NL1028157C2 - Data transfer method for use between X-ray and analysis system and coupled X-ray analysis component, with memory devices fitted on X-ray analysis component - Google Patents

Abstract

The method is for data transfer between an X-ray analysis system (3) and a coupled X-ray analysis component (2). Memory devices (2A) are fitted on the X-ray analysis component and in the coupled state the memory devices can be read through the X-ray analysis system. During operation, actual operational parameters can be stored in the memory devices. Such parameters can cover the X-ray analysis component and/or the X-ray analysis system and/or the operating ambiance and/or other relevant operating data. X-ray analysis can occur with the aid of different techniques, i.e. X-ray diffraction, X-ray fluorescence, with particular application and crystalline structure of natural and industrially produced materials, with X-ray fluorescent spectrometry generally applicable for identification and determination of concentrations of elements in specimens of materials, be they in solid, liquid or powder form. The X-ray analysis component comprises an X-ray tube and the X-ray analysis system consists of an X-ray detector (4) for receipt of X-ray radiation from the X-ray tube. An optical system (5) is provided for the X-ray detector for controlled conduct of the X-ray radiation. The system also has a high voltage generator (6) for the X-ray tube.

Description

METHOD FOR DATA TRANSFER BETWEEN AN X-RAY ANALYSIS SYSTEM AND A LINKABLE X-RAY ANALYSIS COMPONENT

The invention relates to a method for data transfer between an X-ray analysis system and at least one X-ray analysis component connectable thereto, comprising the following steps: a) applying memory means to the X-ray analysis component; b) storing data relating to the X-ray analysis component 10 in the memory means; and c) reading the memory means in the coupled state of the X-ray analysis component on the X-ray analysis system by the X-ray analysis system.

The invention also relates to a device for carrying out the method.

Such an apparatus has been developed by the applicant itself for carrying out a method of the type mentioned in the preamble. The known device comprises an X-ray analysis system and an X-ray tube connectable thereto. The X-ray tube is provided with analogue memory means in the form of resistors 20 and / or diodes. At the factory, the analogue memory means is set once to a nominal value that indicates the type of house. The X-ray analysis system is provided with means for reading that nominal value in order to be able to determine the tube type of the connected tube.

It is an object of the invention to provide a more advanced method for data transfer between an X-ray analysis system and an X-ray analysis component connectable thereto.

To this end, the method according to the invention is characterized by the following steps: d) applying writable memory means to the X-ray analysis component; and e) storing operating parameters in the writable memory means with respect to the x-ray analysis component and / or the x-ray analysis system and / or the operating environment and / or other relevant operating data during operation of the x-ray analysis system.

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The operating parameters thus stored are related to current operational process data and provide a detailed insight into the operation of the X-ray analysis system and the associated X-ray analysis component, such as the aforementioned X-ray tube. By means of the method according to the invention, therefore, information is made available which offers the possibility of extensive improvement and optimization of both the X-ray analysis process and the X-ray analysis system and the coupled X-ray analysis component. In daily practice, the actual operating parameters thus provided also provide vital information for eliminating technical failures. In addition, these can also be used to assess the validity of any guarantee claims. In the situation in which an X-ray analysis component, such as a X-ray tube, is coupled in turn to a plurality of X-ray analysis systems, the method according to the invention provides the possibility of recording data relating to the exchange process and therefore to better control thereof.

According to a practical preferred embodiment, use is made of non-volatile writable memory means. This guarantees the retention of the stored data and thus guarantees a reliable implementation of the method according to the invention. Use is preferably made of flash PROM memory means, which can be written on quickly.

According to a further preferred embodiment, the operating parameters are stored encrypted in the writable memory means. The business parameters are effectively protected with this and confidential treatment thereof is assured.

According to another preferred embodiment, actual values of specific technical characteristics of the X-ray analysis component are stored in the writable memory means. By making this information available to the X-ray analysis system, this system can adjust to the actual values of the associated X-ray analysis component instead of the usual nominal values, which leads to a further optimization of the X-ray analysis process.

The device for performing the method according to the invention comprises an X-ray analysis system and at least one X-ray analysis component, which is connectable to the X-ray analysis system, wherein the X-ray analysis component is provided with writable memory means and in which the X-ray analysis system is provided with means for storing the memory means from to read and describe. In the preferred embodiment, the X-ray analysis component comprises an X-ray source, which is provided with flash PROM memory means.

The invention also relates to an X-ray source for use in a device according to the invention, which X-ray source is provided with writable memory means. Preferably, the writable memory means comprises flash PROM memory means.

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The invention will be further described with reference to the drawings, in which:

Figure 1 shows a diagram of a preferred embodiment of the device according to the invention; and Figure 2 schematically shows the steps of writing and reading the memory means in accordance with the method according to the invention.

Figure 1 shows schematically the most important components of device 1 according to the invention in their mutual relationship. Device 1 is generally intended for analyzing materials with the help of X-rays.

X-ray analysis can be performed using various techniques: XRD ("X-Ray Diffraction") and XRF ("X-Ray Fluorescence"). XRD techniques are particularly suitable for obtaining information about the chemical composition and crystal structure of natural and industrially manufactured materials. XRF-25 spectrometry is generally used to identify and determine concentrations of elements in specimens of materials, be it in solid, liquid or powder form. For the implementation of both techniques, the applicant markets various X-ray analysis devices. The present invention is suitable for use with both X-ray analysis techniques and is therefore illustrated with reference to a very general device 1, of which only the most important components are indicated.

Device 1 comprises an X-ray analysis component 2 and an X-ray analysis system 3, which can be coupled to each other. In the preferred embodiment described, X-ray analysis component 2 comprises an X-ray source, for example 1028157 4 an X-ray tube. X-ray analysis system 3 comprises an X-ray detector 4 for receiving the X-ray radiation from X-ray tube 2. An optical system 5 is located in front of the X-ray detector 4 for controlled transmission of the X-ray radiation. System 3 further comprises a high-voltage generator 6 for the X-ray tube 2. Control system 7 controls the various system components, including the detector 4, the optical system 5 and the high-voltage generator 6.

According to the invention, X-ray tube 2 is provided with writable memory means 2A and control system 7 is provided with means 7A for writing and reading the memory means 2A. It is noted that each of the mentioned system components according to the invention can be provided with writable memory means. The invention is described in the preferred embodiment on the basis of an X-ray tube 2 as an X-ray analysis component with writable memory means, but instead of the X-ray tube, for example, the detector 4, the optical system 5 and / or the high-voltage generator 6 of writable memory means (resp. 4A, 5A, 6A (not shown) are provided with features similar to those described for the writable memory means 2A.

Suitable writable memory means 2A can be characterized as "active": the stored information is non-static or changeable. Memory means 2A are furthermore non-volatile: the stored information is retained even in the event of a power failure. Based on currently available techniques, memory means 2A are digital. Other options may be available in the future. An example of a suitable memory is an EEPROM ("Electrically Erasable Programmable Read-Only Memory") or a flash PROM memory. It will be apparent to one skilled in the art that any other memory which satisfies the above characteristics and is commercially available is suitable for use with the present invention.

Means 7A for writing and reading the memory means 2A should be adjusted to the choice of memory type and are commercially available per se. For the said EEPROM memory or flash PROM memory, for example, an EEPROM programming unit or flash PROM programming unit is available.

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Figure 2 shows a block diagram of the steps relating to the writing and reading of the memory means in accordance with the method according to the invention.

Step 10: Storing data relating to the X-ray analysis component in the memory means

In this step, all technical information that may be important for operational use of the X-ray analysis component is stored in the writable memory means. In the preferred embodiment of device 1 shown, this means that all relevant technical specifications with regard to the X-ray tube 2 are stored in memory means 2A. This can already take place during manufacture of the X-ray tube 2.

The writable nature of the memory means makes it possible to store actual values of the specific technical characteristics of the X-ray analysis component instead of the nominal values that were customary up to that time. Some specific examples are, in addition to product identification number and serial number, other source-type dependent information such as: anode material type, focal dimensions and permitted generator settings.

20 Step 20: Reading out the memory means

After coupling of the X-ray analysis component to the system, the writable memory means are read out. In the preferred embodiment shown, the means 7A reads out the memory means 2A under the control of the control system 7. The x-ray analysis system 3 hereby has access to all technical information which is important for the operational use of the coupled x-ray analysis component, in this case tube 2. As a further specific advantage, this means that customer-specific information can be pre-programmed, as well as standby settings. Moreover, in this specific example, tube type-dependent software upgrades have now become superfluous.

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Step 30: Storing actual operating parameters in the writable resources

During operation of the X-ray analysis system, (current) operating parameters are stored in the writable memory means. The 5 operating parameters can relate to the X-ray analysis component, the X-ray analysis system, the operating environment and to all other relevant data.

In the preferred embodiment shown, this means that when the system 3 is in use, operating information is stored during use by the means 7A in the memory means 2A of the tube 2. In the context of the invention, "being in use" means system 3 generally means that system 3 is switched on, both in stand-by or standby mode and for X-ray analysis or any other use, for example routine check-ups or updates ("upgrades").

Many examples of relevant operating parameters are conceivable, such as: date / time of connection and / or disconnection, system identification (specifically for X-ray analysis components that can be used with multiple systems), generator settings, changes in the set values, flow rate of the cooling water and / or the demineralized water, temperature of the cooling water and / or demineralized water, date / time of last use, data regarding

Component environment, such as specimen chamber: pressure, information regarding vacuum, helium.

In general, this makes much important information available with regard to the behavior of the X-ray analysis component, in this example the X-ray tube, during its lifetime. Collecting, studying and analyzing these operating parameters provides, among other things, more insight into the settings during the lifetime of the X-ray analysis component and into the (influence of) environmental parameters. This insight paves the way for far-reaching optimization of production processes and also offers the possibility of a thorough evaluation and assessment of (the validity) of warranty claims with regard to the X-ray analysis component.

Finally, the invention is explicitly not limited to the described and shown embodiment. In particular, the use of writable memory means is not limited to X-ray tubes, but is also suitable for use with other X-ray analysis components, such as other X-ray sources 10281 57, 7 and / or other components of the X-ray analysis system, including the detector, the optical system, the high voltage generator etc.

The invention therefore extends generally to any embodiment that falls within the scope of the appended claims viewed in the light of the foregoing description and drawings.

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Claims (9)

A method for data transfer between an X-ray analysis system and at least one X-ray analysis component connectable thereto, comprising the following steps: a) applying memory means to the X-ray analysis component; b) storing data relating to the X-ray analysis component in the memory means; C) reading the memory means in the coupled state of the X-ray analysis component to the X-ray analysis system by the X-ray analysis system, the method being characterized by d) applying writable memory means to the X-ray analysis component; and e) storing operating parameters in the writable memory means with respect to the x-ray analysis component and / or the x-ray analysis system and / or the operating environment and / or other relevant operating data during operation of the x-ray analysis system. The method of claim 1, wherein step d) comprises applying non-volatile memory means to the X-ray analysis component. The method of claim 1 or 2, wherein step d) comprises applying flash PROM memory means to the X-ray analysis component. 25 The method of claim 1 or 2, wherein step d) comprises applying EEPROM memory means to the X-ray analysis component. Method according to one of the preceding claims, wherein step e) comprises encrypted storage of the operating parameters in the writable memory means. A method according to any one of the preceding claims, wherein step b) comprises storing actual values of specific technical characteristics of the X-ray analysis component in the writable memory means. 1028157 A method according to any one of the preceding claims, wherein the linkable X-ray analysis component comprises an X-ray source. 5. Device for performing the method as claimed in any of the foregoing claims, comprising an x-ray analysis system and x-ray analysis component, which can be coupled to the x-ray analysis system, wherein the x-ray analysis component is provided with writable memory means and in which the x-ray analysis system is provided with means for extracting the memory means read and describe. The device of claim 8, wherein the linkable X-ray analysis component comprises an X-ray source. X-ray source as described as part of a device according to claim 8 or 9, which X-ray source is provided with writable memory means. 1028157