RU44364U1 - ELECTROMAGNETIC VALVE OF INDIRECT ACTION - Google Patents

Abstract

The utility model relates to the field of instrumentation and can be used as an on-off executive device with remote electric control on large diameter pipelines (up to 100 mm) for automatic control of liquid and gaseous media flows. The goal is to reduce energy consumption and overall dimensions, increase reliability and expand the scope. The solenoid valve of indirect action contains an actuator having an input and output channels separated by a saddle, with which the main valve, fixed by a feedback spring, fixed on a diaphragm forming a control chamber connected to the input channel through a feed hole on the diaphragm, and an electromagnetic unit having an inductor, a housing with coaxially fixed cores located therein, arcuate permanent magnets with diametrically magnetized em, creating a magnetic flux acting on the movable armature located in the housing, and the core located on the side of the actuator has an unloading channel that opens or closes with an anchor that can axially move between the cores depending on the change in the magnetic flux, and the outlet channel, respectively connecting an anchor chamber of an electromagnetic unit with a control chamber and an output channel of the actuator.

Description

The utility model relates to the field of instrumentation and can be used as an on-off executive device with remote electric control on large diameter pipelines (up to 100 mm) for automatic control of liquid and gaseous media flows.

Known servo valve for application No. 3929551, Germany, publication of March 7, 1991, and an auxiliary two-channel solenoid valve for application No. 63-35878, Japan, publication of July 18, 1988.

The servo valve, operating from its own medium and controlled by a magnetic core, according to the application No. 3929551 contains a housing, inside of which there is a differential piston carrying a valve disc. On the one side of the piston there is a pressure chamber connected to the inlet of the servo valve, and on the other side of the piston there is a control chamber that is connected through the discharge hole in the center of the piston to the output of the servo valve and through its eccentric control hole with its pressure chamber. An elastic element in the form of a membrane isolates the pressure chamber from the control chamber. In the absence of voltage on the inductor, the discharge opening in the center of the piston is closed by means of a seal on the magnetic core, which moves to the lower position under the action of the spring force. When voltage is applied to the inductor, the magnetic core moves to the upper position, overcoming the force of the spring, and opens the discharge hole in the center of the piston. As a result, the pressure in the control chamber drops sharply and the valve opens under the action of the inlet pressure in the pressure chamber.

The auxiliary two-channel solenoid valve according to the application No. 63-35878 contains a housing with inlet and outlet channels, inside of which a main valve is installed. A working pressure chamber (control chamber) is formed on the back of the valve, which is connected through openings to the inlet and outlet channels. The hole connecting the working pressure chamber to the output channel opens and closes the control valve element, moved by the movable core of the electromagnetic unit. The electromagnetic valve is characterized in that the control valve element is provided with an additional spring for hermetic locking in the absence of voltage on the inductor. When voltage is applied to the inductor, the magnetic core moves to the upper position, overcoming the force of the springs, and specially provided

protrusion moves the control valve element, venting pressure from the working chamber.

A common drawback of these solenoid valves is the high power consumption due to the fact that in the working position both valves are constantly energized.

Closest to the proposed utility model are a gas-assisted gas valve according to the application No. 63-4073, Japan, publication 01/27/88, and electric bistable controlled with open / closed positions for liquids according to the application No. 0356536, ЕВП, publication 07.03.90 , as well as an electromagnetic valve according to the application No. 2004114181/22 (015591), Russia, priority dated 05/12/2004, the decision to grant a patent on 06/01/2004

The gas servo-controlled valve according to the application No. 63-4073 contains an electromagnetic unit connected to a housing having an inlet and outlet chamber. Inside the body there is a main diaphragm kinematically connected to the main valve, and a feedback diaphragm, on the opposite surfaces of which a servo valve and a permanent magnet are fixed, respectively. When voltage is applied to the inductor, the magnet is attracted to the fixed core of the inductor under the action of electromagnetic force, while moving the feedback diaphragm and a servo valve mounted on it, which changes the cross-sectional area of the hole through which pressure from the outlet chamber is supplied through the distribution valve to the main diaphragm. The main diaphragm through the pusher acts on the main valve, changing its position relative to the seat. The disadvantage of the design of the gas servo-controlled valve is the low reliability due to the presence of two diaphragms (main and feedback) and three valves (main, distribution and servo valve), as well as large dimensions and weight.

Controlled by electric pulses, a bistable with open / closed positions for liquids according to application No. 0356536 contains an electromagnetic unit connected to a housing having an input, output and control chamber. The control chamber is separated from the inlet chamber by an elastic membrane mechanically connected on one side to the electromagnet armature and, on the other hand, to the valve flap. The control chamber and the inlet chamber are connected by a pressure equalization channel. The electromagnetic valve block has a U-shaped core with two inductors, while the poles of the core and the movable armature interacting with them are placed in the control chamber. The disadvantage of the valve design is the large dimensions and weight due to the presence of two inductors, as well as the high complexity of manufacturing the valve as a whole.

The electromagnetic valve according to the application No. 2004114181/22 (015591) comprises a housing in which cores are coaxially fixed on both sides, one of which has an input and an output channel, and the other only an output channel. An anchor is placed inside the housing coaxially to the cores, which serves as a two-way shut-off valve with the possibility of axial movement. The anchor has the shape of a cylinder with spherical bases, on the side surface of which faces are made for the passage of the working medium. An inductor is fixed to the outer surface of the housing. Between the inductor and the casing symmetrically installed arc-shaped permanent magnets with diametrical magnetization (magnets type MDD according to GOST 24936-89). To exclude mutual attraction, the permanent magnets are separated by stops in the form of half rings. The design feature of this electromagnetic valve is low power consumption and increased reliability due to the use of arc-shaped permanent magnets with diametrical magnetization in the design. The disadvantage is the limited scope, since the electromagnetic valve can be installed on the pipeline with a nominal diameter of no more than 10 mm.

The technical task of the proposed utility model is to reduce power consumption and overall dimensions, increase reliability by reducing the number of assembly units and expand the scope - the design of the proposed electromagnetic valve of indirect action allows automatic regulation of the flow of liquid and gaseous media in large pipelines (with nominal diameter up to 100 mm).

This goal is achieved due to the fact that the solenoid valve of indirect action contains an actuator having an input and output channels separated by a saddle, with which the main valve, fixed on a diaphragm forming a control chamber connected to the input channel, coaxially interacts with the feedback spring a loading hole on the diaphragm, and an electromagnetic unit having an inductor, a housing with coaxially fixed cores located therein, arcuate stationary magnets with diametral magnetization, creating a magnetic flux acting on the movable armature located in the housing, and the core located on the side of the actuator has an unloading channel that opens or closes with an armature that can axially move between the cores depending on the change in magnetic flux, and the outlet a channel respectively connecting the chamber of the armature of the electromagnetic unit with the control chamber and the output channel of the actuator.

The drawing shows a diagram of an electromagnetic valve of indirect action.

The solenoid valve of indirect action contains an actuator 1 having an input channel 2 and an output channel 3, and an electromagnetic unit 4. Inside the actuator 1 there is a main valve 5 mounted on the diaphragm 6 and constantly pressed by the feedback spring 7 to the seat 8 separating the channels 2 and 3. The diaphragm 6 has a loading hole 9 connecting the input channel 2 to the control chamber 10. The electromagnetic unit 4 includes a housing 11 made of non-magnetic material. In the housing 11c of the two sides, fixed cores 12 and 13 are coaxially arranged, made of soft magnetic material. In this case, the core 12 has an unloading channel 14 and an outlet channel 15 connecting the chamber of the armature 16 of the electromagnetic unit 4 with the control chamber 10 and with the output channel 3 of the actuator 1, respectively. Anchor 17 is placed coaxially with cores 12 and 13 and serves as a one-way shut-off valve that blocks the discharge channel 14. An inductor 18 is fixed on the outer surface of the housing 11. Between the inductance 18 and the housing 11 there are symmetrically arched permanent magnets 19 with diametrical magnetization (type DMD GOST 24936-89).

An indirect solenoid valve works in conjunction with an energy-saving control unit (ECU) according to the patent of the Russian Federation No. 37174 for a utility model (priority 08.12.2003), which, depending on the position of the contact of the monitoring sensor D _to , which senses any physical quantity, generates pulses negative or positive polarity and transfers them to the inductor 18 of the electromagnetic unit 4, causing a change in the direction of the magnetic flux.

In the initial state, in the absence of a working current in the inductor 18, the permanent magnets 19 create a magnetic flux that, passing through the armature 17, branches into two parts: the magnetic flux Ф ₁ passing in the gap u ₁ , and the magnetic flux Ф ₂ , which passes into clearance u ₂ . These magnetic fluxes (f ₁ and f ₂ ) create traction forces acting on the anchor 17 and directed in opposite directions. Under the influence of traction, the armature 17 is attracted, for example, to the core 12, blocking the discharge channel 14. In this case, the magnetic flux Ф ₁ , closing through the poles of the permanent magnets 19, the armature 17 and the core 12, reliably fixes the position of the armature 17 relative to the core 12. In neutral position (i.e., with u ₁ = u ₂ ), the armature 17 practically does not stop due to the instability of this position, since the slightest asymmetry or a negligible external force leads the armature 17 out of mid-position. The main valve 5 under the influence of its own weight and the efforts of the feedback spring 7 blocks the passage in the seat 8. The working medium under pressure from the inlet

channel 2 (high pressure cavity) through the feed hole 9 in the diaphragm 6 enters the control chamber 10, creating a contact pressure of the main valve 5 on the sealing surface of the seat 8. Closing the flow of the working medium through the actuator 1.

When the energy-saving control unit (ECU) is connected to the network, depending on the position of the switching contact of the monitoring sensor D _k , a pulse of negative (or positive) polarity is generated, which lasts for several half-periods of the mains voltage and creates a short-term (control) magnetic in the inductor 18 the flow f _y passing sequentially through the gaps u ₁ and u ₂ . If the anchor 17 is located at the core 12, then in the gap u ₁ , the resulting magnetic flux Ф _p1 = Ф _1- Ф _у will act, and in the gap the magnetic flux Ф _p2 = Ф ₂ + Ф _у Therefore, the attractive force due to magnetic the flux Ф _p2 , there will be more force created by the magnetic flux Ф _p1 , and the armature 17 will move to the core 13, opening the discharge channel 14. As a result, the control chamber 10 through the chamber of the armature 16 and the outlet channel 15 is in communication with the output channel 3 (low cavity pressure). Since the area of the orifice of the opening of the discharge channel 14, overlapped by the anchor 17, is larger than the area of the loading hole 9, the filling of the control chamber 10 is much slower than the emptying, as a result of which the pressure drops. The diaphragm 6, under the influence of the pressure differential, bends upward, raising the main valve 5 and opening the passage in the seat 8. The flow of the working medium through the actuator 1 is opened. The electrical circuit of the energy-saving control unit (ECU) is de-energized until the next change in the state of the contacts of the monitoring sensor D _k . At this time, the position of the armature 17 relative to the core 13 will be fixed by magnetic flux f ₂ .

When the position of the contacts of the monitoring sensor D _k changes, the energy-saving control unit (ECU) is recharged with half-waves of voltage of a different polarity, as a result of which the direction of the current in the inductor 18 changes and, therefore, the direction of the (control) magnetic flux Ф _у changes, causing the armature 17 to move along main axis in the opposite direction.

The proposed utility model can significantly reduce energy consumption and weight and size characteristics, as well as increase the reliability of an indirect solenoid valve by efficiently using permanent magnets and reducing the number of assembly units that make up the product.

Claims (1)

An indirect solenoid valve containing an actuator having an input and output channels separated by a seat, with which the main valve is constantly coaxial with the feedback spring, mounted on a diaphragm forming a control chamber connected to the input channel through a feed hole on the diaphragm, and an electromagnetic a block having an inductor, a housing with coaxially fixed cores located therein, arcuate permanent magnets with diametrically magnetized creating a magnetic flux acting on a movable armature located in the housing, characterized in that the core located on the side of the actuator has an unloading channel that opens or closes with an armature that can axially move between the cores depending on the change in the magnetic flux, and the outlet channel respectively connecting the chamber of the armature of the electromagnetic unit with the control chamber and the output channel of the actuator.