FR2649794A1 - Apparatus for automatic measurement of the reflectance of vitrinite - Google Patents

Abstract

An apparatus for automatic measurement of the reflectance of vitrinite comprises an image input part comprising an object-holder plate 1 intended to receive an object sample 2 to be measured, an objective (lens) 3 for providing an enlarged (magnified) image of an object sample, an epiprism device 5 supplemented by a light source device 4, and a television camera 9 taking an image of the object sample 2 to be measured, an image processing part comprising an analog/digital converter 10, an image memory 11 and an image processor 12, both connected to the analog/digital converter 10, and a control part comprising a data medium 21 containing a polished-particle image extraction program, a fine-texture part removal program, a luminance measurement program, a sequence control program for the execution of the programs, and a basic program, and furthermore having a memory (storage) region for the measurement results, a control processor 16 and a data medium input/output device 22 connected to the data medium 21 and to the control processor 16, the television camera 9 contained in the image input part being connected to the analog/digital converter 10 contained in the image processing part, and the control processor 16 contained in the controlled part being connected to the image processor 12 contained in the image processing part.

Description

Apparatus for automatic measurement of reflectance
vitrinite
The present invention relates to an apparatus for the automatic measurement of the reflectance of vitrinite to determine the degree of aging of organic matter in sedimentary rocks and also the qualities of coal in the formation of petroleum and natural gas. In particular, the invention allows an apparatus to automatically measure the reflectance of vitrinite on kerogen samples and carbon samples.

 In the case of measuring the reflectance of vitrinite on kerogen samples according to a method of the prior art illustrated in FIG. 5, a sample of pretreated object to be measured 2 is placed on the object plate 1 of a microscope photometric apparatus having an epi-prism device 5 supplemented by a light source device, a luminance measuring device 38 connected to a light receiving part 37, and a binocular 36 connected to a objective tube 6, and is observed with the naked eye by means of the photometric apparatus with microscope to make a reading of the sample on the basis of the petrographic knowledge of the operator relating to coal. Only the particles of vitrinite are selected among their mixture with various types of other organic matter, and then a luminance measurement is made for each of the window particles. The resulting luminance value is plotted in a calibration curve equation previously established by calibration to convert the luminance into corresponding reflectance. In addition, an apparatus for the automatic measurement of the reflectance of vitrinite on carbon samples is commercially available, but such a type of apparatus usable with kerogen samples is not available.

However, the measurement methods of the prior art have several disadvantages, which are as follows
1t) The evaluation and the discrimination of the particles of vitrinite being carried out by visual observation with the naked eye, only the people who know professionally the structures of coal and various kinds of fossils can effectively make measurements of reflectance
2 ") the large areas of the samples must be observed with high magnifications, and the field of vision in these devices is very dark. Consequently, their use is accompanied by great physical fatigue
3) the operation itself being monotonous, the operator suffers from a great mental weariness
4) only two or three samples are measured per day due to the disadvantages 2 ") and 3") listed above
5) the evaluation of the particles to be measured or not is subjective and can therefore vary from one operator to another, and the measurement results thus obtained are not always constant and regular
6) commercially available automatic measuring devices are used mainly for coal samples, the use of these devices not being permitted for kerogen samples, the quality of which is completely different from the quality of the coal samples .

 The subject of the invention is an apparatus which does not require that the users check the particles of vitrinite in the sample of object to be measured 2, nor that they have professional knowledge of the structures of coal and of the various kinds of fossils for perform automatic measurements.

 Another subject of the invention is an apparatus which allows users to keep their criteria for evaluating samples constant and eliminates errors due to the operator.

 The invention further relates to an apparatus in which the operator does not need to observe the dark field of vision under the microscope by repeating tedious and complicated operations for a long time, and which makes it possible to reduce his physical fatigue and mental at work.

 Another object of the invention is an apparatus in which a larger number of samples can be processed per unit of time compared to the apparatuses of the prior art, that is to say in which the measurement efficiency is improved .

 The invention finally aims at an apparatus which allows the automatic measurement of the reflectance of vitrinite on kerogen samples as well as on carbon samples.

 According to the invention, an apparatus for the automatic measurement of the reflectance of vitrinite comprises an image input part comprising an object-holder plate to have a sample of object to be measured as soon as possible, an objective for obtaining an enlarged image of a object samples, an epi-prism device supplemented by a light source device, and a television camera taking a view of the sample of object to be measured, an image processing part comprising an analog / digital converter , an image memory and an image processor both connected to the analog / digital converter, and a control part comprising an information medium in which is stored a program for extracting the image of polished particles, a program for removing fine textured parts, a luminance measurement program, a sequence control program for executing programs, and a basic program, and further having a storage area for measurement results, a control processor and an input / output device for the information medium connected to the information medium and to the control processor, the television camera included in the image input part being connected to the analog / digital converter included in the image processing part, and the control processor included in the control part being connected to the image processor included in the image processing part.

The foregoing objects and characteristics of the invention, as well as others, will appear more clearly on reading the description of preferred embodiments given below in relation to the appended drawings, in which:
- Figure 1 is a perspective view showing the apparatus for automatically measuring the reflectance of vitrinite according to a preferred embodiment of the invention
- Figure 2 is a block diagram of the apparatus for automatically measuring the reflectance according to the preferred embodiment of the invention, this Figure 2 comprising Figure 2A and Figure 2B which are arranged respectively to the left and to the right to form a unique scheme
- Figure 3 is a block diagram of the apparatus for automatically measuring the reflectance of vitrinite according to another preferred embodiment of the invention, this Figure 3 comprising Figure 3A and Figure 3B which are arranged respectively to the left and right to form a single pattern
FIG. 4 is a block diagram of the apparatus for automatically measuring the reflectance of the vitrinite according to yet another preferred embodiment of the invention, this FIG. 4 comprising FIG. 4A and FIG. 4B which are arranged respectively on the left and right to form a single pattern; and
- Figure 5 is a perspective view showing a photometric apparatus with a microscope for measuring the reflectance of vitrinite.

 Now considering the drawings, in which the numerical references of the different views identify identical parts, it can be seen that FIGS. 1 and 2 represent an embodiment of the invention, with an object-plate 1 for receiving a sample of object to be measured 2, a lens 3 to obtain an enlarged image of the sample 2, a light source device 4, an epi-prism device 5, a lens holder tube 6 and a camera support 8, which are fixed to the stand 7. A television camera of the shooting tube type 9 is aligned with the optical path of the lens holder tube 6 and fixed to the camera support. 8. An image input part 31 includes the epi-prism device 5 supplemented by the object-holding plate 1, the objective 3 and the light source device 4, and the television camera 9 aligned on the optical path of the objective-carrying tube 6.

 An analog / digital converter 10 converting the image obtained by the television camera 9 into a digital signal is connected to an image processing processor 12 which is connected so as to send to or receive image memories 11 image information and is constructed in such a way that the image information transmitted from the analog / digital converter 10 can be stored in the image memory 11. A digital image input device comprises the television camera 9 and the analog / digital converter 10.

 A television receiver 14 is connected to the image processing processor 12 via a television interface 13. A communication interface B 15 is connected to the analog / digital converter 10 and to the image processing processor 12 An image processing part 32 includes the image processing processor 12, the analog / digital converter 10, the image memory 11, the television interface 13, the television receiver 14 and the communication interface. bidirectional B 15. The output part of the television camera 9 included in the image input part 31 is connected to the input part of the analog / digital converter 10 included in the image processing part 32.

 A control computer is produced by connecting both a mouse 17 giving the order to execute a treatment and a display unit 18 to a control processor 16. The control processor 16 included in the control computer is connected to the bidirectional communication interface B 15 included in the image processing part 32 by means of both a bidirectional communication interface A-19 and a bidirectional communication cable 20 and is provided for controlling the operation of the image processing processor 12 by the program of the control processor 16. In addition, an information carrier input / output device 22 is constituted by a flexible disk input / output device and is connected to the processor 16.An information carrier 21A is constituted by a flexible disk A for the control program, and another information carrier 21B is constituted by a flexible disk B for the measurement results, and these information carriers 21A and 21B are inserted in the input / output device a. information carrier 22. A control part 33 includes the control processor 16, the mouse 17, the display unit 18, the two-way communication interface A 19, the input / output device with information carrier 22 and the information carriers 21A and 21B inserted into the information carrier input / output device 22.

 Furthermore, the control program comprises an automatic sampling curve establishment program 23, an image input program 24, an image extraction program for polished particles 25, a program for removing fine texture parts 26, a particle shape arrangement program 27, a luminance measurement program 28, a sequence control program 29 for executing the programs, and a basic program 30.

 The automatic calibration curve establishment program 23 controls the automatic establishment of the calibration curve used to convert the luminance values contained in the image memory 11 into corresponding reflectances of the vitrinite. The image input program 24 controls the associated operation of the analog / digital converter 10 for image input with the image memory 11. The image extraction program of polished particles 25 controls the processing of 'remove the background and the image of unpolished particles from an input image, and extract only a solid image of a particle appearing on a polished surface.

 The program for removing the fine-textured portions 26 commands the treatment to remove the fine-textured portions comprising different categories of vitrinite in the histology of the coal forming an image of the particle appearing on the polished surface, and n ' extract only a vitrinite particle image. In addition, the particle shape arrangement program 27 instructs the processing to shape the image of the extracted vitrinite particle so that effective measurement is performed.

 The luminance measurement program 28 commands the processing to measure the luminance of the particles of vitrinite extracted, for each of these particles, to convert each luminance to corresponding reflectance and to record the results measured on the information carrier 21B as data of reflectance. Furthermore, the sequence control program 29 established for the execution of the programs controls the sequence for executing each control program, and also controls the mutual relationship between the order given by the operator using the mouse. 17 and each control program.

 The basic program 30 translates each of the programs mentioned above written in a programming language.

computers in a form understandable by the control processor 16 to transfer it to this control processor 16, and controls the mutual relationship between various devices connected to the control processor 16 and this control processor 16. In addition, the basic program 30 controls the bidirectional communication between the control processor 16 and the image processing processor 12 by means of the bidirectional communication interface A 19, the bidirectional communication cable 20 and the bidirectional communication interface B 15 concerning the information from the program controlling the image processing processor 12 and included in each program and also relating to the information resulting from the processing executed by the image processing processor 12.

 The operation of the automatic vitrinite reflectance measuring apparatus of this embodiment is described below.

 First, the light source device 4, the television camera 9, the analog / digital converter 10, the image memory 11, the image processing processor 12, the television receiver 14, the communication interface bidirectional communication B 15, the control processor 16, the mouse 17, the display device 18, the bidirectional communication interface A 19 and the information carrier input / output device 22 are all put under voltage to start the basic program 30 and the sequence control program 29 for the execution of the programs stored in the information medium 21A via the information medium input / output device 22, and for correctly set each of the devices. The timing of the orders given by the operator using the mouse 17 to the control processor 16 is judged by observing the messages displayed on the display device 18 under the control of the program. sequence control me 29 for program execution.

 Secondly, a standard commercial sample for reflectance measurements is placed on the stage 1, and an order originating from the mouse 17 is entered into the control processor 16 to launch the program for automatically establishing the calibration curve 23. In this way, the image input program 24 is automatically and temporarily called up, and the image input operation begins. the enlarged image of the standard sample appearing on the television receiver 14 is developed by manual adjustment, and the order from the mouse 17 is entered to store the image of the standard sample in the memory of image 11. Next, the automatic calibration curve setting program is launched, and the luminance data of the standard samples are entered into the automatic calibration curve setting program 23.

 When, in an analogous manner, more than three standard samples are measured and an order from mouse 17 is given, a calibration curve equation for converting the luminance appearing on the image into corresponding reflectance is formed automatically and then stored in the information carrier 21B to store the measurement results to complete the execution of the automatic calibration curve setting program 23.

Then, the standard samples used to measure their reflectance are removed from the stage 1.

 Then, the sample of object to be measured 2, pretreated by an appropriate method, is placed on the object plate 1 and an order originating from the mouse 17 is entered into the control processor 16 to launch the sequence control program 29 for program execution.

The calibration curve equation stored in the information carrier 21B for the measurement results is read under the control of the sequence control program 29 for the execution of the programs, and the image input program 24 is then launched.

 In addition, the enlarged image of the sample of object to be measured 2 formed on the screen of the television receiver 14 is focused manually, and an order from the mouse 17 is entered to memorize the image of the sample of the object to be measured 2 in the image memory 11.

 Then, the polished particle image extraction program 25 and the fine texture part removal program 26 are executed under the automatic control of the sequence control program 29 for executing the programs, and only the part corresponding to the vitrinite in the image contained in the image memory 11 is extracted automatically. Then, the particle shape arrangement program 27 is executed under the automatic control of the sequence control program 29 for the execution of the programs, and the image extracted from the vitrinite is shaped by removing the images of particles not suitable having smaller areas, and also particulate peripheral parts.

 Then, the luminance measurement program 28 is executed under the sequence control program command 29 for the execution of the programs, and the image luminance of each of the vitrinite particles arranged to be shaped in the memory 11 is automatically measured. The measured luminance values are introduced into the equation of the calibration curve already read, and then converted into corresponding reflectance data which are automatically recorded in the information medium 21B provided for the measurement results.

 When the processing of a screen is finished, another part of the sample of object to be measured 2 comes into the field of vision of the objective 3 by displacement of the object-holding plate 1, and the hand is ironed again. image input program 24 by the introduction of an order from the mouse into the control processor 16. While the sample of object to be measured 2 is maintained on the stage 1, the operations are repeated in the same sequence and at the correct times.

 The number of vitrinite reflectance data necessary for a single sample of the object to be measured is entered into the sequence control program 29 for the execution of the programs. When the measurement sequence is repeated on a single sample of the object to be measured until the sequence provides the necessary number of vitrinite reflectance data, the series of repetitions of the sequence is automatically terminated, and the operation automatic measurement of the reflectance of the vitrinite for a single sample of object to be measured under the control of the sequence control program 29 for the execution of the programs is completed.

 When the measurement results are stored in the information medium 21B provided for them, they are read in another program for displaying character strings, a character editor program, a table calculation program and a plot program of graph for the shapes corresponding to the needs of the operator by the control computer included in the apparatus of the invention.

 During the implementation of the invention, as shown in FIG. 3, the device for controlling the object plate 35 is connected to this object plate 1, and the program for controlling the door plate object 34 is added to the information stored in the information carrier 21A. The movement of the object-holder plate 1 can be switched to the automatic control mode after the processing of a screen of the sample of object to be measured 2 is finished. In addition, the message controlled by the sequence control program 29 for the execution of the programs can be displayed on the screen of the television receiver 14 by using the circuit shown in FIG. 4, without using the device d 'display 18.

 A CCD camera can be used in place of the TV camera mentioned above. With regard to the information carriers 21A and 21B mentioned above, it is possible to use an optical disk or a magnetic tape instead of the flexible disk. In addition, instead of the mouse 17 for entering commands into the control processor 16, various keyboards can be used.

Various computers, such as personal computers, minicomputers or mainframe computers, can be used as the control computer. By omitting the bidirectional communication interface A 19, the bidirectional communication cable 20 and the bidirectional communication interface B15 of FIG. 2, it is possible to use a single large computer. The image processing part 32
and the control part 33 can be included in the same computer by making the processor perform the functions of the control processor 16 and those of the image processing processor 12 and in addition making the memory perform both the memory functions of image 11 than those in the storage area.

Claims (4)

 1 - Apparatus for the automatic measurement of the reflectance of vitrinite, characterized in that it comprises  - a part between image- (31) comprising an object plate (1) intended to receive a sample of object to be measured (2), an objective (3) to provide an enlarged image of a sample of object, an epi-prism device (5) supplemented by a light source device (4), and a television camera (9) taking a view of the sample of object to be measured (2)  - an image processing part (32) comprising an analog / digital converter (10), an image memory (11) and an image processing processor (12) both connected to the analog / digital converter (10)  - a control part (33) comprising an information medium (21) composed of an information medium (21A) containing an image extraction program for polished particles (25), a part removal program fine texture (36), a luminance measurement program (28), a sequence control program (29) for executing the programs and a basic program (30), and an information carrier (21B) having a storage area for measurement results, a control processor (16), and an information carrier input / output device (22) connected to the information carrier (21) and the control processor ( 16)  - the television camera (9) included in the image input part (31) being connected to the analog / digital converter (10) included in the image processing part (32); and  - the control processor (16) included in the control part (33) being connected to the image processing processor (12) included in the image processing part (32).  2 - Apparatus for the automatic reflectance measurement of the vitrinite according to claim 1, characterized in that a device for controlling the object plate (35) for automatically controlling the movement of the object plate (1) after the end of the measurement processing of a screen for the sample of object to be measured (2), is connected to the object-plate (1), and in that the information carrier '(21A) contains a program control plate control (34).  3 - Apparatus for the automatic measurement of the reflectance of vitrinite according to claim 1, characterized in that a television receiver (14) for displaying the messages controlled by the sequence control program (29) for the execution of the programs is provided in the image processing part (32).  4 - Apparatus for the automatic measurement of the reflectance of vitrinite according to claim 1, characterized in that the information carriers (21A) and (21B) are flexible disks.