EA046144B1 - ELECTROMAGNETIC INDUCTION MODULATOR - Google Patents

Description

The invention relates to the field of hydraulic engineering and can be used as a water hammer modulator in electrical engineering to create electromagnetic induction and can be used in other devices that use modulation of electrical signals.

A water hammer modulator is known (patent KG No. 2331, C1, 03/31/2023, class F04F 7/02, (2023.01)), containing a shock pipeline connected to the tank with a valve, one end of which is connected to the tank, a housing connected to the second end shock pipeline, and a valve chamber installed in its middle part, which has a discharge hole in its upper part, an impact valve installed in the cavity of the valve chamber under the discharge hole, and the valve has a central air outlet pipe with a tap installed in the guides, a discharge chamber installed on valve chamber, a discharge pipe with a valve, connected at one end to the discharge chamber, and the other end is installed outside the device, and also has an inlet pipe with a valve, an air pipe with a valve and a drain valve. In addition, the device contains one, two or more magnets installed on the discharge chamber, and a metal disk installed on the central air outlet pipe in order to be in contact with the magnets, and may also contain one, two or more electromagnets.

The disadvantage of the device is its limited scope of application.

The objective of the invention is to expand the scope of application of the device.

This task is achieved by the fact that an electromagnetic induction modulator containing a pressure tank, a shock pipeline connected to the pressure tank, an air valve, a magnet and a metal plate, while the pressure tank has a liquid inlet pipe having a valve, as well as a liquid discharge valve and connected to pressure tank, a guide pipe, a shock pipe installed in the guide pipe, a shock plate of a plug attached to the top of the shock pipe, having a tap, and a gas supply pipe with a tap connected to the pressure tank, a fastening element and a metal plate attached to the fastening element, the device also contains a main plate to which a magnet is attached, loop magnets and one, two or more induction coils. In addition, the device may contain one, two or more electromagnetic induction modulators, one, two or more electronic devices with a contact key, as well as one, two or more electronic devices with a contact button and one, two or more contact rods. It may also contain a ballast weight and a rod attached to the main plate, to the lower end of which is attached an internal disk having a calibrated hole and a container in which the internal disk is installed, as well as one, two or more loop electromagnets.

The electromagnetic induction modulator, as well as its operation, are shown in the diagrams:

in fig. Figure 1 shows the electromagnetic induction modulator in plan;

in fig. 2 - side view of the device (view A);

in fig. 3-32 shows diagrams explaining the operation of the device in a longitudinal section B-B, as well as possible design options.

The electromagnetic induction modulator (Fig. 1, 2, 3) contains a shock tube 1 installed in the LT guide pipe, which has a plug shock plate 2 with an air valve 3 in the upper part, and the lower end of the shock pipeline is connected to a pressure tank 4. The device also contains a rigid a fastening element 5 installed in the upper part of the shock pipeline 1 and a metal plate 6 attached to it, as well as a rigidly installed main plate 7 and a magnet 8 attached to its upper plane. In this case, the pressure tank 4 contains a gas pressure sensor 9, a liquid discharge valve 10, a liquid inlet pipe 11 having a valve 12, a gas supply pipe 13 with a valve 14 and a gas pressure switch 15. In addition, the device contains loop magnets 16 and an induction coil 17, and may also contain a loop electromagnet 18, an electronic device 19 with a contact key 20 and an electronic device 21 with a contact button 22, as well as a contact rod 23, a proximity switch 24 and a ballast weight 25. In addition, the modulator may contain a device for damping the magnitude of the ultimate impact force, having a rod 26 attached to the main plate 7, to the lower end of which is attached internal disk 27, having a calibrated hole 28 and a capacity 29.

Accepted conventions for text and diagrams:

H - mark of the design pressure in the system;

NOT - design filling mark in pressure tank 4;

S is the distance from the lower end of the guide pipe to the water level in pressure tank 4 (Fig. 3);

(0-0) - plane of the inlet of shock tube 1;

P is the force of water pressure on the lower surface of the impact plate 2;

R _M is the force of magnetization of the plate 6 by magnet 8;

U is the electrical voltage in the induction coil 17;

I - electric current in the induction coil 17;

V is the speed of the water flow in the shock tube;

C is the speed of the shock wave;

- 1 046144 (+,+) - high pressure wave;

(-,-) - low pressure wave;

(B-B) - restoring pressure wave.

The device operates as follows (Fig. 1-28).

We will assume that the cavity of the device is filled with liquid (Fig. 1-28), the filling in the pressure tank 4 is at the design filling level NOT and the entire system is under constant design air pressure coming from the pneumatic line through the gas supply pipe 13 with valve 14, providing calculated water pressure at mark H during control operation of gas pressure sensor 9, which also performs the functions of relieving excess pressure.

To turn on the device, we will begin to supply gas under pressure into pressure tank 4, as a result of which the pressure P in the tank will increase. In this case, the magnet 8, by magnetizing the metal plate 6 with a force P _M exceeding the current pressure force P acting on the shock plate of the plug 2, will hold the shock tube 1 in a static position (Fig. 4). When the water pressure force P exceeds the force P _M , which can be expressed by the inequality P>P _M , the metal plate 6 will be separated from the magnet 8 and the shock tube 1, together with the contour magnets 16 and the volume of water enclosed in the cavity of the pipe, will occur under the influence of pressure in the pressure container 4 will begin to move upward at speed V (Fig. 5). In this case, due to the resulting movement of the contour magnets 16 relative to the induction coil 17, alternating electrical induction voltage U and current I will arise in the induction coil. When the shock tube 1 reaches the main plate 7 and when the shock plate touches the plug 2, the shock tube 1 will immediately stop, which is what happens here will lead to the occurrence of a hydraulic shock and the resulting high pressure wave (+,+) (Fig. 6) will rush to the inlet section (0, 0) of the shock pipe 1. In this case, both the electromagnetic induction voltage U and the current I will begin to fade.

Since water hammer is a combination of the movement and transformation of various waves and, in fact, only some of its key moments are of interest, we will discard the moments of formation and movement of restoring pressure waves (BP).

When a low pressure wave (-,-) (Fig. 7) is formed under the influence of atmospheric pressure and gravity, the shock tube 1 will begin to quickly descend to its lowest position, and due to the newly emerged movement of the contour magnets 16 relative to the induction coil 17, the induction coil will again appear alternating electrical induction voltage U and current I. When the plate 6 reaches the magnetic field of the magnet 8, the plate will again be rigidly magnetized by it (Fig. 8) by force Р _М. In this case, both the electromagnetic induction voltage U and the current I will fade away. At the same time, the low pressure wave (-,-), having reached the plane (0-0) of the inlet of the shock tube 1, is converted into a restoring pressure wave (B-B) (Fig. 9), which will immediately begin to move in the shock cavity pipe 1 in the direction of the impact plate of the plug 2 and when the wave (B-B) reaches and touches its lower plane (Fig. 10), a pressure force (Fig. 4) of water P will again arise, the value of which will exceed the magnetization force P _M of the plate 6 by the magnet 8 i.e. the inequality P>P _M will again arise and, as a result of the above, the metal plate 6 will again be separated from the magnet 8 and the shock tube 1, together with the contour magnets 16 and the volume of water enclosed in the cavity of the pipe, under the influence of pressure forces in the pressure tank 4 will begin to move at a speed V upward (Fig. 5) and due to the newly emerged movement of the contour magnets 16 relative to the induction coil 17, alternating electrical induction voltage U and current I will appear in the induction coil. As can be seen from the above, the above process occurs again and this process will be repeated again and again.

In all embodiments of the device, the distance from the lower end of the guide pipe to the water level in the pressure tank 4 must be no less than the calculated value S (Fig. 3).

The number and power of loop magnets 16 is determined by joint calculation with the induction coil 17, while the magnets are rigidly attached to the outer contour of the shock tube 1, which ensures their joint movement during operation of the device.

The device offers various design options depending on the application conditions and customer needs. In particular, it is possible to replace the loop magnets 16 with a loop electromagnet 20 (Fig. 11), made in the form of a coil with a calculated number of turns on the outer contour of the shock tube 1. In this case, the number of loop electromagnets 20 can be one, two or more (Fig. 12 ), and also a mixed use of loop magnets 16 and loop electromagnets 20 is possible (Fig. 13).

It is also possible to use two or more induction coils 17 in the design of the device (Fig. 14). In addition, magnet 8 can be replaced by an electromagnet 18 (Fig. 15), which is controlled by an electronic device 19 having a contact key 20. It is also possible to use magnet 8 and electromagnet 18 together (Fig. 16). In this case, the number of magnets 8 and electromagnets 18 can be one, two or more of each of the given names, which is determined by calculations.

The joint operation of two or more electromagnetic induction modulators is also possible (Fig. 17-24). Let's consider this using the example of the joint operation of two modulators MPEI 1 and MPEI 2. In this case

- 2 046144 the device operates as follows in the presence of voltage at the terminals of the device, in which the electronic device 19 on the MGU 1, operating according to a given program, is turned on and the contact key 20 is in the closed position (Fig. 17), maintaining the electromagnet 18 in the on state, thereby magnetizing metal plate 6. When you turn off the electronic device 19, the contact key 20 will open and the electromagnet 18 on the MGU 1 will turn off, as a result of which the magnetic field will disappear and the metal plate 6 will be released and the shock tube 1, under the influence of pressure in the pressure tank 4, will begin to quickly move to the top and When the shock plate reaches the plug 2 of the main plate 7 and touches its rigid bottom plane, the shock tube 1 will immediately stop and a hydraulic shock will occur (+,+) (Fig. 18). At the same time, the contact rod 23 moved by the shock tube 1, having reached the contact button 22 on the electronic device 21, will open it and turn off the electromagnet 18 on the MGU 2, which will also lead to the shutdown of the magnetic field, the release of the metal plate 6, and movement under the influence of pressure in the pressure container 4 of the shock pipe 1 in the upward direction at the MGU 2 and when the shock plate reaches the plug 2 of the main plate 7, the shock pipe 1 will immediately stop again and a hydraulic shock (+,+) will occur (Fig. 18, 19). In this considered option, when setting up a system consisting of MGU 1 and MGU 2, you can set the alternation of the operation of these devices, which is clearly demonstrated by the diagrams and description of the operation.

The proposed device can also use a contactless switch 24 (Fig. 20-22). The choice when designing a contactless switch must be made based on the type of design element of the device acting on the sensitive element of the contactless switch 24, and in our case, for example, we will consider a contactless capacitive switch which in the initial position, in the absence of external influence, is in the on state (ON) (Fig. 20), see MPEI 1. When you turn off the electronic device 20, the contact key 19 will open and the electromagnet 18 on MPEI 1 will turn off, as a result of which the magnetic field will disappear and the metal plate 6 will be released and the shock tube 1 will begin quickly under the influence of pressure in the pressure tank 4 move upward and upon reaching the shock plate of the plug 2 of the main plate 7 and touching its rigid bottom plane, the shock tube 1 will immediately stop and a hydraulic shock will occur (+,+) (Fig. 21). At the same time, the final element of the device, moved by the shock tube 1, in our case it is the fastening element 5 on MEI 1, will reach with its upper edge the sensitivity zone of the contactless switch 24 and the contactless switch will turn off (OFF), thereby turning off the electromagnet 18 on MEI 2, as a result of which the disappearance will occur magnetic field and the release of the metal plate 6 on MPEI 2 and the shock tube 1, under the influence of pressure in the pressure tank 4, will begin to quickly move upward and upon reaching the shock plate of the plug 2 of the main plate 7 and touching its rigid lower plane, the shock tube 1 will instantly stop and the occurrence of water hammer (+,+) (Fig. 22). In this considered option, when setting up a system consisting of MEI 1 and MEI 2, it is possible to establish an alternation of water hammer waves, which is clearly demonstrated by the given diagrams and description of the work. In this case, it is possible to use contactless switches 24 operating under other physical influences.

We have discussed above the system operation of a device consisting of two water hammer modulators from MPEI 1 and MPEI 2. But the proposed device can also be used in the presence of three or more water hammer modulators; for this it is enough to install an electronic device 21 with a contact button on MPEI 2 22, as well as contact rod 23 (Fig. 23) and connect the next water hammer modulator MEI 3 (Fig. 24), etc. If necessary, the above can be closed to MEI 1 and obtain closed operation of the device complex.

The proposed device uses a gas pressure sensor 9 and a pressure switch 15, which in the electronic version can, in order to maintain the design pressure in the pressure tank 4, control the operation of a compressor or liquid pump connected to the gas supply pipe 13 or inlet pipe 11.

The device may also contain a ballast weight 25 (Fig. 25, 26), which is designed to equalize the existing loads, thereby ensuring that the system is within the design parameters.

In addition, the modulator may contain a device for damping the magnitude of the ultimate impact force (Fig. 27, 28), which consists of a rod 26 attached to the main plate 7, to the lower end of which an internal disk 27 is attached, having a calibrated hole 28 and a container 29. In this case, the internal the disk 27 is installed in the cavity of the container 29 from the condition of free sliding in it and dividing the cavity into two parts, lower and upper, connected to each other by a calibrated hole 28. When the shock tube 1 reaches the container 29 with the shock plate plug 2 touching the lower plane of the container 29, the blow will be taken towards itself with the container and, under the influence of the resulting impact force, it will begin to move upward, thereby reducing the magnitude of the impact force, thus performing the function of a shock absorber. In this case, liquid from the lower container will flow into the upper one through the calibrated hole 28 (Fig. 28). The speed and time of reduction of the force of the ultimate impact depend on the height of the internal cavity of the ultimate impact absorber t, as well as on the diameter of the calibrated hole 28. When a wave is formed

- 3 046144 low pressure (-,-) the shock tube 1 will lower and the container 29 will lower under the influence of gravity, and the liquid will again flow through the calibrated hole 28 into the lower cavity of the container (Fig. 27).

The loop magnets 16 are made of the n-th number of magnets in order to cover the calculated outer contour of the shock tube 1 optimally for the effective one in the process of inducing the induction coil 17.

As can be seen from the above description, the device can be implemented in various embodiments, which must be considered not only in the form of the proposed designs, but also in other combinations of known possible embodiments.

Claims (5)

1. An electromagnetic induction modulator containing a pressure tank, a shock pipeline connected to the pressure tank, an air valve, a magnet and a metal plate, wherein the pressure tank has a liquid inlet pipe having a valve, as well as a liquid discharge valve, characterized in that the device contains a guide pipe connected to the pressure tank, a shock pipe installed in the guide pipe, a plug impact plate having a tap attached to the top of the shock pipe, and a gas supply pipe with a tap connected to the pressure tank, a fastening element and a metal plate attached to the fastening element, a device also contains a main plate to which a magnet is attached, loop magnets and one, two or more induction coils. 2. The electromagnetic induction modulator according to claim 1, characterized in that the device contains one, two or more electromagnetic induction modulators, one, two or more electronic devices with a contact key, as well as one, two or more electronic devices with a contact button and one , two or more contact rods. 3. Electromagnetic induction modulator according to claim 1, characterized in that the device contains a ballast weight. 4. Electromagnetic induction modulator of claim 1, characterized in that the device contains a rod attached to the main plate, to the lower end of which is attached an internal disk having a calibrated hole and a container in which the internal disk is installed. 5. Electromagnetic induction modulator according to claim 1, characterized in that the device contains one, two or more loop electromagnets.