CS220356B1 - Flexible Delay Proximity Magnetic Transmitter - Google Patents

Abstract

Flexible delay-free magnetic position transducer based on the principle of a system of at least two permanent magnets oriented in the same direction. It consists of a guide tube in the lid of which a magnetic relay is attached and in which at least two permanent magnets move, one of which is equipped with a sealing washer that closes the nozzle of the regulating pneumatic system.

Description

The present invention relates to a resilient, delayed, non-contacting magnetic position transducer, wherein motion and resilient directive torque are generated by two mutually repelling magnetic fields.

In operation, a number of different level sensors and the like are used, based on different principles, such as a magnetic relay, a mercury switch, mechanical devices and others. Particularly specific conditions are for transmissions from enclosed and pressure areas in a corrosive environment. This, in most cases, is carried out by means of magnetic couplings.

The disadvantage of various switching devices is that only a short-term switching pulse is obtained, which is not suitable for control purposes, where the constant switching on and off causes the control system to oscillate and thus a considerable wear on the control elements and devices.

According to the invention, the flexible, permanent contact non-contacting magnetic transducer of the permanent magnet principle, consisting of a guide tube and a magnet assembly, consists in attaching a magnetic relay in the guide tube cover in which at least two correspondingly oriented permanent magnets are located. The switching permanent magnet is provided with a sealing washer for closing the nozzle of the control, pneumatic system.

The essence of the flexible deceleration magnetic transducer is a permanent magnet mounted on a vertically moving part of the control element. Above this, the second permanent magnet is loosely mounted in the guide tube. The magnets are oriented with their magnetic fields so that they repel each other. As the magnets come under the influence of the control element, they are repelled from each other and the free-standing magnet rises upwards, where it engages the contacts of the magnetic relay in the final position or closes the control nozzle of the pneumatic regulator. When the magnet drops on the regulating element, the magnetic field is weakened, the loosely placed working magnet drops with its weight downwards and the regulating elements are disconnected.

Since the magnets are still moving at a certain distance from each other due to the magnetic field, the control magnet can, due to the inertia of the control system, further approach the switching magnet which is already in the end position and has switched on the control device. As a result, the magnetic fields are amplified and this excess becomes delayed when the control magnet drops before the magnetic field reaches its original value and the switching magnet drops under its weight and opens the control circuit.

By this arrangement, periodic switching on and off around the control value is eliminated, and the switch-off occurs only when the control value has a continuous decreasing value. and

The effect of the invention is manifested in simplicity of design and operational reliability, since there are no mechanical spring transmissions and other mechanisms where the position transmission is constituted by a loosely mounted magnet controlled by a magnetic field in an enclosed space.

The transducer can be used in conjunction with a float level gauge, pressure regulator, vacuum, and anywhere the result is a change in position. It is suitable for closed and pressure equipment as well as for potentially explosive atmospheres.

The drawing shows a diagram of a flexible delay magnetic transducer with an example of use with a float level gauge. A permanent magnet 3 is attached to the float 1 and a second permanent magnet 5 with a sealing washer 6 is loosely mounted in the guide tube 4. As the float 1 rises, the magnet 3 approaches the magnet 5, which is repelled by the magnetic field and rises in the guide tube. up. At the end of the guide tube 4, a magnetic relay 8 is mounted in the cap 9, which closes or closes the nozzle 7 of the pneumatic control system when the magnet 5 approaches. Due to the compressible magnetic field, the inertia float can still rise upwards, creating a certain excess direct pressure force.

In the case of a short-term low drop of the float 1 with the magnet 3 or a fluctuation of the level around the controlled value, the magnet 5 remains in the upper position due to the excess magnetic force and the control circuit is switched on. The control circuit is switched off when the control value has a continuous decreasing tendency, the excess magnetic field strength is exhausted and the magnet 5 decreases by its weight. This delay has a positive effect on control, where in conventional two-position control systems the control system oscillates around the control value and thus excessive wear of the control elements.

Several magnets can be used to extend the working height of the sensors.

Claims (1)

Subject Flexible permanent contact non-contact magnetic transducer consisting of a guide tube and a set of magnets, characterized in that in the cover (9) of the guide tube (4) in which at least two consecutively oriented inventions of permanent magnets (3, 5) are freely located a magnetic relay (8) is mounted, the switching permanent magnet (5) being provided with a sealing washer (6J) for closing the nozzle (7j) of the control pneumatic system.