RU27262U1 - DEVICE FOR REGULATING LIQUID FLOW CONSUMPTION IN THE PIPELINE - Google Patents

Description

DEVICE FOR REGULATING LIQUID FLOW

The utility model relates to control valves of large-diameter pipelines (DN over 400 mm) in the form of throttle control devices used in nuclear and thermal power plants to control the flow of flux carrier depending on the operating mode of the core of a nuclear reactor or boiler of a thermal power plant.

Known devices for regulating fluid flow in pipelines operate on the principle of throttling the flow by changing the flow area, for example, using control valves.

Control valves in energy pipelines are used in combination with gate valves, as control valves are not used as stop valves.

There are mainly two types of control valves: rotary butterfly valves in the form of a disk and spool structures, when the flow in the valve body is blocked by a fixed sleeve with windows, into which a rotary spool sleeve with the same windows is inserted. When the windows coincide, the maximum flow through them passes, and when the spool sleeve rotates by a predetermined angle, the windows on the fixed sleeve partially overlap, the flow is throttled and its flow rate changes.

IN THE PIPELINE

A control valve of the type of rotary damper in the form of a Du 400 disk is known (see the industry catalog "Power fittings for thermal power plants and nuclear power plants, Moscow, 1986, p. 190, Fig. 194). Valves of this type are very large bore holes, for example, butterfly valve DN 800 PT 96510-800. The main disadvantage of this type of valve is the large asymmetry of the flows that flow around the ajar damper on both sides. This asymmetric flow leads to vibration of the damper disk and ripple of the output stream.

This is manifested most intensively at small opening angles of the damper, which is necessary to isolate the pump unit from cavitation processes that occur in certain modes of the heat unit, requiring a small flow of coolant, for example, for the core of a nuclear reactor.

At any opening angles of the damper disk and correspondingly large values of the pressure drop, caditic phenomena occur that lead to erosion of the rotary damper, valve body and equipment located behind the valve, including pipe walls.

To extend the service life of the equipment in practice, erosion-resistant surfacing an disk of the damper, the body and the pipe surface of the equipment adjacent to the valve are used.

In addition, in valves with a rotary damper, vibration occurs, from which the bearings on which the damper rotates quickly fail.

All this together increases the operating cost of these types of throttle devices, especially on pipelines with a through section (DN) of more than 500 mm.

the pipeline (see the industry catalog “Power fittings for thermal power plants and nuclear power plants, Moscow, 1986, pp. 69-70, Fig. 61).

Flow control in this valve design is performed by throttling the flow through the windows of the fixed sleeve and through the windows of the rotatable spool sleeve. When the windows coincide, the flow rate is maximum, and when the spool is turned to the side of the position when the windows of the fixed sleeve begin to overlap, the flow rate decreases.

In those cases when, under the operating conditions of the reactor core, low flow rates are required, the windows in the fixed sleeve open at a small angle. With small openings of windows in a fixed sleeve with a spool sleeve and, accordingly, large pressure drops, cavitation processes occur both in the throttle itself and around it, which ultimately leads to various erosion damage to the internal surfaces of the housing and the spool system.

Cavitation of surfaces is caused not only by a small opening, but also by the fact that the axis of the fixed sleeve and the spool sleeve are perpendicular to the longitudinal axis of the valve body and pipeline.

Because of this, a high-speed coolant flow, entering the valve body, hits the wall of the fixed socket, passes through its windows, changing its direction by 90 ° twice. This also leads to conditions for the formation of cavitation processes and vibration.

Another disadvantage of slide-type throttles, in which the axis of the stationary sleeve with the slide sleeve is perpendicular to the axis of the housing and the pipeline, is the high hydraulic resistance that the MCP (main centrifugal pump) must overcome. For example, in the case of a boiling mode in the reactor core, the hydraulic resistance increases, so you have to minimize the hydraulic resistance of the inductor. This is possible only because

increase the dimensions of the fixed sleeve and the spool sleeve and their windows, and therefore the body, which increases the weight and cost of the valve.

The closest in the number of essential features that coincide with the claimed design is the throttle control valve according to the certificate for utility model No. 19605 "Throttle control valve for pipes of large diameter.

In the case of the throttle-control valve, as well as in the claimed design, devices are made that ensure the formation of two independent flows of fluid transported through the pipeline: one is unregulated, passing through the throttle located along the axis of the body and made in the form of a sleeve with a constant coefficient of hydraulic resistance, and the other in the form of an annular flow, coaxial with the first, which is regulated by a slide valve installed coaxially with the body and the pipeline. The annular flow is adjusted by turning the spool sleeve with the longitudinal windows relative to the longitudinal windows of the fixed spool sleeve.

The disadvantage of this design of the throttle valve is that its design is such that the adjustable part of the flow to be throttled is first assembled closer to the center of the valve body due to the confuser to enter the flow inlet to the spool device, and then through the windows of the movable part of the spool device goes to the periphery of the valve body, in the form of an annular flow. The location of the output annular flow along the wall of the valve body adversely affects the pipeline elements located behind the throttle-control valve, for example, a shut-off device, which, as a rule, is installed at a small distance behind the throttle device. Due to such a distribution of flows with large consumption and long-term operation.

dynamic destruction of parts lying in the path of this flow can occur.

The problem the utility model is aimed at is creating a device design for regulating fluid flow in a large-diameter pipeline (Dy over 400 mm), which would allow the adjustable part of the flow to pass through itself not to the periphery of the device body, but to its center, directly covering the flow coming out of an uncontrolled throttle located along the axis of the device in the form of a sleeve with constant hydraulic resistance.

The technical result obtained by the implementation of this utility model is to reduce the flow path passing through the control throttle, and at the same time reduce its compression ratio, which reduced the energy costs of pumping the flow through the throttle control valve. At the same time, the dynamic effect of the flow on the parts of the device and on the parts of the shutoff valves located behind it decreased, since the stream now exits the housing in its center.

Another technical result is a significant (over 30%) reduction in the weight of the device for regulating fluid flow in the pipeline, both by reducing the diameter of the regulating throttle, and due to the design of the device, in which there is no confuser.

The specified technical result is achieved by the fact that in the device for regulating the flow of fluid in the pipeline containing the housing and two throttle devices installed therein: an unregulated throttle in the form of a sleeve with a constant coefficient of hydraulic resistance along the axis of the body and a throttle that regulates the flow rate, consisting of a fixed sleeve with windows, located concentrically to the bush of an uncontrolled throttle, and a movable slide valve with windows, and also two annular channels, dressed on it.

designed to enter the flow into the regulating throttle and exit it;

an annular channel for entering the controlled flow into the control throttle is located outside the movable spool sleeve with windows, and a channel for flow output is located inside the stationary spool sleeve of the control throttle;

- In addition, one of the walls of the channel for the exit of flow from the control choke is formed by the outer wall of the uncontrolled choke.

- in addition, the movable spool sleeve is provided with a drive shaft mounted tangentially to the spool sleeve with the possibility of axial movement, while the working end of the shaft is connected to the spool sleeve using a link mechanism.

- in addition, a fork is made on the outer surface of the spool sleeve, in which, with the provision of movement, a “rocker mechanism stone is installed, in which the working end of the drive shaft is fixed with the possibility of rolling.

- In addition, a cone-shaped fairing is installed at the inlet of the fixed spool sleeve, the outer diameter of which coincides with the outer diameter of the movable spool sleeve of the regulating throttle, and the inner diameter of the fairing coincides with the outer diameter of the sleeve of the uncontrolled throttle.

The essence of the utility model is illustrated by drawings, where in FIG. 1 is a longitudinal section through a device for controlling fluid flow in a pipeline. In FIG. 2 is a view along line A. FIG. Figure 3 shows an enlarged fragment of a section along the BB in the case when the windows of the fixed spool sleeve are closed by the movable spool sleeve. In FIG. Figure 4 shows an enlarged fragment of a section along the BB in the case when the windows of the fixed spool sleeve are opened by the movable spool sleeve.

A device for controlling fluid flow in a pipeline is made in the form of: a housing 1, an unregulated throttle in the form of a sleeve 2 with a constant coefficient of hydraulic resistance, a regulating throttle 3, consisting of a fixed spool sleeve 4 with windows 5 and a movable spool sleeve 6 with windows 7 on it ; an annular channel 8 intended for flow inlet into the control throttle 3 formed by the inner wall of the housing 1 and the outer surface of the movable spool sleeve 6; an annular channel 9, designed to exit the flow from the control throttle 3, formed by the inner wall of the fixed spool sleeve 4 and the outer wall of the sleeve 2 of an uncontrolled throttle; a drive shaft 10 and a fork 11, made on the outer surface of the movable spool sleeve 6; "Stone 12 rocker mechanism; a drive nut 13 with a thread portion 14 on the drive shaft 10 and the front portion 15 and a fairing 16 directing the flow into the annular channel 8.

The design of the named device provides for the separation of a single stream going through the pipeline from the MCP into two p allelic flows converging at the outlet of the housing. The flow with a constant flow rate (with the regulator throttle open) is provided by a throttle in the form of a sleeve with transverse ribs installed along the axis of the device body, while the size of the sleeve and the flow through it are selected in such a way and with such hydraulic resistance that this throttle provides the lowest level coolant flow rate, required by the regulations, nanomer, when decommissioning the reactor. This low-flow mode in known chokes designs causes intense flow vibration and cavitation processes both inside the housing and at the outlet from it.

It also contributes to the fact that the throttle in the form of a sleeve 2 is installed but on the axis of the note, where the flow velocity is greatest, and in its movement the note does not encounter any obstacles, except for near-wall braking due to the transverse ribs mounted on the inner wall of the sleeve 2.

The second flow is formed by a regulating throttle 3, consisting of a fixed spool sleeve 4 with windows 5 and a movable spool sleeve b with windows 7, which leaves the annular channel 9 in the form of an annular flow covering the flow exiting the uncontrolled throttle 2.

When it is necessary to increase the flow rate according to the operating conditions of the thermal unit, then using the drive nut 13 and the drive shaft 10, turn the spool sleeve 6. This leads to a partial coincidence of the windows 7 on the movable sleeve 6 with the windows 5 on the stationary sleeve 4.

In FIG. 3 and FIG. 4 shows two extreme positions of the windows: in FIG. 3 shows flow shutoff through an adjustable throttle, and FIG. 4 shows the full opening of the windows, which, in combination with the unregulated throttle 2, maximize the flow rate of the liquid passing through the device.

The intermediate positions of the windows of the movable and fixed spool sleeves provide any desired flow rate through the inventive device.

The shape of the windows 5 and 7 in the form of longitudinal slots over their entire length forms a smooth flow of the stream from the input channel 8 into the cavity of the output channel 9.

The rotation of the spool sleeve by a predetermined amount of opening of the windows is carried out by the drive shaft 10 through a fork 11, made on the outer surface of the movable spool sleeve 6, and "stone 12 of the rocker mechanism.

The inventive device for controlling fluid flow in large pipelines, over 400 mm, has smaller dimensions, weight and manufacturing cost as well as lower operating costs compared with known structures of the same purpose. In this case, the greatest savings are obtained by reducing the diameter of the regulating throttle and the lack of overall confuser. So, for example, for a pipeline with a DN of 800 mm, according to the utility model certificate No. 19605, the weight of the device is 343 kg, and according to the claimed utility model, 219 kg.

Claims (5)

1. Device for regulating fluid flow in a pipeline, comprising a housing and two throttle devices installed in it: an unregulated throttle in the form of a sleeve with a constant coefficient of hydraulic resistance along the axis of the body and a throttle that regulates the flow rate, consisting of a fixed spool sleeve with windows located concentrically an unregulated throttle bushing, and a movable slide valve with windows mounted on it, as well as two annular channels intended for flow inlet to the control dross s and exit therefrom, characterized in that the annular channel for the entry into a regulated flow control throttle slide valve is disposed outside the movable sleeve with windows and exit flow passage is located inside a fixed bush with slide valve regulating throttle windows.  2. The device according to claim 1, characterized in that one of the walls of the channel for exiting the flow from the control choke is formed by the outer wall of the uncontrolled choke.  3. The device according to claim 1, characterized in that the movable spool sleeve is provided with a drive shaft mounted tangentially to the spool sleeve with the possibility of axial movement, while the working end of the shaft is connected to the spool sleeve using a rocker mechanism.  4. The device according to claims 1 and 3, characterized in that on the outer surface of the spool sleeve there is a fork in which, with the provision of movement, a "rock" of the rocker mechanism is installed, in which the working end of the drive shaft is fixed with a possibility of rolling. 5. The device according to paragraphs. 1-4, characterized in that at the input of the fixed spool sleeve there is a cone-shaped fairing, the outer diameter of which coincides with the outer diameter of the movable spool sleeve of the regulating throttle, and the inner diameter of the fairing coincides with the outer diameter of the bush of the uncontrolled throttle.