RU2186373C1 - Spectrometric meter - Google Patents

Abstract

FIELD: spectrometry, low-temperature spectrometric measurements. SUBSTANCE: spectrometric meter includes heating clear electrode deposited on reverse side of glass substrate of liquid-crystal display, temperature-sensitive element measuring ambient temperature in close proximity to liquid-crystal display, comparator comparing signals from temperature-sensitive element with reference signal and generating signal to switch on heating by result of this comparison, commutation unit to turn on power of heating electrode by signal from comparator. EFFECT: autonomous operation of spectrometric meter practically under any temperature conditions without necessity of mating computer in process of measurement. 4 cl, 1 dwg

Description

 The present invention relates to spectrometric measurements of the radionuclide or elemental composition of substances and, in particular, to a spectrometric meter, which can also be used in the field.

The current level of technology
At present, spectrometers are widely used in various fields of science and technology, including at all stages of the nuclear fuel cycle: field exploration, production, processing and enrichment of mineral raw materials, manufacture of fuel elements and assemblies, technological control at enterprises and nuclear power plants, processing of irradiated fuel , storage and disposal of waste, radiation monitoring of industrial enterprises and adjacent territories, as well as for state accounting and control of nuclear materials and radioactive stances and waste.

 As a rule, any existing spectrometric meter contains an input unit designed to supply power to the detection unit and to receive and convert measurement signals from the detection unit, a data processing unit designed to at least process the measurement signals converted by the input unit in accordance with a predetermined program processing, and a display for displaying the results of data processing in the data processing unit.

 However, existing spectrometric meters are either not designed for operation in the field at negative ambient temperatures, or require various additional means for their autonomous operation, for example, a heated casing. In addition, portable spectrometric meters must be connected to a computer to ensure the processing of measurement results in real time.

SUMMARY OF THE INVENTION
Thus, it is an object of the present invention to provide a spectrometric meter free of these drawbacks. The present invention solves this problem with the achievement of a technical result in the form of autonomous operation of a spectrometric meter in virtually any temperature conditions without the need for connecting to a computer during the measurement process.

 This problem is solved due to the fact that in a spectrometric meter containing an input unit designed to supply power to the detection unit and for receiving and converting measurement signals from the detection unit, a data processing unit designed to at least process the measurement signals converted by the input unit into in accordance with a predetermined processing program, and a liquid crystal display designed to display the results of data processing in the data processing unit, - according It is clear to the present invention that a transparent heating electrode is deposited on the back side of the glass substrate of the liquid crystal display and intended to heat the liquid crystal display; a temperature sensor designed to measure the ambient temperature in the immediate vicinity of the liquid crystal display; a comparison unit for comparing a signal from a temperature sensor with a reference signal and generating a heating enable signal based on the result of this comparison; and a switching unit for supplying power to the heating electrode by a heating enable signal from the comparison unit.

 A feature of the spectrometric meter of the present invention is that it can further comprise a heating mode control unit for changing a power supply supplied through a switching unit to a heating electrode, under the control of a data processing unit receiving comparison results from a comparison unit.

 Alternatively, a feature of the spectrometric meter of the present invention is that the processing program in the data processing unit may include a subroutine for changing the power supply supplied by the switching unit to the heating electrode, according to the results of comparison with the comparison unit.

 In addition, a feature of the spectrometric meter of the present invention is that the switching unit may comprise a typical mode switch for supplying a heating power electrode, the power of which depends on the ambient temperature, and a forced mode switch for supplying a heating power electrode a predetermined power exceeding the minimum possible power supplied to the heating electrode by a typical mode switch.

 Finally, another feature of the spectrometer meter of the present invention is that it may further comprise a heating mode indicator for indicating the presence of a heating enable signal.

 In the current level of technology, objects of the same purpose have not been identified that contain a combination of the above essential features, as well as a set of features that distinguish the claimed spectrometric meter from existing analogues, which makes it possible to consider the spectrometric meter of the present invention to be new and inventive.

Brief Description of the Drawings
The present invention will now be described with reference to the accompanying drawing, which is a functional diagram of a spectrometer meter of the present invention.

DETAILED DESCRIPTION OF THE INVENTION
The spectrometric meter of the present invention is intended both for stationary operation and for use in the field in the temperature range from -40 ^o C to +50 ^o C.

 The spectrometric meter in the embodiment shown in the drawing comprises an input unit 1, a data processing unit 2, a matrix liquid crystal display (LCD) 3, a heating electrode 4, a temperature sensor 5, a comparison unit 6, a reference voltage source 7, a switching unit 8, a mode control unit 9 heating and indicator 10 heating mode. The switching unit 8 comprises a typical mode switch 11 and a forced mode switch 12.

 The input unit 1 is designed to supply power to the detection unit (not shown) and for receiving and converting measurement signals from the detection unit. The input unit 1 contains a high voltage power supply for supplying this power to the detection unit. In addition, the input unit 1 contains an amplifier for amplifying signals from the detection unit and an analog-to-digital converter for sampling and quantizing the level of amplified signals from the detection unit and supplying them to the data processing unit 2. An analog-to-digital converter can process from 512 to 4096 measurement channels. The amplifier and the high-voltage power supply in the input unit 1 are controlled by the corresponding signals of the data processing unit 2. The specific implementation of the nodes included in the input unit 1 can be any, in order to ensure the proper operation of the detection unit and the preliminary processing of the results of its measurements, i.e. amplification and digitization. If, in conjunction with the spectrometric meter of the present invention, a detection unit is used, which outputs the measurement results already in digital form, then the input unit 1, in addition to issuing the corresponding supply voltages to the detection unit, serves as a unit for matching signals from the detection unit with the specific requirements of the processing unit 2 data.

 The data processing unit 2 is intended to at least process the measurement signals converted by the input unit 1 from the detection unit in accordance with a predetermined processing program. The data processing unit 2 is a computer or processor with memory, where the measurement data processing program is entered. Preferably, the data processing unit 2 can be equipped with a functional keyboard that allows you to work in dialogue mode with the LCD 3 and modify the data processing as desired. Block 2 computer can be made in the form of an IBM-compatible node, to which you can connect both peripherals (printer, external memory) and another computer (for example, over the network) for data exchange. The specific implementation of the data processing unit 2 is not included in the patent claims of the present invention and may be standard. The data processing program stored in the memory of the data processing unit 2 is intended to control the operation of all hardware of the spectrometer and provides, in particular: the accumulation of information in memory in the amplitude analysis mode, the display of graphic (in the form of histograms) and symbolic information on the LCD screen 3, and also provides the operator in interactive mode with an intelligent display. In addition, this program includes a subroutine for controlling the mode and heating power, the purpose and functioning of which are described below.

 Matrix liquid crystal display (LCD) 3 is designed to display the results of data processing in block 2 data processing. LCD 3 has any design on a glass substrate. For example, you can use LCD type IZHG96-240x80, produced by NPO Platan in Fryazino, Moscow Region.

On the reverse side of the glass substrate of the LCD 3, a heating transparent electrode is applied, intended for heating the liquid crystal display 3. The need for this heating electrode 4 is explained by the fact that when the ambient temperature decreases, the viscosity of the liquid crystal mixture in LCD 3 increases, which leads to an increase in the time for changing the displayed information. For example, at an ambient temperature of 0 ^o With the reaction time and relaxation time of the LCD 3 reach 0.7-1.0 seconds. To ensure the information change time is less than 1 second, the LCD 3 needs to be heated in the required range of negative temperatures. This purpose is served by a heating electrode 4, which generates heat when a corresponding current is passed through it.

 The temperature sensor 5 is designed to measure the ambient temperature in the immediate vicinity of the LCD 3. This temperature sensor 5 can be of any type with any unambiguous functional dependence of the output signal on the measured temperature, for example, a thermocouple or semiconductor. A specific type of temperature dependence of the output signal of this sensor 5 can be taken into account in the heating power control subroutine considered below.

 Comparison unit 6 is intended for comparing a signal from a temperature sensor 5 with a reference signal and for issuing a heating enable signal based on the result of this comparison. The comparison unit 6 exchanges the results of the comparison with the data processing unit 2.

 The reference signal to the comparison unit 6 is supplied from the source 7 of the reference signal, issuing a predetermined value of the reference signal.

The switching unit 8 is designed to supply power to the heating electrode 4 by the signal to turn on the heating from the comparison unit 6. In a preferred embodiment, the switching unit 8 includes a typical mode switch 11 for supplying such a power supply to the heating electrode 4, the power of which depends on the ambient temperature, and a forced mode switch 12 for supplying a predetermined power to the heating electrode 4, which exceeds the minimum possible power supplied to the heating electrode 4 by the switch 11 of the typical mode. The presence of two separate switches 11 and 12 is explained by the fact that in typical mode, the heating power must be increased by lowering the ambient temperature by every 10 ^o C. The specific heating power value is determined by the heat removal conditions and the difference between the required and ambient temperatures, so the specific power of the typical mode limited to some value W _T.

To reduce the availability time at negative ambient temperatures, a short-term (several minutes) forced mode of heating the LCD 3 with increased power is allowed, which, however, should not exceed about 2W- _T so as not to damage the LCD 3 due to heat stroke.

 The heating mode control unit 9 is designed to change the power supply supplied by the switching unit 8 to the heating electrode 4, under the control of the data processing unit 2, which receives the comparison results from the comparison unit 6. The heating mode control unit 9 is, for example, a separate controller programmed to control a switching unit 8, consisting, as already noted, of a typical mode switch 11 and a forced mode switch 12, according to a comparison with the comparison unit 6. In a preferred embodiment, the heating mode control unit 9 is included in a functional form in the data processing unit 2 and is implemented by means of a subroutine for changing the power supply supplied by the switching unit 8 to the heating electrode 4 according to the results of comparison with the comparison unit 6 in accordance with the above-described switching order in the unit 8. The specific form of this routine is not the subject of the present invention and may vary depending on the data processing program used in block 2.

 The indicator 10 of the heating mode is designed to indicate the presence of a signal to turn on the heating. This optional indicator 10 can be an LED and serves for the convenience of working with the spectrometric meter of the present invention in the field, when you want to monitor the energy consumption from the battery.

 The spectrometric meter of the present invention operates as follows.

 If it is necessary to carry out measurements, a detection unit (not shown) is installed on the measured sample, which may contain an ionizing radiation source and which is designed to receive signals from the test sample characterizing the radionuclide or elemental composition of this sample. When the spectrometer meter of the present invention is turned on, the input unit 1 supplies power to the detection unit connected to the meter and receives signals from the detection unit. These signals in the input unit 1 are amplified, digitized (if necessary) and are consistent (for example, in level) with the requirements of the data processing unit 2, where incoming digital samples from the detection unit are processed. The processing results are displayed on the LCD screen 3. If necessary, modify the measurement and / or data processing mode in block 2, the corresponding information is entered using the function keyboard 13.

At the same time, the temperature sensor 5 outputs the values of the measured ambient temperature to the comparison unit 6, which also receives the reference voltage from the source 7. In the preferred embodiment, the temperature sensor 5 starts to give measurement results only when the temperature reaches below -10 ^o C. When the signal level of the measured temperature is below the level of the reference voltage from the source 7, the comparison unit 6 provides a heating enable signal to the data processing unit 2 or directly to the switching unit 8, as well as a signal to ind Mode indicator 10 to signal that heating is on.

Regardless of whether, in the spectrometric meter of the present invention, there is a separate block 9 for controlling the heating mode or whether the heating mode is implemented using the corresponding subprogram in block 2, the block 2 for processing data by a signal from block 6 comparing the ambient temperature drops below the threshold (for example , below -10 ^o С) gives on the LCD 3 an offer to choose automatic or manual control of the heating mode. When choosing manual mode, the data processing unit 2 serves as a relay of commands entered by the operator from the keyboard 13.

When choosing the automatic heating mode, the data processing unit 2 for a given subroutine first gives a control signal to the forced mode switch 12 for the time specified by the subroutine, then it removes the signal from the switch 12 and supplies the control signal to the switch 11. Based on these signals, the corresponding switches 11 and 12 are connected heating electrode 4 with a source of appropriate power. The current flowing through the electrode 4, the magnitude of which depends on the switch specifically turned on in the switching unit 8, causes heat to be generated in this electrode 4. The generated heat heats the glass substrate of the LCD 3, preventing the viscosity of the liquid crystal from increasing. When the temperature of the LCD 3 rises to a predetermined temperature (for example, -10 ^o С), the temperature sensor 5 installed next to the LCD 3 gives a signal that becomes lower than the reference voltage level from the source 7, which leads to the removal of the signal from the comparison unit 6 and the power is turned off, supplied by the switching unit 8 to the heating electrode 4. Next, the heating mode will be repeated when the temperature measured by the sensor 5 drops below a predetermined level. At the same time, block 2 again prompts the operator to select a mode (automatic or manual) and will give out signals in accordance with the choice made.

 To save the energy of the battery used in the case of the spectrometer meter of the present invention in the field (for example, it can be a power source used in the car cigarette lighter), the operator can independently turn off the heating in any mode - stand-alone or manual - using the appropriate functional Keys on the keyboard 13.

 The presence in the spectrometric meter of the present invention of a data processing unit 2 equipped with an appropriate data processing program makes it possible to store the processing results (measurement results) in the memory of unit 2 without the need for a spectrometric meter to be connected to another computer.

Industrial applicability
The present invention can be used in spectrometric meters both stationary and portable type.

 The present invention is described by examples of its implementation, which are given only for illustration and do not limit its scope, defined only by the attached claims.

Claims (5)

 1. A spectrometric meter comprising an input unit for supplying power to the detection unit and for receiving and converting measurement signals from the detection unit, a data processing unit for at least processing the measurement signals converted by the input unit in accordance with a predetermined processing program, a liquid crystal display designed to display data processing results in a data processing unit, characterized in that heating is introduced into it a transparent electrode deposited on the back of the glass substrate of the liquid crystal display and intended for heating the liquid crystal display; a temperature sensor for measuring the ambient temperature in the immediate vicinity of the liquid crystal display; a comparison unit for comparing the signal from the temperature sensor with the reference signal and outputting heating enable signal according to the result of this comparison, a switching unit designed to supply power to the heating electrode according to the heating enable signal from the comparison unit.  2. The spectrometric meter according to claim 1, characterized in that it further comprises a heating mode control unit for changing a power supply supplied by the switching unit to the heating electrode under the control of a data processing unit that receives comparison results from a comparison unit.  3. The spectrometric meter according to claim 1, characterized in that the processing program in the data processing unit includes a subroutine for changing the power supply supplied by the switching unit to the heating electrode, according to the results of comparison with the comparison unit.  4. The spectrometric meter according to claim 2 or 3, characterized in that the switching unit includes a typical mode switch for supplying a power supply to the heating electrode, the power of which depends on the ambient temperature, and a forced mode switch for supplying to the heating a power electrode of a predetermined power exceeding the minimum possible power supplied to the heating electrode by a typical mode switch.  5. The spectrometric meter according to claim 1, characterized in that it further comprises a heating mode indicator intended to indicate the presence of a heating enable signal.