the 3 pin TXD of the COM2 module is used for transmitting data, the D pin TXD of the second socket is used for transmitting data, and the 2 pin RXD of the COM2 module is used for receiving data.

In an embodiment, the protocol conversion module is specifically configured to:

extracting an ID number and coordinates of the exploder from the 16-system format READY signal character string, and converting the ID number and the coordinates into an SGDS READY protocol character string in an ASIIC code format;

extracting an explosive ID number from an ignition instruction character string in an ASIIC code format of an SGDS explosive, and converting the explosive ID number into an ignition protocol character string in a 16-system format;

the explosive ID number, coordinates and explosive state information are extracted from the 16-system format REF signal string and converted into an ASIIC code format SGDS REF protocol string.

Through the conversion, the construction mode of the SGDS protocol format explosive machine can be simulated to realize the source driving function of the explosive machine.

In one embodiment, the K pin of the second socket is used for accessing a high-level analog signal; the L pin of the second socket is used for accessing a low-level analog signal;

the N pins of the second socket are used for accessing a high-level starting signal, and the R pins of the second socket are used for accessing a low-level starting signal.

In one embodiment, the COM2 module sends a low start signal when sending a 16-ary format firing protocol string to the encoder;

and the encoder sends a detonation instruction to the explosive machine when receiving the low-level starting signal, and simultaneously sends a high-level analog signal to the LCI.

In an embodiment, the protocol converter further includes a power module 1034, and as shown in fig. 3, it is another schematic diagram of an apparatus for implementing source driver compatibility in an embodiment of the present invention. The power supply module supports 12V power supply to complete power supply of the protocol converter.

Based on the above embodiments, the present invention provides the following embodiment to describe a detailed flow of an apparatus for implementing source driver compatibility, where fig. 4 is a detailed flow chart of an apparatus for implementing source driver compatibility in an embodiment of the present invention, and as shown in fig. 4, the apparatus includes:

step 401, after the explosive is charged, an encoder of the explosive sends a 16-system format READY signal character string to a COM2 module;

step 402, the COM2 module sends the 16-system format READY signal character string to the protocol conversion module;

step 403, the protocol conversion module converts the 16-system format READY signal character string into SGDS READY protocol character string in ASIIC code format and sends the SGDS READY protocol character string to the COM1 module;

step 404, the COM1 module sends the SGDS READY protocol character string in ASIIC code format to the LCI of the source driver;

step 405, when blasting is triggered, the COM1 module receives an ignition instruction character string in an ASIIC code format of an SGDS (small start system) blasting machine sent by the LCI and sends the ignition instruction character string to the protocol conversion module;

step 406, the protocol conversion module converts the ignition instruction character string in the ASIIC code format of the SGDS exploder into an ignition protocol character string in a 16-system format and sends the ignition protocol character string to the COM2 module;

step 407, the COM2 module sends the 16-ary format ignition protocol character string to the encoder, and sends a low-level start signal at the same time, and the encoder sends a detonation instruction to the explosive machine when receiving the low-level start signal, and sends a high-level analog signal to the LCI at the same time;

step 408, after the detonation of the shot point, the COM2 module receives the REF signal character string in the 16-system format sent by the encoder and sends the REF signal character string to the protocol conversion module;

step 409, the protocol conversion module converts the REF signal character string in the 16-system format into an SGDS REF protocol character string in an ASIIC code format and sends the SGDS REF protocol character string to the COM1 module;

in step 410, the COM1 module sends the SGDS REF protocol string in ASIIC code format to the LCI.

Of course, it is understood that other variations of the above detailed flow can be made, and all such variations are intended to fall within the scope of the present invention.

To sum up, in the embodiment of the present invention, the COM1 module is connected to the LCI of the source driver through the first socket, and is configured to send a SGDS READY protocol string in an ASIIC code format to the LCI; receiving an ignition instruction character string in an ASIIC code format of the SGDS explosive machine sent by the LCI and sending the ignition instruction character string to a protocol conversion module; sending the SGDS REF protocol character string in the ASIIC code format to the LCI; the COM2 module is connected with an encoder of the explosive machine through a second socket and is used for receiving a 16-system format READY signal character string sent by the encoder and sending the READY signal character string to the protocol conversion module; sending a 16-ary format firing protocol string to the encoder; receiving a 16-system format REF signal character string sent by the encoder and sending the character string to a protocol conversion module; the protocol conversion module is used for converting the 16-system format READY signal character string into an SGDS READY protocol character string in an ASIIC code format and sending the SGDS READY protocol character string to the COM1 module; converting the ASIIC code format ignition instruction character string of the SGDS exploder into a 16-system format ignition protocol character string and sending the 16-system format ignition protocol character string to a COM2 module; and converting the REF signal character string in the 16-system format into an SGDS REF protocol character string in an ASIIC code format and sending the character string to a COM1 module. Through the conversion of the first socket, the second socket, the serial communication port COM1 module, the serial communication port COM2 module and the protocol conversion module to data, the problems that an explosive machine does not have a source driving protocol and cannot realize source driving construction on source driving equipment can be fundamentally solved, additional GPS equipment is not needed, and the source driving construction cost of the explosive machine is greatly reduced.

In addition, the protocol converter in the embodiment of the invention has small volume, is convenient to install, does not need to be additionally arranged and has good field adaptability. The device for realizing the compatibility of the source driving equipment can also shorten the time that an operator of an explosive machine repeatedly verifies the shot point and reports the time to an instrument operator in the conventional well shot blasting method, avoid the phenomena of easy occurrence of gun error, gun leakage and the like, and improve the blasting efficiency.

The above-mentioned embodiments are intended to illustrate the objects, technical solutions and advantages of the present invention in further detail, and it should be understood that the above-mentioned embodiments are only exemplary embodiments of the present invention, and are not intended to limit the scope of the present invention, and any modifications, equivalent substitutions, improvements and the like made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (10)

1. An apparatus for implementing source driver compatibility, comprising: a first socket, a second socket and a protocol converter, wherein, the protocol converter comprises a serial communication port COM1 module, a serial communication port COM2 module and a protocol conversion module,

the COM1 module is connected with the LCI of the source driving equipment through a first socket and is used for sending SGDS READY protocol character strings in an ASIIC code format to the LCI; receiving an ignition instruction character string in an ASIIC code format of the SGDS explosive machine sent by the LCI and sending the ignition instruction character string to a protocol conversion module; sending the SGDS REF protocol character string in the ASIIC code format to the LCI;

the COM2 module is connected with an encoder of the explosive machine through a second socket and is used for receiving a 16-system format READY signal character string sent by the encoder and sending the READY signal character string to the protocol conversion module; sending a 16-ary format firing protocol string to the encoder; receiving a 16-system format REF signal character string sent by the encoder and sending the character string to a protocol conversion module;

the protocol conversion module is used for converting the 16-system format READY signal character string into an SGDS READY protocol character string in an ASIIC code format and sending the SGDS READY protocol character string to the COM1 module; converting the ASIIC code format ignition instruction character string of the SGDS exploder into a 16-system format ignition protocol character string and sending the 16-system format ignition protocol character string to a COM2 module; and converting the REF signal character string in the 16-system format into an SGDS REF protocol character string in an ASIIC code format and sending the character string to a COM1 module.

2. The apparatus for implementing source driver device compatibility of claim 1, wherein the protocol conversion module is specifically configured to:

extracting an ID number and coordinates of the exploder from the 16-system format READY signal character string, and converting the ID number and the coordinates into an SGDS READY protocol character string in an ASIIC code format;

extracting an explosive ID number from an ignition instruction character string in an ASIIC code format of an SGDS explosive, and converting the explosive ID number into an ignition protocol character string in a 16-system format;

the detonator ID number, coordinates and detonator state information are extracted from the 16-ary format REF signal string and converted to an ASIIC code format SGDS REF protocol string.

3. The apparatus of claim 1, wherein the first socket is a 6-core socket and the second socket is a 19-core socket.

4. The apparatus of claim 1, wherein the 1 pin TXD of the first socket is connected to the 2 pin RXD of the COM1 module, the 2 pin RXD of the first socket is connected to the 3 pin TXD of the COM1 module, the 3 pin of the first socket is connected to the K pin of the second socket, the 4 pin of the first socket is connected to the L pin of the second socket, the 5 pin of the first socket is connected to the M pin of the second socket, and the 6 pin of the first socket is connected to the N pin of the second socket.

5. The apparatus for achieving source drive device compatibility according to claim 1, wherein the C pin RXD of the second socket is connected with the 3 pin TXD of the COM2 module, the D pin TXD of the second socket is connected with the 2 pin RXD of the COM2 module, the L pin and the R pin of the second socket are respectively connected with the 5 pins of the COM1 module, the L pin and the R pin of the second socket are respectively connected with the 5 pins of the COM2 module, and the COM1 module and the COM2 module are connected with the same ground.

6. The apparatus for implementing source driver compatibility of claim 1, wherein the K pin of the second socket is used to access high level analog signals; the L pin of the second socket is used for accessing a low-level analog signal;

the N pins of the second socket are used for accessing a high-level starting signal, and the R pins of the second socket are used for accessing a low-level starting signal.

7. The apparatus for implementing source driver compatibility of claim 6 wherein said COM2 module simultaneously sends a low enable signal when a 16-ary format firing protocol string is sent to said encoder;

and the encoder sends a detonation instruction to the explosive machine when receiving the low-level starting signal, and simultaneously sends a high-level analog signal to the LCI.

8. The apparatus of claim 1, wherein the protocol converter further comprises a power module.

9. The apparatus of claim 1, in which the source driven device is a 428XL instrument.

10. The apparatus for achieving source driven device compatibility as recited in claim 1 wherein said detonator is a BOOM BOX detonator.

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