RU182991U1 - Linear generator - Google Patents

Abstract

The utility model relates to the field of electrical engineering, namely to electrical machines that convert the mechanical energy of the reciprocating motion into electrical energy. The required technical result, which consists in increasing the efficiency of converting mechanical energy into electrical energy, while at the same time providing an increased maximum frequency of the generated electric current, is achieved in a device containing two magnetic circuits facing each other, two pairs of working coils and two pairs of permanent magnets made with the possibility of horizontal mounting on the drive of the linear generator, and the magnetic cores are made U-shaped in plan and facing each other vertically elements, in the gap between the same vertical elements of the magnetic cores are placed the corresponding pairs of permanent magnets at a distance between pairs corresponding to the distance between the pairs of vertical elements of the magnetic cores, while the permanent magnets in each pair are made with the opposite polarity and are installed with an adjustable gap, and the working coils, made in the form of windings of vertical elements of the magnetic circuits, connected to a single electrical circuit, the output of which is the output of a linear the generator. 8 s.p. f-ly, 1 ill.

Description

The utility model relates to the field of electrical engineering, namely to electrical machines that convert the mechanical energy of the reciprocating motion into electrical energy.

A technical solution is known comprising a cylindrical body, two cylindrical magnetic cores with axial magnetization located inside the cylindrical body and facing each other with the same poles, two cylindrical coils with axial windings placed on the cylindrical body above the corresponding magnetic cores [RU 83373, H02K 35 / 02, 01/27/2011].

The disadvantage of this device is the lack of conversion of mechanical energy into electric current.

A linear electric generator is also known [RU 101881, Н02К 35/02, 01/27/2011], comprising a cylindrical body, two cylindrical magnetic cores with axial magnetization located inside the cylindrical body and facing each other with the same poles, two cylindrical coils with axial windings placed on a cylindrical body above the respective magnetic cores.

The disadvantage of this technical solution is also the insufficient efficiency of the conversion of mechanical energy into electric current.

The closest in technical essence to the proposed one is a linear electric generator [RU 2654079, C2, Н02К 35/02, 05.16.2018] containing a cylindrical body, two magnetic cylindrical core with axial magnetization, placed inside the cylindrical body and facing each other with the same name poles, two cylindrical coils with axial windings placed on a cylindrical body above the corresponding magnetic cores, and a cylindrical coil with a radial winding located on the cylindrical m case between cylindrical coils with axial windings.

The disadvantage of the closest technical solution is the relatively low efficiency of converting mechanical energy into electric current, which determines the efficiency of the generator.

The task is to create a generator that provides increased efficiency for converting mechanical energy into electrical energy.

The technical result consists in increasing the efficiency of converting mechanical energy into electrical energy.

The problem is solved, and the required technical result is achieved by the fact that, in a linear generator containing two magnetic circuits facing each other, the first pair of working coils and the first pair of permanent magnets, made with the possibility of horizontal mounting on the drive of the linear generator, according to the utility model, introduced a second pair of permanent magnets, made with the possibility of horizontal mounting on the drive of a linear generator, and a second pair of working coils, and the magnetic cores are made U-shaped in the plan and facing each other with vertical elements, in the gap between the same vertical elements of the magnetic cores are placed the corresponding pairs of permanent magnets at a distance between pairs corresponding to the distance between the pairs of vertical elements of the magnetic cores, while the permanent magnets in each pair are made with the opposite polarity and installed with an adjustable gap, and working coils made in the form of windings of the vertical elements of the magnetic circuits are connected in a single electrical circuit, the output of which is the output of a linear generator.

In addition, the desired technical result is achieved in that, the working coils are connected in a single electric circuit with their serial connection.

In addition, the required technical result is achieved in that, the working coils are connected in a single electrical circuit with their parallel connection.

In addition, the desired technical result is achieved in that, the working coils are connected in a single electric circuit with their parallel-serial connection.

In addition, the required technical result is achieved in that the gap between the permanent magnets and the ends of the vertical elements of the magnetic cores is a = 0.25-0.5 mm.

In addition, the required technical result is achieved in that the gap between the permanent magnets in pairs is b = 10-15% of their width.

In addition, the required technical result is achieved in that the vertical elements of the magnetic cores in the section are rectangular, and the permanent magnets are made in the form of rectangular parallelepipeds with a section corresponding to the section of the vertical elements of the magnetic cores.

In addition, the required technical result is achieved in that, the cross sections of the vertical elements of the magnetic cores and permanent magnets are made equal in width and length.

In addition, the required technical result is achieved by the fact that the height of the permanent magnets is h = 0.1L mm, where L = (H + D / 2 - s) is the length of the midline of the magnetic circuit.

The height of the magnets also depends on the magnetic permeability of the magnetic circuit and the initial induction of the magnets.

The drawing shows a linear electric generator in conjunction with the drive of a linear generator.

In the drawing are indicated:

1 - magnetic circuit;

2 - working windings;

3 - drive linear generator;

4 - two pairs of permanent magnets.

The linear generator contains two magnetic circuits 1 facing each other, the first and second pair of working coils 2 and the first and second pair of permanent magnets 4, made with the possibility of horizontal mounting on the drive 3 of the linear generator.

In a linear generator, the magnetic cores 1 are made U-shaped in plan and face each other with vertical elements, and in the gap between the same vertical elements of the magnetic cores, the corresponding pairs of permanent magnets 4 are placed at a distance between pairs corresponding to the distance between the pairs of vertical elements of the magnetic cores.

In addition, in the linear generator, the permanent magnets 4 in each pair are made with the opposite polarity and are installed with an adjustable gap, and the working coils 2, made in the form of windings of the vertical elements of the magnetic circuits, are connected to a single electric circuit, the output of which is the output of the linear generator.

The connection of the working coils 2 can be serial, parallel or parallel-serial.

The gap between the permanent magnets 4 and the ends of the vertical elements of the magnetic circuit is a = 0.25-0.5 mm. At lower values of the gap, their mechanical destructive interaction can occur; at large values, the level of the output signal of the linear generator significantly decreases.

The gap between the permanent magnets in pairs is b = 10-15% of their width and in the particular case b = 2 mm.

The vertical elements of the magnetic cores 1 in the section are made rectangular, and the permanent magnets 4 are made in the form of rectangular parallelepipeds with a section corresponding to the section of the vertical elements of the magnetic cores. The most effective version of the linear generator, when the cross sections of the vertical elements of the magnetic circuits 1 and the permanent magnets 4 are made equal in width and length.

The height of the permanent magnets in the particular case is h = 6 mm.

The linear generator operates as follows.

Permanent magnets 4 are mounted on the drive 3 of a linear generator of non-magnetic material, which is connected, for example, with a two-stroke internal combustion engine. The drive 3 of the linear generator slides along the guide supports in such a way that a small gap is provided within a = 0.25-0.5 mm between the permanent magnets 4 and the magnetic circuit 1. The magnetic circuit 1 is made in such a way as to reduce losses on its heating, for example from the thin strips of transformer iron connected together.

The design of the supports is selected so as to provide the least resistance to movement of the actuator 3.

Permanent magnets 4 in each pair are made with the opposite polarity and installed with an adjustable gap, and working coils made in the form of windings of the vertical elements of the magnetic circuits 1 are connected to a single electrical circuit, the output of which is the output of a linear generator.

Between the permanent magnets 4 in pairs there is a gap b, the selection of which achieves the desired shape of the output current or voltage ~ U from the working windings 2, for example, a shape close to a sinusoid.

Since changes in the output voltages occur in phase, the working windings 2 can be connected in parallel, in parallel, in series or in series. An alternating output voltage may be supplied to the rectifier to obtain a constant voltage.

For normal operation of the linear generator, it is necessary that the width of the permanent magnets 4 is equal to the thickness of the magnetic circuit 1, and the length is the width of the magnetic circuit 1.

When the reciprocating movement of the drive 3 at a distance equal to half the value of "c" from the middle position, the induction in the magnetic circuit 1 changes from 0 to a certain value B _max or (- V _max, ) The value B _max is determined by the thickness of the permanent magnets 4, magnetic permeability of the material of the magnetic circuit and the initial induction of magnets.

When the reciprocating motion of the drive 3 (± s / 2) in the magnetic circuit 1, an alternating magnetic flux occurs, the amplitude value of which is defined as the product of induction B by the cross-sectional area of the magnetic circuit S = dxc. The voltage ~ U at the output of the working coil 2 is proportional to the rate of change of the magnetic flux, which depends on the frequency of the reciprocating movements of the drive 3.

Improving the efficiency of converting mechanical energy into electrical energy is ensured by the fact that when the pairs of permanent magnets are increased to two and their placement between the vertical elements of the magnetic cores when they are U-shaped. The indicated arrangement of magnets ensures minimal dispersion of their magnetic field, and the connection of the working windings into a single circuit ensures maximum energy removal.

In addition, since the permanent magnets 4 in each pair are made with the opposite polarity and are installed with an adjustable gap, in addition to increasing the conversion efficiency, at the same time, the effect of the increased maximum frequency of the generated electric current and the possibility of adjusting its shape are ensured.

In this case, the small thickness of the permanent magnets provides a small mass of the movable system as part of the drive and permanent magnets. It also leads to an increase in conversion efficiency. The displacement amplitude of the mobile system is of little importance - for 100 W of generator power - about 10 mm and for 30 kW of power - 20 mm.

Claims (9)

1. A linear generator containing two magnetic circuits facing each other, the first pair of working coils and the first pair of permanent magnets, made with the possibility of horizontal mounting on the drive of the linear generator, characterized in that the second pair of permanent magnets is introduced, made with the possibility of horizontal mounting on a linear generator drive, and a second pair of working coils, the magnetic cores being made U-shaped in plan and facing each other by vertical elements, in the gap between the same name the vertical elements of the magnetic cores are placed the corresponding pairs of permanent magnets at a distance between pairs corresponding to the distance between the pairs of vertical elements of the magnetic cores, while the permanent magnets in each pair are made with the opposite polarity and installed with an adjustable gap, and working coils made in the form of windings of the vertical elements of the magnetic are connected in a single electrical circuit, the output of which is the output of a linear generator. 2. The linear generator according to claim 1, characterized in that the working coils are connected in a single electric circuit with their series connection. 3. The linear generator according to claim 1, characterized in that the working coils are connected in a single electric circuit with their parallel connection. 4. The linear generator according to claim 1, characterized in that the working coils are connected in a single electric circuit with their parallel-serial connection. 5. The linear generator according to claim 1, characterized in that the gap between the permanent magnets and the ends of the vertical elements of the magnetic circuits is a = 0.25-0.5 mm. 6. The linear generator according to claim 1, characterized in that the gap between the permanent magnets in the pairs is b = 10-15% of their width. 7. The linear generator according to claim 1, characterized in that the vertical elements of the magnetic cores in the section are made rectangular, and the permanent magnets are made in the form of rectangular parallelepipeds with a section corresponding to the section of the vertical elements of the magnetic cores. 8. The linear generator according to claim 1, characterized in that the cross sections of the vertical elements of the magnetic cores and the permanent magnets are made equal in width and length. 9. The linear generator according to claim 1, characterized in that the height of the permanent magnets is h = 0.1L mm, where L = (H + D / 2 - s) is the length of the midline of the magnetic circuit.

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