RU2599258C1 - Magnetic induction voltage generator - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to electrical engineering, to devices generating electric power using magnetic appliances. Device includes a housing, inside which there is a spring, as well as ferromagnetic core, around which there is a inductive winding. Ferromagnetic core consists of a set of magnets arranged with non-magnetic gap and reverse polarity relative to each other, and is suspended to spring. Around the magnets there is a hollow cylinder, one end of which is attached to the inner side of upper wall of the body. Around the cylinder at the location of ferromagnetic core there are several oncoming inductive windings. Ferromagnetic core and/or spring are connected to source of oscillations.

EFFECT: technical result consists in improvement of efficiency and wider range of equipment.

8 cl, 5 dwg

Description

The invention relates to the field of energy, and in particular to devices that generate electricity using magnetic means [IPC H02N 11/00].

A DEVICE FOR TRANSFORMING ELECTROMAGNETIC ENERGY INTO MECHANICAL [RF patent No. 116287] is known, which can be used to convert mechanical work into electrical energy. For these purposes, the prototype is made in the form of a rod with a load and magnets located in the upper and lower parts of the rod, a mechanism for converting the reciprocating motion into rotational motion.

The disadvantage is the low efficiency due to the low electromotive force arising in the device under the influence of a magnetic field.

The closest in technical essence is a SEISMOACOUSTIC OSCILLATION SENSOR [RF patent No. 14682] containing a housing within which a spring is suspended, as well as a ferromagnetic rod around which an inductive coil is located.

The disadvantage of the prototype is the lack of an external source of oscillation.

The technical result consists in expanding the arsenal of technical means, increasing efficiency.

The technical result is achieved due to the fact that the prototype containing the housing inside which the spring is suspended, as well as the ferromagnetic rod around which the inductive winding is located, is characterized in that the ferromagnetic rod consists of a set of magnets located with a non-magnetic gap and reverse polarity relative to each other ; a ferromagnetic rod is suspended from a spring, around which there is a hollow cylinder, one of the ends of which is attached to the inner side of the upper wall of the housing; around the cylinder, at the location of the ferromagnetic rod, there are several opposite inductive windings, while the ferromagnetic rod and / or spring are connected to a vibration energy source.

In particular, the oscillation energy source is made in the form of a piston tape with a tape drive mechanism that is installed inside the housing, while the piston tape is placed under the rod at the end of which the firing pin is made.

In particular, the oscillation energy source is made in the form of a plate mounted on the outer side of the housing at one end of the lever, on the other hand, a spring with a ferromagnetic rod is suspended from the lever through the hole in the upper part of the housing, while at the location of the plate between the lever and the housing spring.

In particular, the source of forced oscillations is made in the form of an additional winding made of copper wire over oncoming inductive windings, closed on an additional current source through a key.

In particular, the plate is made of thin and light material, and also has a large windage.

In particular, the oscillation energy source is made in the form of an additional inductive winding located around oncoming inductive windings, while it is closed to an additional power source through a key.

In particular, the cylinder is made of dielectric.

In particular, oncoming coils are closed to the consumer of electric energy.

In particular, the housing is mounted on adjustable legs.

Brief Description of the Drawings

In FIG. 1 shows an embodiment of a magneto-induction voltage generator with piston tape.

In FIG. 2 shows an embodiment of a magneto-induction voltage generator with a plate.

In FIG. 3 shows an embodiment of a magneto-induction voltage generator with an additional winding.

In FIG. Figure 4 shows the arrangement of magnets on the rod of a magneto-induction voltage generator.

In FIG. 5 is a diagram of a commutation of oncoming inductive windings of a magnetic induction voltage generator.

The implementation of the invention

The magneto-induction voltage generator comprises a housing 1, inside of which a spring 2 with a ferromagnetic rod 3 is suspended from the upper wall. A hollow cylinder 4 is located around the spring 2 and the ferromagnetic rod 3. A counter induction winding 5 is installed around the cylinder 4 at the location of the rod 3.

In one embodiment of the implementation of a magnetic induction voltage generator (see Fig. 1), a striker 6 is installed at the end of the rod 3, under which there is a tape drive mechanism 7 with a piston tape 8.

In another embodiment, the implementation of the magnetic induction voltage generator (see Fig. 2) on top of the housing on the support 9 is a lever 10, one of which has a plate 11, and a spring 2 with a rod 3 is suspended from the other end. Between the lever 10 and the housing 1 the place of installation of the plate 11 is installed spring 12.

In another embodiment of the magneto-induction voltage generator (see Fig. 3), an additional field winding is located in the lower part of the magnetic rod, which is closed via a key to the current source and is activated when the magnetic rod is raised upward, thereby increasing the amplitude by moving masses. The metal rod 13 of the linear motor is inserted into the magnetic rod 14, and a stroke limiter 15 (stop) is installed at the end of the rod 13.

When voltage is applied to the winding 18 of the linear motor, consisting of several coils, a magnetic field is created, which makes it possible to pull an additional load 17 to the magnetic rod 14, thereby increasing the oscillations of the magnetic rod on the spring. The additional load 17 is a gravilator and has 1 / 5-1 / 7 of the total mass of the load suspended on a spring. Upon reaching the magnetic rod of the upper point, the key switches, the magnetic field in the coils 18 creates a repulsive direction of the linear motor, thereby directing the additional load 17 downward, again increasing the vibrations of the rod 14.

This option is good in that it increases the operating time of the device several times.

The ferromagnetic rod 3 (see Fig. 4) consists of a set of magnets 14, which are mounted on the base 14 with a non-magnetic gap and reverse polarity relative to each other.

Counter induction windings 5 (see Fig. 5) are closed to the consumer 15.

The housing 1 is mounted on adjustable legs 16.

The cylinder 4 is made of a thin-walled dielectric.

The magnets 14 may be made of neodymium magnets.

Plate 11 has a large area, low weight and high windage.

The device is used as follows.

Magnetic induction voltage generator is placed on a flat surface and using adjustable legs 16 is aligned in its horizontal plane. In the embodiment with the piston tape 8, the strikers 6 of the rod 3 hits the piston of the piston tape 8 and causes it to burst, while the energy of the powder gases pushes the rod 3 upwards, when it reaches the upper point due to its own mass, the rod 3 moves downward and pulls the spring 2, which in turn tends to take its initial position and thereby creates a fading reciprocating motion of the rod 3. The movement of the rod 3 changes the position of the magnets 14 and their magnetic field relative to the windings 5, in which electromotive force, which is transmitted to the consumer 15. At the time when the movement of the rod 3 attenuates to a critically small value, the tape drive mechanism 8 extends another piston under the rod 3, the firing pin 6 of which produces a piston explosion.

In the case of using the embodiment of the invention with the plate 11, the source of oscillation of the rod 3 is the wind force, which drives the plate 11, while the plate 11 transfers energy through the lever 10 to an oscillating system consisting of a spring 2 and a rod 3.

If an additional exciting winding is used as a source of forced oscillations, the oscillatory system activates the magnetic field of the winding when it is short-circuited to a current source.

A positive technical effect of the use of the device is to expand the range of devices designed to convert mechanical vibration energy into electrical energy.

Considering the fact that swinging requires a little effort, the device can work from swinging at least by hand, even by foot. So, for example, to swing a magnetic rod weighing one ton, a force of 10 Newtons is enough to operate the device for 30 minutes. Also, the device has a minimum of friction. Thus, the result of these advantages is an increase in efficiency.

Claims (8)

1. Magnetic induction voltage generator, comprising a housing, within which a spring is suspended, and a ferromagnetic rod, around which an inductive winding is located, characterized in that the ferromagnetic rod consists of a set of magnets located with a non-magnetic gap and reverse polarity relative to each other; a ferromagnetic rod is suspended from a spring, around which there is a hollow cylinder, one of the ends of which is attached to the inner side of the upper wall of the housing; around the cylinder, at the location of the ferromagnetic rod, there are several opposite inductive windings, while the ferromagnetic rod and / or spring are connected to a vibration energy source. 2. The magneto-induction voltage generator according to claim 1, characterized in that the oscillation energy source is made in the form of a piston tape with a tape drive mechanism that is installed inside the housing, while the piston tape is placed under the rod at the end of which the firing pin is made. 3. The magneto-induction voltage generator according to claim 1, characterized in that the oscillation energy source is made in the form of a plate mounted on the outer side of the housing at one of the ends of the lever, on the other hand, a spring with a ferromagnetic rod is suspended through the hole in the upper part of the housing, while in the location of the plate between the lever and the housing is a spring. 4. Magnetic induction voltage generator according to claim 3, characterized in that the plate is made of thin and light material, and also has a large windage. 5. The magneto-induction voltage generator according to claim 1, characterized in that the oscillation energy source is made in the form of an additional inductive winding located around oncoming inductive windings, while it is closed to the additional power source through a key. 6. The magneto-induction voltage generator according to claim 1, characterized in that the cylinder is made of a dielectric. 7. The magneto-induction voltage generator according to claim 1, characterized in that the oncoming coils are closed to the consumer of electrical energy. 8. The magneto-induction voltage generator according to claim 1, characterized in that the housing is mounted on adjustable legs.

Images