RU57896U1 - TEMPERATURE SENSOR - Google Patents

Abstract

The utility model relates to thermometry, namely, to contact temperature sensors and can be used in various industries, for example, in the food, oil, chemical industries and in public utilities for measurement at shallow depths, for example, in pipes of small diameter. The objective of the proposed technical solution is to ensure the operability of the sensor while increasing the accuracy of the measurement. The housing 1 of the temperature sensor has an external thread, is fixed in the pipeline with the installation head 2 and is closed in the upper part by a cover 3. It is connected in the lower part with a metal protective sleeve 4, in which a thermosensitive element 5, which is a quartz resonator, is fixed. The findings 6 of the latter by means of wires 7 are included in the circuit of the frequency generator 8 assembled on a printed circuit board 9 located in the housing 1. At the same time, the mounting head 2, the housing 1 and the sleeve 4 are made in the form of a functionally consistent integral, hollow inside, metal structure. The sleeve 4 is made with a variable thermal resistance along its length — minimum at the place of removal of heat flux and maximum at the place of heat removal to the converter. A quartz resonator 5 can be installed in the sleeve 4 if the measurement accuracy is required so that the points of attachment of the leads 6 to it are facing the bottom of the sleeve 4 (Fig. 1), or it is installed by the leads 6 upward from the bottom of the sleeve (Fig. 2), if particularly high measurement accuracy is not required. A printed circuit board 9 with a quartz oscillator 8 is placed under the cover 3 and is separated from the head 2 of the housing 1 by a nonmetallic sleeve-cup 10 with a hole 11 in the center, which coincides in diameter with the diameter of the hole in a single metal structure. The space between the walls of the hole in the sleeve 1 and the resonator 5 is filled with heat-conducting material 12, for example, quartz sand or heat-conducting paste, to a level just above the upper edge of the resonator housing 5. The space of the part of the hole in the housing 1 located above this level is filled with viscant 13.

The variable thermal resistance of the sleeve 4 along its length is provided, in particular, due to its shape. This is achieved, for example, by the fact that upon transition from the housing 1 to the sleeve 4 there is a tapering neck 14 to reduce heat removal from the sensing element, and in the middle part of the sleeve 4 its diameter increases, forming an additional annular extension 15 to increase the heat flux from the center of the stream liquids (or other local place). The installation head, housing and sleeve in the form of an integral metal structure avoids leakage of the structure during heating due to different expansion of elements in the temperature sensor (as occurs in the prototype) and ensures the operability of the device. The same purpose is served by placing a board with a quartz generator at a certain distance from the temperature measurement place and isolating it from the housing head by means of a nonmetallic sleeve, eliminating overheating of the generator elements and impairing its performance. Improving the accuracy of measurements is ensured by making the thermowell with a variable thermal resistance along its length - minimum at the place of heat flux removal and maximum at the place where the thermowell connects to the housing, thereby reducing the heat flux from the thermowell to the housing, which reduces heat removal from the sensing element, allowing the thermowell closer to the point of measurement to retain more heat and reducing the influence of the body on the amount of heat flux to the outside. 6 pf, 2 ill.

Description

The utility model relates to thermometry, namely, to contact temperature sensors and can be used in various industries, for example, in the food, oil, chemical industries and in public utilities for measurement at shallow depths, for example, in pipes of small diameter.

Known temperature sensor described in the same application of the Russian Federation No. 93025623 by class. G 01 K 7/32, c. 04/28/93, op. 05/27/95.

The known sensor is made in the form of a housing in which a crystalline quartz element is placed in the form of a truncated cone with the orientation yxb1 / 6 ° 44 '+ _ 1 ° / + 6 ° 02' _ + 1 °. Film electrodes are placed on the upper and lower base of the cone, and the internal volume is filled with helium.

A disadvantage of the known sensor is the design complexity, due to the complexity of the shape and orientation of the quartz element, as well as the need to fill the internal volume with helium.

The closest in technical essence to the claimed one is the temperature sensor used in CJSC PG "Metran", presented in the technical documentation SPGK 7050.110.00 "Thermocouples" Metran-299 "from 06.25.04 (see the Appendix to the application) and selected as a prototype.

The known sensor comprises a housing fixed in the pipeline by means of an installation head with a cover in the upper part, connected in its lower part by a threaded connection to a sleeve, in which a thermosensitive element is mounted, which is a quartz resonator placed by leads in the direction opposite to the bottom of the sleeve and connected by leads in a circuit of a frequency generator assembled on a printed circuit board located in a carrier tube. In this case, the free space between the quartz resonator and the inner wall of the sleeve is filled with heat-conducting material, the fitting and the sleeve are made of metal and have an internal thread, and the carrier tube has an external thread and is made of plastic. The circuit board is connected to external circuits via cable.

A disadvantage of the known sensor is the fact that the housing is made of plastic, and the installation head and sleeve are made of metal, as a result of which they have different coefficients of thermal expansion and when water begins to leak at the joint between the sleeve and the tube, water starts to leak into the sensor, which makes the structure inoperative. In addition, when a quartz generator board is placed in a carrier tube (housing) due to overheating of the generator elements, its operability can also be violated. In addition, in the known design of the sensor, part of the heat on the metal sleeve goes to the sensor housing, which reduces the accuracy of the measurements.

The objective of the proposed technical solution is to ensure the operability of the sensor while increasing the accuracy of the measurement.

The problem is solved in that in a temperature sensor containing a body with an external thread fixed in the pipeline by means of an installation head, closed in the upper part by a lid and connected in the lower part with a metal protective sleeve, in which a thermosensitive element, which is a quartz resonator, is fixed, conclusions which, through wires, is included in the circuit of the frequency generator assembled on a printed circuit board located in the housing, ACCORDING TO THE USEFUL MODEL, installation head, housing and sleeve flaxen in the form of a functionally consistent solid, hollow inside, metal structure, while the sleeve is made with a thermal resistance that is variable along its length — minimum at the place of removal of heat flux and maximum at the place of heat removal to the converter, and the printed circuit board with a crystal oscillator is located under the lid and is separated from the head of the body with a non-metallic sleeve - a glass.

In this case, thermal resistance, variable along the length of the sleeve, is provided due to the shape of the sleeve or its execution from materials with different thermal conductivity, or both.

In this case, the quartz resonator can be installed in the sleeve in such a way that the points of attachment of the leads to it are facing the bottom of the sleeve, or with the leads upward from the bottom of the sleeve in case of less high requirements for measurement accuracy.

The installation head, housing and sleeve in the form of a solid metal structure avoids leakage of the structure

when heated due to the different expansion of the elements in the temperature sensor (as occurs in the prototype) and ensures the operability of the device.

The same purpose is served by placing a board with a quartz generator at a certain distance from the temperature measurement place and isolating it from the housing head by means of a nonmetallic sleeve, eliminating overheating of the generator elements and impairing its operability. Improving the measurement accuracy is ensured by making the thermowell with a variable thermal resistance along its length - minimum at the place of heat flux removal and maximum at the place where the thermowell connects to the housing, thereby reducing heat flux from the thermowell to the housing, which reduces heat removal from the sensing element, allowing the thermowell closer to the point of measurement to retain more heat and reducing the influence of the housing on the amount of heat flux out.

The placement of the quartz resonator with the terminal mounting points down ensures that its most thermally sensitive point is located as close as possible to the measurement site, while reducing the length of the immersed part of the sensor, which is important when measuring temperature in pipes of small diameter, and at the same time increases the measurement accuracy. If a particularly high measurement accuracy is not required, then sufficient measurement accuracy is also achieved with the usual arrangement of a quartz resonator with leads upward from the bottom of the sleeve.

EFFECT: ensuring the tightness of the device and reliable operation of the generator, providing temperature measurement in the center of the fluid flow with minimal heat loss through structural elements.

In comparison with the prototype, the inventive temperature sensor has a novelty, differing from it by the presence of such essential features as the implementation of several functional units in the form of a single all-metal construction, the implementation of thermowells with variable thermal resistance along its length, and the placement of the circuit board with a signal converter at some distance from the temperature measurement site and isolating it from the metal casing with the help of a non-metallic sleeve, which together ensure the achievement of a given result.

The inventive temperature sensor can be widely used in thermometry for measuring temperature in various industries, for example, in the food, chemical, metallurgical industries and in municipal

economy, in particular, in pipes of small diameter, and therefore meets the criterion of "industrial applicability".

The inventive utility model is illustrated by drawings, where shown in:

- figure 1 is a General view of the sensor with a quartz resonator mounted downward;

- figure 2 is a General view of the sensor with a quartz resonator installed with the leads up.

The housing 1 of the temperature sensor has an external thread, is fixed in the pipeline (not shown in the drawings) using the installation head 2 and is closed in the upper part by a cover 3. It is connected in the lower part with a metal protective sleeve 4, in which the heat-sensitive element 5 is fixed, which is quartz resonator. The findings 6 of the latter by means of wires 7 are included in the circuit of a frequency generator 8 (not shown in the drawings) assembled on a printed circuit board 9 located in the housing 1. At the same time, the mounting head 2, the housing 1 and the sleeve 4 are made in the form of a functionally consistent integral, hollow inside metal construction. The sleeve 4 is made with a variable thermal resistance along its length — minimum at the place of removal of heat flux and maximum at the place of heat removal to the converter. A quartz resonator 5 can be installed in the sleeve 4 if the measurement accuracy is required so that the points of attachment of the leads 6 to it are facing the bottom of the sleeve 4 (Fig. 1), or it is installed by the leads 6 upward from the bottom of the sleeve (Fig. 2), if particularly high measurement accuracy is not required. A printed circuit board 9 with a quartz oscillator 8 is placed under the cover 3 and is separated from the head 2 of the housing 1 by a nonmetallic sleeve-cup 10 with a hole 11 in the center, which coincides in diameter with the diameter of the hole in a single metal structure.

The space between the walls of the hole in the sleeve 4 and the resonator 5 is filled with heat-conducting material 12, for example, quartz sand or heat-conducting paste, to a level just above the upper edge of the resonator housing 5. The space of the part of the hole in the housing 1 located above this level is filled with viscant 13.

The variable thermal resistance of the sleeve 4 along its length is provided, in particular, due to its shape. This is achieved, for example, by

the transition from the housing 1 to the sleeve 4 has a tapering neck 14 to reduce heat removal from the sensing element, and in the middle part of the sleeve 4 its diameter increases, forming an additional annular extension 15 to increase the heat flux from the center of the fluid flow (or other local place).

The temperature sensor operates as follows.

When the sensor is placed in an environment whose temperature it should measure, the protective metal sleeve 4 is heated, while heat is transferred to the quartz resonator 5, which changes the frequency of the output signal when the temperature changes. In this case, the sensitive part of the quartz resonator 5, facing the place of heat measurement, receives most of the heat through the terminals 6, which are turned inward to the medium flow, and which communicate with the generator board 9 by wires 7 passing inside the ring expansion 15, which heats them up, reducing the influence of the cold parts sensor on his testimony.

Sometimes, sufficient measurement accuracy is provided when installing a quartz resonator with 5 leads up. In both cases of the mentioned installation of the quartz resonator 5, the presence of an annular expansion 15 on the sleeve 4 in a place close to the center of the liquid flow allows the maximum amount of heat to be removed, and the narrowing neck of the sleeve 14 reduces the influence of the heat outflow from the terminals of quartz 5 on the sensor readings.

In comparison with the prototype of the claimed utility model provides reliable operation of the sensor and improving the accuracy of temperature measurement.

Claims (6)

1. A temperature sensor comprising a body with an external thread fixed in the pipeline by means of an installation head, closed at the top by a lid and connected at the bottom with a metal protective sleeve, in which a thermosensitive element is mounted, which is a quartz resonator, the terminals of which are connected via wires to a signal converter circuit made in the form of a frequency generator assembled on a printed circuit board located in the housing, characterized in that the installation head, the housing and the sleeve they are filled in the form of a functionally consistent integral, hollow inside, metal structure, while the sleeve is made with a thermal resistance varying along its length — minimum at the place of removal of heat flux and maximum at the place of heat removal to the converter, and the printed circuit board with a crystal oscillator is located under the lid and is separated from the head of the housing with a non-metallic sleeve-glass. 2. The temperature sensor according to claim 1, characterized in that a thermal resistance variable along the length of the sleeve is provided due to the shape of the sleeve. 3. The temperature sensor according to claim 1, characterized in that a thermal resistance variable along the length of the sleeve is provided by making the sleeve of materials with different thermal conductivity. 4. The temperature sensor according to claim 1, characterized in that a thermal resistance variable along the length of the sleeve is provided due to the shape of the sleeve and its implementation from materials with different thermal conductivity. 5. The temperature sensor according to claim 1, characterized in that the quartz resonator is installed in the sleeve in such a way that the points of attachment of the leads to it are facing the bottom of the sleeve. 6. The temperature sensor according to claim 1, characterized in that the quartz resonator is mounted in the sleeve in such a way that the points of attachment of the leads to it are facing upward from the bottom of the sleeve.