CS235422B1 - Gas-tight, pressure-resistant, automatic and manually operated closure for air and gas flow - Google Patents

Abstract

The above-mentioned task is solved by the fact that in the cylindrical closure, a control electromagnetic mechanism is mounted in the longitudinal axis, in principle an electromagnet with a return spring, with the output rod of which a pressure-resistant closing plate with a sealing ring on the contact piece, which rests on the cutting edge, is hingedly connected. The lifting of the closing plate is adjustable. Its end positions are signaled in such a way that the movement of the conically terminated electromagnet core, connected to the output rod, is transmitted perpendicularly to the axis mounted by the control rod to a switch, which is located on the outer wall of the closure. The control of the electromagnets is ensured by circuits outside the closure, which are said to be such that after the attraction of the electromagnet core - opening the closure - - they automatically reduce the current to a value ensuring the open position, which is then overcome by the effect of the pressure wave on the closing plate and the closure automatically closes with the cooperation of the return spring and does not open again.

Description

(54) Gas-tight, pressure-resistant, automatic and manually operated closure for air and gas flow

This object is achieved by providing a cylindrical closure in the longitudinal axis with an actuating electromagnetic mechanism, in principle an electromagnet with a return spring, with the output rod of which a pressure-resistant closing plate with a sealing ring on the contacting fruit which abuts the lip is articulated. The lift plate lift is adjustable. Its end positions are signaled in such a way that the movement of the conically terminated core of the electromagnets connected to the output rod is transmitted perpendicular to the axis by means of the actuating rod to the switch located on the outer wall of the closure.

Electromagnet control is provided by circuits outside the shutter, which means that when the solenoid core is energized - the shutter opens - automatically decreases the current to a value that ensures an open position, but surpasses the pressure wave effect on the shutter plate and automatically closes the shutter again .

FIG

The invention relates to a gas-tight, pressure-resistant, automatically and manually operated closure for the flow of air and gases.

The prior art shutters or valves, both remote and manually operated, have relatively high hydraulic losses due to lever mechanisms located inside the flow profile. The movements of such a lever mechanism and thus the shutter function are compromised by the dustiness and corrosion effect of the flowing medium. A further disadvantage of existing closures is the rigid connection of the closure plate and the shaft of the actuating mechanism, so that a constant specific pressure is not ensured over the entire contact sealing surface. The sealing material is embedded in the groove of the disc, so that it does not have the possibility of resilient expansion.

The stroke of the adjustable closing plate also affects the stroke of the electromagnet core and thus affects the required control current to the magnet coil.

The coil of the solenoid has dual windings, one of which acts as a power winding for attracting a high current core and the other acts as a holding winding to maintain the closure in an open state, the switching function of these windings being performed by a snap switch controlled by a rod passing through the center of the magnet. This arrangement is electrically unsuitable with respect to the switching of the current passing through the large inductive coil of the solenoid winding and also because the rod actuating the instantaneous switch contacts imparts an axial momentum to the impacting core of the magnet that threatens the instantaneous switch function.

The above-mentioned drawbacks are eliminated by a gas-tight, pressure-resistant, automatically and manually operated closure according to the invention, characterized in that the actuating electromagnetic mechanism is arranged in the cylindrical body by the closure coaxially and its output rod extending from its first end is the control electromagnetic mechanism, including its return spring, is separated from the flowing medium by a seal in a gas-tight and gas-tight manner.

In the case of the need for steering control, it is advantageous in that the actuating electromagnetic mechanism is coupled at its other end to a sliding shaft of the manual control connected to the cylindrical body, in which balls are displaceably disposed in the radial direction.

In this case too, it is advantageous if the sliding shaft is separated from the flowing medium by a dust-tight and gas-tight seal.

The closure plate is preferably convex and between the hinged joint and the closure plate there is arranged an adjusting mechanism for the closure plate lift, in the bearing surface of which a rebate is formed, in which a sealing ring is received.

It is also advantageous that the control electromagnetic mechanism is provided with a first yoke having a continuously weakened cross-section in the region of the core drawing, the core in its end position abutting a non-planar part of the yoke and the winding leads of the control electromagnetic mechanism pass through a gas-tight hollow spacer.

From the point of view of reliable signaling of the operating state, it is advantageous if a tapered start is formed on the core, on which the control rod coupled to the signaling switch bears radially.

For reliable operation, it is suitable if the winding is connected to the power supply via a lowering circuit connected to the delay circuit.

In all the above cases it is preferred that the hinge is spherical.

A new and higher effect of the invention is that the control electron is coaxially arranged. the magnetic mechanism causes considerably less hydraulic losses than the previously used lever mechanisms.

The actuating electromagnetic mechanism has a specially adapted iron yoke shape so that the traction force has a linear increment along the path corresponding to the linear characteristic of the return spring.

When the power supply is interrupted, the closure closes with a gas-tight return spring and remains closed until the power supply resumes, automatically opening again.

When the closure is closed by a pressure wave with an uninterrupted supply, the closure remains permanently closed until the power is switched off and on again.

Emergency manual opening and closing is independent of automatic control, but the pressure wave closes the cap. The closure plate is shaped to withstand the effects of a pressure wave.

The uniformity of the specific pressure distribution along the perimeter of the closing plate flange is ensured by an articulated joint with the actuating electromagnetic mechanism.

The adjuster connecting the articulated joint to the shut-off plate allows the stroke and thus the amount of flowing medium to be adjusted independently of the stroke of the actuating electromagnetic mechanism without affecting the flowing current into the solenoid coil.

The closing plate shafts as well as the manual shafts are provided with either rubber sealing rings or rubber caps firmly connected to both the shafts and the electromagnetic actuator housing, thereby ensuring complete dustproof, watertightness and gas tightness of the interior of the electromagnetic actuator and manual actuation. Firmly coupled rubber caps ensure an explosion-proof design.

The signaling position of the closure plate is derived from the movement of the tapered portion of the core of the actuating electromagnetic mechanism via a perpendicular to the axis of the actuating rod on the signaling switch located on the outer wall of the closure.

The closing of the closure by electric current is performed by external circuits with the possibility of further signaling of the current flowing into the actuating electromagnetic mechanism.

These circuits have the advantage of allowing the control electromagnetic mechanism to be supplied with a significantly higher current at the time of the downpressure than later during holding, which on the one hand increases the reliability of the pull and on the other .

The invention is further elucidated by means of an exemplary embodiment, which is described with reference to the drawings in FIG. 1 showing an overall embodiment of a gas-tight, pressure-resistant, automatically and manually operable closure according to the invention in cross-section; Fig. 2b is a block diagram of the electrical connection, in Fig. 3a a first variant of the electrical connection suitable for DC power supply; in Fig. 3b a second variant of the electrical connection suitable for the DC power supply;

The cylindrical body 1 of the closure is in FIG. 1 provided with connecting flanges for the respective pipe or wall. The control electromagnetic mechanism 2 comprises a return spring X which keeps the closure closed in the rest state.

The actuating electromagnetic mechanism 2 consists of a housing 4, and a core 2 firmly connected to the outlet rod 6, operating via the articulation 2 of the closing plate 8 with the sealing ring 22.

The magnetic flux excited by the electric current flowing through the coil 12j® is closed over the first yoke of the core 2 ® of the second yoke 10.

By adjusting the air gap between the first yoke 2 and the modified pole-shaped core 2, a linearly increasing tensile force is achieved over a large part of the core 2 path, which only increases substantially when the core 2 is fully retracted.

The lower part of the core 2 is provided with a tapered recess 27 for the slow movement of the control rod U acting on the contacts of the signaling switch 22, which is located in the terminal box 13 on the cylindrical body 1 and provided with a connector 14. mechanism 2,

The manual control consists of a sliding shaft 16 rigidly connected to the cylindrical body 12, in which balls 18 with a spring 12 are displaceable in the radial direction.

After power is applied to the coil 12, the core 2 is drawn into the first yoke 2, the overprinted return spring 2 is opened and the closure is opened. After the electric current has been interrupted, the return spring 2 closes the closure again.

In order to prevent the ingress of dust and moisture, the outlet rod 6 operating the closure plate 8 and the sliding shaft 16 of the manual control are provided with seals 20, 21, for example rubber rings or rubber caps. The manual handle 23 is connected to the sliding shaft 16, which can be of any length and can also be led out through a sealing bushing 24 located in the wall of the knee - shown in dashed lines in FIG. The signaling of the closed or open position is provided by switch contacts 12.

When the closure is opened, a reduced holding current e flows through the coil 15 and the closure plate 8 is in the open position. On the impact of a pressure wave with an overpressure of more than 50 kPa, the force caused by this overpressure on the surface of the closure plate 8 overcomes the holding force of the actuating mechanism 2, the return spring 2 closes the closure. The reopening can only be done by switching off the electric current with switch S - fig. 3 and switching it on again.

The closure plate 8 is connected to the hinge 2 by means of an adjusting device 25, which consists of a screw passing through the thread in the closure plate 8. Said screw is secured against the free rotation in the thread of the closure plate 8 by a counter-lock. It can be seen that by altering the screwing of the screw into the closing plate 8, the resting position of the core 2 inside the actuating electromagnetic mechanism is changed so that, for example, by unscrewing the screw from the thread in the closing plate 8 opening the closure when applying electrical current to the coil 15.

FIG. 1 shows a simple embodiment of a hinge 2, which is spherical. The hinged joint 2 allows the sealing disc 6 to fit tightly over the entire circumference of the cylinder body and the closure. The sealing ring 22 is also supported by a rebate 22 in the seating surface of the closure plate, which allows the sealing ring 22 to deform when clamped between the closure barrel 2 and the closure plate 8.

The entire actuating electromagnetic mechanism 2 is supported within the closure barrel 1 by, for example, three hollow spacers 28, one of which is also used for the passage of the actuating rod 11 and the electrical leads to the coil 15.

Fig. 2a shows a block diagram of the electrical connection of a gas-tight, pressure-resistant, automatically and manually operated closure according to the invention. The coil 15 of the control electromagnetic mechanism 2 of FIG. 1 is connected via a lowering circuit 29 to a power supply 41, for example a conventional AC or 24 V DC distribution. The lowering circuit 29 is connected to the delay circuit 60. The interplay of the operation of the lowering circuit 29 and the delaying circuit 30 achieves that, after switching on, the current necessary for pulling in the core 6 is introduced into the coil 15, which after a certain time given by the delaying circuit 30 The core position signaling block 32 is connected to the power supply 41 for a longer period of time and is shown in the manner shown with the switch 12 of FIGS. 1 and 3.

Fig. 2b shows a block diagram corresponding to Fig. 2a, except that in addition to the core position signaling block 32, a working current signaling block 33 through the coil 15 is connected to the lowering circuit 29.

The first variant of the specific embodiment of FIG. 3a consists of the capacitor _C1 being charged via the resistor of the DC voltage source to the full value U. Upon closing of the switch S flows through the coil 15 initially large current, which, after the time necessary for reliably opening the seal decreases to a value much smaller and keeps the cap open.

In the variant according to FIG. 3b, after the switch S is closed, the full current flows into the coil 15 through the contacts of the relay A. At the same time, a capacitor C ₂ , to which the coil of the relay A is connected, is charged via a resistor Rj.

Pa for some time *, relay A pulls the armature and opens contact tp, thus ae de series

a. coil 15 o <por R _{2 of} ^{<i T} coil 15 drops. Instead of the resistor R ₂ can be employed a suitable bulb, which then for the duration of current flow performs signaling current flowing into the closure.

In the variant according to Fig. 3c, which is intended for operation with alternating voltage, for example 220 V, 50 Hz, switch S is connected to transformer Tr and time delayed relay B. Contact b, relay B conducts current from higher-voltage transformer tap 5 through diode 6 into the coil 15 and the capacitor C1. After delaying the armature of relay B with contact b, the branch is disconnected and branch 2 with a lower voltage is connected. At the time the contact b is switched, relay B supplies the coil 8 with the capacitor C1.

The closure according to the invention can be used in all plants where it is necessary to gas-tightly separate two spaces with different pressure drops, and the medium flowing through the closure can be explosion-free with and without the signaling on the closure. The closure can be used as a protection against the penetration of pressure waves, both from one space to the other, and when two closures are connected on both sides.

In general, the closure in the chemical industry can also be used to protect both stable and mobile devices and the like.

Claims (8)

OF THE INVENTION 1. A gas-tight, pressure-resistant, automatically 1 ruined closure for air and gas flow, consisting of a cylindrical body of a closure provided with flanges and having a closing plate coupled to an electromagnetic actuating mechanism for automatic and manual actuation which is further coupled with a shutter transfer status indicator, characterized in that the actuating electromagnetic mechanism (2) is disposed coaxially in the shutter barrel (1) and its outlet rod (6) extending from its first end is connected to the shut-off plate by a hinged link (7) (8), wherein the actuating electromagnetic mechanism including its return spring (3) is dust-tightly separated from the flowing medium by a seal (20, 21). The gas-tight, pressure-resistant, automatically and ruined closure according to claim 1, characterized in that the actuating electromagnetic mechanism (2) is coupled at its other end to a hand shaft (16) connected to the cylindrical body (17). in which balls (18) are displaceably mounted in the radial direction, between which a spring (19) is arranged. Gas-tight, pressure-resistant, automatically and manually operated closure according to claim 2, characterized in that the sliding shaft (16) is separated from the flowing medium by a dust-tight and gas-tight seal (20, 21). Gas-tight, pressure-resistant, automatically operated closure according to claim 1, characterized in that the closure plate (8) is convex and a closing mechanism (25) of the closure stroke (25) is arranged between the hinge (7) and the closure plate (8). a plate (8), in which the pelvis groove (26) is formed, in which the sealing ring (22) is located. Gas-tight, pressure-resistant, automatically and manually operated closure according to claim 1, characterized in that the actuating electromagnetic mechanism (2) is provided with a first yoke (9) which has a continuously thinned cross-section, core (5). 5) in its end position the skin abuts against the planar part of the first yoke (9) and the winding outlets (15) of the actuating electromagnetic mechanism (2) pass through a gas-tight hollow spacer (28). 6. A gas-tight, pressure-resistant, automatically and manually operated closure according to claim 5, characterized in that a tapered run (27) is formed on the core (5) on which the control rod (11) coupled to the signaling switch (12) bears. . Gas-tight, pressure-resistant, automatically and manually operated closure according to run 5, characterized in that the winding (15) is connected to the power supply (31) via a reduction circuit (29) connected to the delay circuit (30). Gas-tight, pressure-resistant, automatically and manually operated closure according to run 1, characterized in that the articulated joint (7) is spherical.