KR890017716A - Measurement and monitoring system using micro difference temperature sensor - Google Patents

Abstract

No content

Description

Measurement and monitoring system using micro difference temperature sensor

Since this is an open matter, no full text was included.

1 is a front view of a split-well thermowell housing of a first sensor embodiment usable in one embodiment of a measurement and monitoring system in accordance with the present invention. 4 is a cross-sectional view of the sensor assembly of the first embodiment, taken along a plane including the axis of the split-well hotplate housing of FIG. 9 is a schematic block diagram of a measurement and monitoring system using a plurality of split-well type sensors according to a first embodiment of the present invention.

Claims (22)

A measuring system for monitoring the fluid state inside a pressure vessel containing steam and variable phase, comprising at least one dual micro-difference temperature sensor (a), which is in use with the liquid contained within the pressure vessel. Complementary set of two probes comprising at least two pairs of temperature measuring probes 12A, 12B, heaters HTR: A, B and a temperature sensing element C) (CTC: A ₁ , A ₂ ) wherein the complementary set is in relation to one of the probe pairs by combining with the associated probe pair (b) and heating one of the probe pairs when activated Define a probe that is heated and reference, sense the probe, and produce a corresponding sensed temperature output with a micro-difference temperature d, the micro-difference temperature being one probe of the sensor (a) To the steam state inside the pressure vessel and In a measurement system that is at an upper value and a lower value at exposure to a state, the at least two identical temperature measuring probes are thermally insulated from each other, and a predetermined set of complementary sets of heaters and predetermined temperature sensing elements. Selective activation means (e) for selectively activating a heater element; Means (f) for determining the micro-difference temperature between a predetermined set of sensed temperature outputs of the complementary sets and generating a corresponding micro-difference temperature output, and selecting one of the two complementary sets as the operating set in normal monitoring mode And to maintain the rest of the set in standby, controlling the selection activation means to activate the selected set and determining the temperature difference between the sensed temperature outputs of the selected set to produce a corresponding sensed temperature differential output. And a control means (g) for controlling the determination means. Means (h) for determining the non-operability of any one of the temperature sensing of the predetermined sensor and the complementary set (C) of the heater elements, and generating a corresponding non-operational element output, In response to the non-operable element output of the judging means (h) in the normal monitoring mode, corresponding to the selected set of operability, the rest of the complementary sets are selected as standby as the set of operability and controlling the selection activating means (e); And control means (e) for activating said determining means for determining a temperature difference between the selected different set of sensed temperature outputs. 3. The system according to claim 2, further comprising sensor display means (i) for generating a display mark of the non-operable element in response to the non-operable element output. The method according to claim 1, wherein an upper value and a lower value of the reference temperature micro-difference value of the temperature micro-difference output value of the judging means generated in response to a predetermined set of sensed temperature outputs are defined, and respectively corresponded to the steam and the pressure inside the pressure vessel. Means (j) for exposing the probe pair of the sensor to a water condition and the sensed temperature micro-difference output of the judging means generated in response to a set of sensed temperature outputs with a selected operability to the reference temperature. And means (k) for generating an alarm output when the sensed temperature difference difference output is less than the reference temperature temperature difference value, in comparison with the minute difference value. 5. The control device according to claim 4, wherein said control means (g) is operable in a verification mode in response to the alarm output of said comparing means, selecting elements of different complementary sets into a standby state and controlling said activating means to select other selected means. A system for activating determining means for determining a difference between selected temperature outputs of a complementary set and generating a corresponding sensed temperature differential difference output. 6. The system according to claim 5, further comprising means for comparing the temperature micro-difference outputs of the generated judging means for the given sensor in the monitoring mode to compare the alarm outputs to confirm the alarm condition in the verify mode. 7. The system of claim 6, further comprising means for generating an alarm indication mark in response to the alarm output. 2. The apparatus according to claim 1, further comprising means (h) for determining which temperature sensing of a given sensor and nonoperability of the complementary set of heater elements to produce corresponding nonoperating element outputs, said control means being a normal Kimsi mode. Is optionally operated during online testing in the step of selecting another complementary set as standby as in the operability set and controlling the selection activation means to activate the judging means for determining the difference between the sensed temperature outputs of the selected other complementary sets. System. 9. The method of claim 8, further comprising: activating and judging means respectively coupled to a plurality of micro-temperature sensors, control means having system control means, a plurality of sensor control means coupled to a plurality of sensors, and online testing of the coupled sensors. And system control means for controlling a plurality of sensor control means to execute the system. 10. The apparatus according to claim 9, further comprising means for comparing the micro-difference temperature outputs generated during normal online monitoring and normal monitoring mode by a plurality of judging means for examining the operation of each corresponding sensor. system. 11. The system of claim 10, further comprising a system display means (n) for displaying respective temperature micro-difference outputs during online testing of the normal monitoring mode and the plurality of determination means related to the indications of the plurality of sensors. system. 12. The apparatus according to claim 11, wherein the system display means (n) displays the micro-difference temperature output only for a single set of selected sensors, and in monitoring mode and online testing the system control means comprises a plurality of sensor control means and a plurality of sensors and A plurality of determination means are continuously selected individually, and the respective micro-temperature difference outputs are displayed in the system relating to the respective continuous display and the marking of the selected sensor corresponding to each sensor set selected in the monitoring mode and each sensor complementary set in online testing. Supplying means. 12. The system of claim 11, wherein the system display means further comprises a plurality of alarm indication display means, each corresponding to a plurality of sensors, wherein the alarm indication display means informs of an alarm condition associated with each sensor. 14. The apparatus of claim 13, further comprising: means coupled to each sensor to determine the non-operationality of any temperature sensing and complementary set of heating elements and to produce corresponding non-operational element outputs and corresponding determinations for the selected set of operability. A plurality of sensor control means operable to produce a non-operable set output in response to the non-operable element output of the means and to generate a failed sensor output in response to receiving the non-operable element output of the two complementary sets of determination means; Control means for supplying the output of the failed set and the failed sensor output of the plurality of sensor control means to the system display means according to the instructions of the corresponding sensor; and in response to the instructions of the corresponding sensor in response to the output of the failed set and the failed sensor output, respectively. The system display means together with means for displaying the failed set and the failed sensor indication separately. The system comprising:. 10. The system of claim 9, further comprising operator control means for selectively controlling system control means to perform selected online testing of multiple sensors. 10. The device of claim 1, wherein each compensation set includes a separate heater element and two temperature sensing elements, each pair of probes having one separate heater element disposed therein and two symmetrically disposed about the heater element. One of said heater elements and temperature sensing elements of the probe and one of the temperature sensing elements of the remaining probes constitute a first complementary set, and separate heaters of the remaining probes of the pair The system and the remaining temperature sensing elements of the pair of probes constitute a second complementary set 2. The complementary set of claim 1, wherein each complementary set comprises an integrated heater and a pair of temperature sensing elements, the probe pair of sensors has an integrated heater / temperature sensing element of one phase, and each integral element is linearly variable with temperature. It has a resistance value and can be operated as a temperature sensing element to produce a sensed temperature output and optionally as a heater element that heats the associated probe when activated, and any heater / temperature sensing element of the probe is Coupled to and integrated with a heater / temperature sensing element of the first and second heater / temperature sensing element complement sets for the probe pair of the given sensor, the control means being the first heater in the normal monitoring mode. / Temperature sensing element complementary set is selected for operation, the second complementary set is left in standby, and the activating means is controlled to Pro right system, comprising a step of activating a predetermined one of the integrated heater / temperature sensing element of the set selected in relation to a predetermined one of beussang. 18. The apparatus of claim 17, further comprising: means for determining the bar operability of any temperature sensing / heater complementary set of a given sensor to produce a corresponding non-operating element output, and in response to the non-operating element output of the determining means in a normal monitoring mode. And control means for selecting one set and raising the rest to standby and controlling the activation means to activate the selected other set of heaters / temperature sensing elements associated with the other probes of the pair. System. 18. The apparatus of claim 17, wherein the activating means comprises a bridge circuit having first and second legs connected in parallel between the first and second junctions, and in series with the first and second heater / temperature sensing elements of the complementary set. A first and a second constant current source connected, wherein in each of said first and second legs a series connection of said first and second legs defines a third and a fourth junction, activating a device such as a heater element. A first constant current source for supplying a first current of a level sufficient to cause the first element of the first leg and the second heater / temperature sensing element to be slightly heated by a second level current flow. A second constant current source connected to a second leg for supplying a second current level with a proportional low proportional rate to the second element, a differential amplifier having first and second inputs and outputs, and a series junction of the bridge network. Contact the first and second input terminals of the differential amplifier Means for normalizing each voltage output present in the third and fourth junctions for a reciprocal of the proportionality ratio according to the first and second current levels flowing through the first and second heater / temperature sensing elements; And said differential amplifier producing a micro-difference temperature output representative of the difference between each sensed temperature output of a set of integral heater / temperature sensing elements. 18. The method of claim 17, wherein the activating means supplies the integrated first and second heaters / temperature sensing elements of a predetermined complementary set with high and low levels of constant current at known rates to their corresponding high and low levels. Means for causing the output voltage to be generated as a sensed temperature output value, wherein a high level of current that sufficiently heats any first heater / temperature sensing element enables the element to function as a heater and its corresponding probe Makes it possible to enable it as a heated probe, the low level current slightly heats any second heater / temperature sensing element and enables the probe coupled to it to function as a reference probe System. 21. The apparatus of claim 20, wherein said determining means determines the difference between the sensed temperature outputs to produce a corresponding sensed temperature differential output and that each voltage output level of the first and second integrated heaters / temperature sensing elements is known. And a means for changing the inverse proportionality. 22. The apparatus of claim 21, wherein the determining means comprises means for providing a continuous reference range of voltage values consistent with the sensed temperature output voltage value range of the integral heater / temperature sensing element in operation; And means for comparing the sensed temperature output voltage with a continuous reference range of voltage values to produce a non-operable element output when the sensed temperature output voltage is not within the continuous reference range. ※ Note: The disclosure is based on the initial application.