RU186482U1 - temperature sensor - Google Patents

Abstract

The utility model relates to thermometry and can be used to measure the temperature of liquids and gases under the influence of excessive pressure. The proposed temperature sensor contains a protective cover, a head, a measuring insert and an element of its fastening that separates the internal cavities of the head and a protective cover. A distinctive feature of the claimed temperature sensor is that it uses a sealing structural element that maintains tightness when exposed to the medium at operating pressure. The technical result is the preservation of the tightness of the temperature sensor when exposed to excessive pressure from the side of the inner cavity of the protective cover equal to the pressure at which the sensor can be operated, i.e. the design of the sensor does not allow the system to be depressurized if the integrity of the cover is violated. 4 s.p. f-ly, 4 ill.

Description

The utility model relates to thermometry and can be used to measure the temperature of liquids and gases under the influence of excessive pressure.

Known temperature sensors (thermoelectric transducers - thermocouples and resistance thermocouples - resistance thermometers) designed to measure the temperature of various environments, including those under excessive pressure. All sensors include a measuring (thermometric) insert, protective cover and terminal head. The measuring insert, as a rule, is a metal tube with one or two pairs of thermoelectrodes placed inside it, isolated between each other and the inner surface of the tube and welded together on the one hand, if this is a thermoelectric transducer, or connecting wires welded to the measuring resistor, in the case of a resistance thermometer. (Lineveg F. Temperature measurement in technology. Handbook. Translation into Russian. Publishing house "Metallurgy". 1980 p. 129, Fig. 3.67; p. 90 Fig. 3.35). A protective cover protects the insert from high pressure or pressure from the flow of the measured (thermometer) medium. The measuring insert is equipped with a structural fastening element in the form of a node or part positioning the position of the insert in the sensor and providing thermal contact of the end face of the insert and the bottom of the cover (fastening element). The fastening element, as a rule, divides the internal space of the head and the cover, preventing dust and moisture from entering the internal cavity of the cover when the head cover is open or the seal is not tight between the cover and the head body.

Known thermoelectric thermometer (thermoelectric converter), in which the measuring insert is made of a pair of thermoelectrode wires, insulated along the entire length between each other and protective fittings with ceramic tubes. A special putty seals the inner space of the protective cover from the head cavity and performs the fastening function and the sealing function of the measuring insert. (Temperature: theory, practice, experiment, Reference publication in 3 volumes, edited by A.M. Belenky, V.G. Levitsky, volume 2, Heat engineer, M., 2007, pp. 89-90). Sealing prevents dust and moisture from entering the internal cavity of the case when the head cover is open or if the seal between the cover and the head housing is broken.

Also known is the design of KTHA sensors of modification 01.07 (TESEY Production Company PRODUCT CATALOG 2016, TAFARET, 2015, p. 2-27), the measuring insert of which is made in the form of a cable thermocouple and has a mounting element in the form of a fitting with thread on both sides, fixed on the shell of the insert using mechanical compression. A cable thermocouple is a flexible metal tube with one or two pairs of thermoelectrodes placed inside it, parallel to each other. The space around the thermoelectrodes is filled with compacted finely divided mineral insulation. The thermoelectrodes of the cable thermocouple from the side of the working end are welded together, forming a working junction inside the steel shell. The end face is drowned out by a welded steel stopper. The free ends of the thermoelectrodes are connected to the terminals inside the head of the thermal converter or compensation wires. On the attachment site in the form of a fitting, the thread on one side serves to install the insert in a protective cover and ensure contact of the end face of the insert with the bottom of the cover, on the other a head is screwed onto it. Resistance thermometers ТСМТ, ТСПТ modifications 107 have a similar design (TESEY Production Company PRODUCT CATALOG 2016, TAFARET, 2015, pp. 6-18). In the described construction, the fastening element in the form of a fitting separates the internal cavities of the head and the protective cover and prevents, as in the above described construction, the ingress of dust and moisture into the internal cavity of the cover in case of a leak in the head, i.e. performs both the sealing function and the positioning function of the insert in the case.

A common drawback of all known designs of temperature sensors is that the mounting element of the measuring insert and (or) the sealing element separating the internal cavities of the head and the protective cover is not designed for the influence of the measured medium under excessive pressure, which in case of violation of the integrity of the cover will act on him. Such an effect can lead to the destruction of the fastening element and the medium to be measured into the head and then into the environment, since the design of the head is not designed for the effect of excessive pressure from the side of the internal cavity. The release of the measured medium into the environment is unacceptable both from the point of view of safe operation of the facilities and the negative environmental impact on it.

The proposed utility model solves the technical problem of eliminating this drawback, namely, it prevents the release of the measured medium under the influence of excess pressure and (or) under the pressure of the flow from the object into the environment if the integrity of the protective cover of the temperature sensor is violated.

The technical result of the utility model consists in maintaining the tightness of the temperature sensor when exposed to excess pressure from the side of the inner cavity of the protective cover equal to the pressure at which the sensor can be operated, namely, at the nominal (conditional) pressure PN of 6.3 MPa, i.e. the design of the sensor does not allow the system to be depressurized in case of violation of the integrity of the cover.

To solve this technical problem and achieve the claimed technical result, a temperature sensor is proposed that includes a protective cover, a head, a measuring insert and an element of its fastening, equipped with a structural element that provides tightness when exposed to pressure from the internal cavity of the cover of the medium, equal to overpressure, in which the sensor is operated, which prevents the measured medium from entering the head cavity and further into the environment.

The essence of the technical solution is illustrated by the following description and the accompanying drawings.

In FIG. 1 shows a General view of the temperature sensor with a sealing structural element, where:

1 - measuring insert;

2 - fastener;

3 - sealing structural element;

4 - a protective cover;

5 - screws;

6 - head.

Measuring insert (1) equipped with a fastening element (2). The sealing structural element (3) is placed in the upper part of the protective cover (4), between its inner surface and the insert, so that it separates the inner space of the cover from the head cavity. The position of the insert is fixed, for example, by screws (5) screwed into the head housing (6).

In case of violation of the integrity of the protective cover, the measured medium, which is under excess pressure, enters the internal cavity of the cover. Further penetration of the medium into the head cavity is prevented by the sealing structural element.

In FIG. 2 shows an embodiment of a temperature sensor, where the measuring insert (1) is equipped with a fastening element (2) in the form of a plate welded to the shell of the insert. On the shell of the insert (1) is sealed structural element (3) of a polymer material or rubber having a conical section. When mounting the insert in a protective cover (4) due to the mechanical effect of the fastening element on the sealing element having plasticity, the space between the surface of the shell of the insert and the inner surface of the cover is sealed. The position of the insert is fixed by spring-loaded screws (5), screwed into the head housing (6).

In FIG. 3 shows an embodiment of a temperature sensor, where a fastening element (2) is welded (soldered) to the shell of the measuring insert (1) in the form of a fitting. The insert with the fitting is screwed into the protective cover (4) through the sealing structural element (3) in the form of a gasket. Also, the thread retainer or sealant filling the gaps between the threads is able to perform the function of the sealing structural element (3).

In FIG. 4 shows an embodiment of a temperature sensor, where a fastening element (2) is welded (soldered) to the shell of the measuring insert (1) in the form of a fitting having thread on both sides. The insert with the fitting is screwed into the protective cover (4) through the sealing structural element (3). The head (6) is screwed onto the other side of the fitting.

To test the proposed technical solution, three samples of temperature sensors presented in figures 2, 3 were made. The measuring insert of the sensors was made in the form of a cable thermocouple with a shell diameter of 3 mm. The protective cover is made of 12X18H10T pipe with a diameter of 10 mm and a wall thickness of 1 mm. A fitting with a thread of 20 × 1.5 and a thrust ring with a diameter of 18 mm were used as elements for mounting sensors on the object. Sensors with this version of the protective cover and mounting elements are designed for a nominal (nominal) pressure PN equal to 6.3 MPa ¹ , which means that the tests must be carried out with a test pressure of 9.5 MPa.

For testing, the cap of the cover was cut off, and the sensors were subjected to hydrostatic pressure of 9.5 MPa. As the medium used water. The sealing structural elements of all sensors have successfully passed the test.

Further, for sensors with a sealing component shown in FIG. 3, the pressure was raised to 15 MPa, the sealing structural element also passed the test, which indicates the possibility of using this design in sensors designed for a nominal pressure of 10 MPa.

The use of the inventive temperature sensor can prevent the release of the measured medium into the environment in case of violation of the integrity of the protective cover of the temperature sensor due to the sealing structural elements made in accordance with FIG. 2 - FIG. 4, and the corresponding fastening elements, which ensure the tightness of the thermometer object when exposed to a measured medium at operating pressure.

Claims (5)

1. The temperature sensor, which includes a protective cover, a head, a measuring insert and an element of its fastening, separating the internal cavity of the head and a protective cover, characterized in that it uses a sealing structural element that maintains tightness when exposed to the medium at nominal (conditional ) a pressure equal to or greater than 6.3 MPa. 2. The temperature sensor according to claim 1, characterized in that the sealing structural element is made in the form of a cone plug of elastic material. 3. The temperature sensor according to claim 1, characterized in that the fastening element is made in the form of a fitting welded or soldered to the shell of the measuring insert and screwed into the inner cavity of the protective cover through a sealing structural element in the form of a gasket. 4. The temperature sensor according to claim 3, characterized in that the thread retainer or sealant performs the function of the sealing structural element. 5. The temperature sensor according to claim 3, characterized in that the fastening element in the form of a fitting is threaded on both sides for connection with a protective cover and a head.

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