RU192123U1 - MAGNETOINDUCTION CONVERTER FASTENING ASSEMBLY TO THE HEAT CARRIER CHANNEL - Google Patents

Abstract

The utility model relates to the technology of operation of nuclear power plants and can be used to replace magnetic inductance transducers (MIP) of ball flow meters. The mounting unit of the magnetic induction converter comprises a housing, a holder for mounting the MIP, a restrictive bar for fixing the course of movement of the holder, a spring mechanism for fixing the required position of the holder, made in the form of springs located on the axes, pins to support and tilt the holder, the spring mechanism and the pins are located on both sides of the transducer housing, and the shape of the holder is made in such a way that the lower part allows you to securely fasten the MIP on the coolant housing, but rather s upper part allows you to visually monitor the correct fixation of the IIP. The design of the mounting unit provides the ability to mount and dismantle the MIP in the installation sites as accurately as possible with minimal time without significant preparatory and repair work. At the same time, the existing design of attachment points on the coolant body remains unchanged. 2 ill.

Description

The utility model relates to the operation technology of nuclear power plants and can be used when replacing magneto-inductive transducers of ball flow meters.

The magneto-induction converter (MIP) is intended for use in the technological channels (TC) of the RBM-K reactor, working together with the ShADR flow converter to measure the flow rate of the working medium flowing through the RBM-K reactor TC. MIP has a strictly limited service life and requires replacement by applying a fastening mechanism to the coolant body.

In the patent materials, the MIP is indicated as a signal pickup unit and is most often or simply listed as part of the flowmeter (RF patent documents No. 2566428, 2000100214, 2215996, 2399822, 93057153, 35429, 96100131, 2118003) or is shown in the figures or figures in addition to the listing schematically in the form of a quadrangle (patent documents of the Russian Federation No. 1806328, 1591618, 2253843, 55968, 51731, 2037142, 78928). In both cases, in the documents found it is not possible to understand the design and principle of operation of the converter mounting mechanism.

A technical solution is known "Method of installation of a primary transducer of a ball flow meter" (RF patent No. 2422775 of 03/02/2010) including hydraulic connection of pipelines supplying and discharging the measured medium to the straightener and auger located on opposite sides of the rotation chamber of the ball from the ball rotation chamber and different the fact that the primary transducer of the ball flow meter and pipelines are installed in such a way that the pipeline supplying the medium to be measured and the flow straightener p spolagayutsya lower ball rotation chamber and discharging the measured medium conduit and arranged above the screw of the ball rotation chamber.

Known technical solution "Ball flow transducer with an angular supply of the measured medium" (RF patent No. 53769 dated 12/15/2005) comprising a housing, a flow swirl forming an annular cavity with a housing in which a ball, a flow rectifier and a signal pick-up unit are located, characterized in that an additional flow straightener is installed at the flow inlet into the housing, having crossed vanes of unequal length, at least one of which is curved towards the flow in the plane of its rotation.

A technical solution is known “A method for replacing ball-type flowmeters of a coolant on a water-graphite nuclear reactor circulation loop” (RF patent No. 21118003 dated 04/02/1997), comprising dismantling the replaceable and installing replacement flowmeters, characterized in that after dismantling the replaced flowmeter is subjected to deactivation, removed rolled into the body the head band, the head is turned away from the body, the flow swirl is removed, the swirl together with the body is subjected to deep decontamination, the replacement head is assembled with replacement with a bushing, ball and swirl, screw the replacement head onto the body of the flowmeter, roll its belt into the groove of the body and undergo hydraulic tests, and replaceable bushing with the ball and head are buried.

The patents on the image No. 21118003 and No. 2422775 show the MIP attachment point to the coolant in a section, on which the body and holder (latch) are indicated, but is not shown, and the principle of operation of the attachment mechanism mechanism is not described in the text of the description.

In patent No. 53769 in figure 3, in more detail than in the above analogs, the components of the MIP fastening mechanism are shown, namely, the housing, holder (latch), spring, strap for restricting the MIP stroke, a screw for fixing the spring travel.

In the text of the patent, the components are not indicated and, as well as in other analogues, the principle of operation of the mechanism of the fastener assembly is not described.

It can be assumed that with a greater degree of probability the design of the converter is the same in all analogues, therefore, analogues have the following disadvantages:

- the holder is made in the form of a plate with a thickness of not more than 2 mm, the protrusion of which is attached to a special groove of the carrier strip.

- the attachment point is located only on one side, respectively, fixing the protrusion of the holder for the groove of the carrier strip also occurs only on one side.

The use of a mounting unit of this design can lead to the fact that under vibration a misalignment of the MIP is possible with subsequent undesirable detachment of the MIP from the heat carrier strip.

- because when installing the MIP, the handle and the protrusion of the holder are located on the lower side of the MIP, then when fixing to the coolant channel, an additional visual check is required to confirm the correct installation of the MIP. Why does it take extra time to perform additional actions, which is unacceptable in the conditions of operation of the RBMK-K reactor. If there is a need to replace the converter, the dismantling and installation of the converter must be done as accurately as possible with minimal time.

The proposed technical solution allows to eliminate the above disadvantages and is aimed at improving the reliability of the flow control system in the fuel cell, reducing acquisition costs and operating costs.

The technical solution is achieved by the fact that the design of the lower part of the holder of the mounting unit allows you to quickly and reliably fix the MIP on the coolant body, and the position of the upper part of the holder allows quick visual control of the correct position of the holder.

The figure 1 shows the design of the MIP with the fixation unit to the side of the coolant housing on the side.

The figure 2 shows the design of the MIP in front.

The MIP mounting assembly consists of a housing 1, a holder 2 for mounting the MIP on the coolant housing, a spring mechanism consisting of springs 3 on both sides of the housing 1 for fixing the required position of the holder and axles 4 on both sides of the housing 1 to maintain the direction of action of the springs 3, restrictive straps 5 to limit the movement of the holder and the pins 6 on both sides of the housing 1, designed to stop and tilt the holder 2.

The mechanism of the mounting unit works as follows: it is necessary to move the upper part of the holder 2 towards the heat carrier body (shown in Fig. 1 by an arrow), while the inclination of the middle part of the holder 2 is fixed on both sides of the housing 1 with pins 6, and the lower part of the holder 2 is pressed to the springs 3 located on the axles 4. Then the MIP is installed on the bar 7, mounted on the body of the coolant and the holder 2 is released. The springs 3 return to their original position, directing the middle part of the holder 2 to the stop with the restrictive bar 5, and the lower part of the holder 2 under the bottom of the bar 7 reliably fixing the MIP on the coolant body.

The transmitter is dismounted as follows: the upper part of the holder 2 is pushed towards the heat carrier body, while the lower part of the holder 2, bringing the springs 3 into a compressed position, moves away from the bottom of the strap 7 and the holder 2 is disconnected from the heat carrier body. The holder 2 is released and the springs return to their original position. Dismantling completed.

This mount prevents incorrect installation of the MIP, as:

- the width of the lower part of the holder 2 corresponds to half the width of the strap 7, which provides an increase in the surface area of the approach of the holder 2 under the strap 7 without distortions.

- by the position of the upper part of the holder 2, you can check whether the lower part of the holder 2 has come under the bar 7, making a quick visual inspection.

- the arrangement on both sides of the transducer of spring mechanisms and pins 6 provide uniform fixation and tilt of the holder 2 over the entire area of the holder 2 under the bar 7 without distortions.

- spring mechanisms in the composition of the springs 3 and the axles 4 ensure the fixation of the holder 2 in the working position.

The design of the mounting unit provides the possibility of mounting and dismounting the MIP at the installation site without significant preparatory and repair work, while the existing design of the mounting points on the coolant housing remains unchanged.

The dismantling and installation of the converter is carried out as accurately as possible with minimal time.

Claims (1)

A mounting assembly of a magnetic induction converter, comprising a housing, a holder for mounting a magnetic induction converter, a restrictive bar for fixing the course of movement of the holder, a spring mechanism for fixing the required position of the holder, pins for stopping and tilting the holder, characterized in that the pins and spring mechanism, made in the form the springs located on the axes are located on both sides of the transducer housing, and the shape of the holder is made in such a way that the lower part allows you to reliably to fix MIP on the heat carrier body, and the position of the upper part allows you to visually control the correct fixation of the magnetic induction converter.

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