RU2668351C1 - Installation for control and/or calibration of submersible multipoint temperature sensor placed inside the tank - Google Patents

Abstract

FIELD: measuring equipment.SUBSTANCE: invention relates to thermometry, namely to means for calibrating and calibrating multi-point temperature sensors, which are designed for continuous measurement and control of the temperature of liquid products in reservoirs of technological and commodity parks at several points along the filling height of the tank. Installation includes a spacer with flanges and an internal groove, a frame with reference thermal sensors, which is arranged to accommodate a measuring probe with a multi-point sensor inside the frame, as well as a drum with a coil and a measuring cable connected to said frame. In this case, the arms of the frame are located concentric to the surface of the measuring probe and coaxial with the multi-point sensor, and the drum is provided with a cylindrical element.EFFECT: creation of an installation that is simple to install and has a small size for checking and/or calibrating a submersible multi-point temperature sensor located inside the tank, not requiring dismantling of equipment and a verified multi-point temperature sensor, which is installed directly on the tank with a working, including explosive, environment.3 cl, 7 dwg

Description

The inventive installation relates to thermometry, and in particular to means of verification and calibration of multi-point temperature sensors, which are designed for continuous measurement and control of the temperature of liquid products in the tanks of technological and commercial parks at several points along the height of the tank.

Multipoint sensors are made in the form of a cable cable in the casing, inside of which are integrated thermometers (up to 16 or more pieces). In the upper part of the cable, a primary converter is connected, which has a molded case and is located outside the tank. The primary converter is an electronic unit that performs the following functions: receiving temperature information from sensitive elements (integral thermometers) and issuing this information by sensor commands to the communication line (http://www.albatros.ru/catalog/products/sensors-of -temperature-density-pressure / the-dtm2-multipoint-temperature-transmitters.php). The multi-point sensor is housed in a sealed enclosure that is resistant to aggressive media, called an immersion probe.

A device for monitoring the reliability of the readings of a thermoelectric converter during its operation, which is made in the form of a cable thermocouple, the working part of which is placed in the inner space of the protective cover next to the heat-sensitive element with an emphasis on the end face of the protective cover (RU 2325622, published on 05.27.2008 )

However, the known device is not intended for verification and calibration of multipoint sensors in liquid and explosive atmospheres and is only suitable for measuring temperatures in process furnaces.

The prior art devices for checking and / or calibrating an immersion multi-point temperature sensor, placed together with a measuring probe inside the tank, which are installed directly on the tank with a working explosive atmosphere, which do not require dismantling of equipment and a multi-point temperature sensor, while having small dimensions and easy to install.

The technical result is the creation of a simple installation and having a small installation for checking and / or calibrating a submersible multi-point temperature sensor located inside the tank, which does not require dismantling of equipment and a verified multi-point temperature sensor, which is installed directly on the tank with a working, including explosive Wednesday.

The specified technical result is achieved as a result of the fact that the installation for checking and / or calibration of an immersion multi-point temperature sensor located inside the tank contains a spacer with flanges and an internal groove, a frame with reference temperature sensors, which is designed to accommodate a measuring probe with a multi-point sensor inside the frame as well as a drum with a reel and a measuring cable connected to the specified frame.

The inventive spacer shape provides mounting of the multi-point sensor over the mounting part of the reservoir opening with the working medium without dismantling it. To ensure the movement of the frame along the measuring probe of the sensor being verified, as well as the possibility of fixing the frame, an internal groove is provided in the spacer. The groove also allows the operator to freely place the frame and the measuring cable on the same axis as the sensor being verified.

The implementation of the frame with the reference temperature sensors with the possibility of placing a measuring probe with a multi-point sensor inside the frame allows you to place the reference temperature sensors as close to the surface of the measuring probe, and, accordingly, to the sensitive elements of the calibrated multi-point sensor itself.

Moreover, according to paragraph 2 of the formula, the shoulders of the frame are concentric with the surface of the measuring probe and coaxially a multipoint sensor, which allows you to limit the volume of the medium in close proximity to the sensor element of the sensor at its place of use and use the method of direct comparison of temperature fields near the sensor sensor elements and the reference thermometer.

The presence of a drum with a coil and a measuring cable connected to the specified frame, allows the frame to move along the measuring probe from the beginning to its end.

The presence of a cylindrical element of the drum during vertical movement of the cable allows you to raise and lower it at the right angle, preventing bending or abrasion of the cable, and also simplifies the orientation of the frame along the axis of the probe (paragraph 3. of the formula).

The invention is illustrated by the following figures.

In FIG. 1 presents a General view of the inventive installation.

In FIG. 2 is a perspective view of a spacer in isometry.

In FIG. 3 shows the inventive installation assembled before

verification and / or calibration work.

In FIG. 4 shows a frame with a measuring probe inside the frame.

FIG. 5 - element I in FIG. one.

FIG. 6 is a section AA in FIG. one.

FIG. 7 is a view B in FIG. one.

The installation consists of the following nodes.

The spacer 1 is made with an internal groove 2 along the entire length of the spacer 1 and two C-shaped adaptive flanges 3, 4 for mounting the calibrated multi-point temperature sensor 5 over the mounting part 6 (flange) of the tank 7 and placing other elements of the device in the groove 2 on the same axis with sensor 5.

The frame 8 has a shape that allows it to move along the outer surface of the measuring probe 9 of the sensor 5 to be verified. The main axis of the frame 8 is formed by the main cable channel 10, inside of which are laid the cable lines to the reference temperature sensors 11.

Frame 8 can be equipped with any temperature sensors based on various principles of temperature measurement, for example, on the dependence of the electrical resistance of conductors on temperature, or on the ability to induce thermo-emf metals, etc.

The reference temperature sensors 11 are fixed in the ports 12 located on the shoulders 13 of the frame 8 using cold or hot interference, depending on the material of the frame 8.

The cable lines of the temperature sensors 11 are connected to a measuring unit (not shown).

The shoulders 13 can be made in the form of a circle, oval, polygon, etc., depending on the profile of the measuring probe 9 and the number of reference temperature sensors 11.

The second cable channel 14 of the frame 8 is intended for the cable line, and also serves as a stiffener for the frame 8.

Frame 8 forms the volume in which the temperature of the measured medium is monitored and the maximum proximity and minimum distance of the reference (exemplary) temperature sensors 11 to the surface of the measuring probe 9 of the multi-point temperature sensor 5 is provided. The arms 13 of the frame 6 are concentric with the surface of the measuring probe 9 and coaxially with the multi-point sensor 5.

Coil 15 serves as a roulette and serves to move the frame 8 along the probe 9. Coil 15 is mounted on the flanges 3 and 4 by screw or bolt connections 16. On the side of the coil 15 there is a cover 17 that serves as a process port for mounting the measuring cable 18 in the drum 19. The cable 18 is mounted in the hole 20 of the drum 19, which is mounted on the housing of the coil 15 by the return cover 21 using the nut 22 through a bronze insert 23, which provides rotation of the drum 19.

The vertical movement of the cable 18 using a cylindrical element 24 provides the lowering of the measuring cable 18 at the desired angle, which prevents bending or abrasion and simplifies the orientation of the frame 8 along the axis of the probe 9.

The handle 25 serves for winding and winding the measuring cable 18 together with the frame 8 on the coil 15.

Installation of the inventive installation and verification work is as follows.

A multi-point temperature sensor 5 is disconnected from the flange of the tank 7 on which it is mounted, and lifted by a distance equal to the height of the spacer 1. The spacer 1 is placed between the flanges of the tank 7 and the sensor 5, without disconnecting the measuring probe 9 from the measuring line (not shown), securing spacer 1 on tank 7.

A coil 15 with a cable 18 and a frame 8 with reference temperature sensors 11 is attached to the spacer 1. The probe 9 is placed inside the frame 8 so that the reference temperature sensors 11 of the frame 8 are in close proximity to the surface of the probe 9.

The power of the installation is connected to the coil 15, and a measuring unit (not shown) is connected to the terminals of the measuring line of the coil 15. Measurements are carried out at the depths specified in regulatory documents.

After stabilizing the temperature, reference measurements are made using all transducers 11 (for example, six) using transducers and communication lines (not shown). Then the frame 8 is lowered or raised on the measuring cable 18 to the next measuring point, then the operation is repeated for the remaining sensitive elements (integral thermometers) of the verified sensor 5.

The installation allows you to measure the temperature of the medium not at one point, but in the entire controlled volume in the immediate vicinity of each sensitive element (integral thermometer) of the calibrated multi-point temperature sensor, therefore, it ensures the reliability of the measurement results, acceleration and facilitation of the verification and / or calibration of the submersible multi-point temperature sensor in operating conditions without dismantling, and also replaces the sampling method from the reservoir, which as a result Due to a multitude of technical and methodological factors, it is not possible to adequately evaluate the measurement information.

Claims (3)

1. Installation for checking and / or calibration of an immersion multi-point temperature sensor located inside the tank, comprising a spacer with flanges and an internal groove, a frame with reference temperature sensors, which is arranged to accommodate a measuring probe with a multi-point sensor inside the frame, as well as a drum with a coil and measuring cable connected to the specified frame. 2. Installation according to claim 1, characterized in that the shoulders of the frame are concentric with the surface of the measuring probe and coaxial with the multipoint sensor. 3. Installation according to claim 1, characterized in that the drum is equipped with a cylindrical element.

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