SK289129B6 - Induction magneto-mechanical generator of electrical energery and the method of its excitation - Google Patents

Abstract

The induction magneto-mechanical electric power generator consists of a fixed frame (1), whose front end has a system of front external permanent magnets (2) and a rear end has a system of rear external permanent magnets (3), and also of a movable frame (4). whose front face has a set of front internal permanent magnets (5) and the back face has a set of rear internal permanent magnets (6). The movable frame (4) has a reciprocating bearing on the guide rods (10) of the fixed frame (1). An induction coil (7) with a core (8) is firmly placed in the space between the front and rear faces of the movable frame (4).

Description

The field of technology

The invention relates to the construction of an induction magneto-mechanical generator of electrical energy with a weakened initial mechanical reaction and also relates to the method of its excitation. The invention belongs to the field of electrical engineering.

Current state of the art

The theoretical principles of the force effect of permanent magnets are generally known. The principle of electromagnetic induction is also known. In technical practice, the non-stationary magnetic field is of great importance. It is characteristic of such a magnetic field that the physical quantities that quantitatively describe it are time-varying. This means that their magnitude or direction changes with time. The source of the non-stationary magnetic field can be:

• a time-varying current passing through a stationary conductor, • a moving conductor through which the current passes, • a moving magnet or electromagnet, and • a time-varying electric field.

It has been known since the second half of the 19th century that events in a non-stationary magnetic field are always associated with the creation of a non-stationary electric field. These are electromagnetic events in which non-stationary electric and magnetic fields are inseparable from each other and create a single electromagnetic field. The best-known example is the phenomenon arising from the movement of a permanent magnet in the coil cavity. A moving magnet creates a non-stationary magnetic field, which is the cause of the induced electric field. This means that an induced electromotive voltage arises between the ends of the conductor (coil) and an induced electric current flows through the closed electric circuit. This phenomenon was named electromagnetic induction. Electric energy generators based on electromagnetic induction use for their operation the input torque derived from the rotating mechanical part - the rotor. However, the force resistance when overcoming the interfaces of magnetic fields is considerable, and therefore a sufficiently large input mechanical energy is necessary.

It is believed that, apart from physical demonstrations, other mechanical inputs for the initiation of devices operating on the principle of electromagnetic induction are not sufficiently explored. WO2015140959 A1 describes a vibration-driven generator. This vibration driven generator includes: two sets of end permanent magnets that can vibrate axially in the frame; induction coils arranged firmly in said frame, which are coupled by a magnetic field to a second set of internal permanent magnets. The disadvantage of this system is that the vibration movement is provided by two sets of end permanent magnets and the own electromagnetic induction in the coils is provided by the second set of internal permanent magnets. Thus, three sets of permanent magnets are needed for the proper functioning of the generator.

The mentioned deficiencies from the state of the art provided an opportunity to solve this problem by appropriate technical means.

The result of this effort is the structure of the inductive magneto-mechanical generator of electrical energy with a weakened initiation mechanical reaction and the method of its excitation according to the present invention, described below.

The essence of the invention

The mentioned shortcomings are largely eliminated by the design of the induction magneto-mechanical generator of electrical energy according to the present invention. The generator consists on the one hand of a fixed frame, the front end of which has a set of front external permanent magnets and the back end has a set of rear external permanent magnets. It also consists of a movable frame, the front face of which has a set of front internal permanent magnets and the back face has a set of rear internal permanent magnets. At the same time, the movable frame has a straight return bearing on the guide rods of the fixed frame. An induction coil with a core is firmly placed in the space between the front and rear faces of the movable frame.

The essence of the invention is that the essential feature of the solution is the mutual arrangement of the system of front internal permanent magnets, in which the permanent magnet on the left side has a magnetic orientation S to the core of the induction coil and the permanent magnet on the right side has a magnetic orientation J to the core of the induction coil. At the same time, in the system of rear internal permanent magnets, the permanent magnet on the left side has a magnetic orientation J to the core of the induction coil, and the permanent magnet on the right side has a magnetic orientation S to the core of the induction coil.

Also important is the mutual arrangement of the system of front external permanent magnets, in which the permanent magnet on the left side has a magnetic orientation J to the movable frame and the permanent magnet on the right side has a magnetic orientation S to the movable frame. At the same time, in the system of rear external permanent magnets, the permanent magnet on the left side has a magnetic orientation S to the movable frame, and the permanent magnet on the right side has a magnetic orientation J to the movable frame.

In an analogous solution, the device according to the invention is functional if the system of the front external permanent magnets of the fixed frame and the rear external permanent magnets of the fixed frame and at the same time if the system of the front internal permanent magnets of the movable frame and the rear internal permanent magnets of the movable frame change their magnetic orientation from S to J and J to S.

The induction magneto-mechanical generator of electrical energy completes the action element with rectilinear reciprocating movement, which is connected to the movable frame. There is also an alternative solution, where an action member, which is a connecting rod, is connected to the movable frame via a pivot bearing. The possible drive for an induction magneto-mechanical generator of electrical energy can be the power of human muscles, wind, water flow, internal combustion engines, electric motors, pneumatic drive, electric hammer impact and others.

The design of the induction magneto-mechanical electric power generator also results in its excitation method, which is based on the fact that the repulsive forces of the front and rear external permanent magnets of the fixed frame oriented towards the front and rear internal permanent magnets of the movable frame will cause a balanced operation in both extreme positions of the movement of the movable frame of the movable frame with the expenditure of minimal supply of mechanical energy necessary to generate induced voltage in the induction coil, the core of which is in the magnetic force interaction of the alternately approaching and receding front and rear internal permanent magnets of the movable frame.

The advantages of the design of the induction magneto-mechanical generator of electrical energy with a weakened initial mechanical reaction and the method of its excitation according to the invention are obvious from the effects they manifest externally. In general, it can be stated that the force effects of the permanent magnets mounted in the movable frame on the core of the induction coil and on the permanent magnets of the fixed frame cancel each other out, which creates conditions for almost balanced operation of the device, and thus a low input of mechanical work. During the alternating movement of permanent magnets mounted in a movable frame approaching the core of the induction coil and simultaneously moving away from the opposite side of the core of the induction coil, sinusoidal electric voltages are induced in the induction coil. The system according to the invention is intended for the production and generation of electrical energy using the input of mechanical work.

Overview of images on drawings

The design of the induction magneto-mechanical generator of electrical energy with a weakened initiation mechanical reaction according to the invention will be explained in more detail in the drawings, where in fig. 1 shows its assembly in one functional extreme position. In fig. 2 shows its assembly in the second functional extreme position.

Examples of implementation of the invention

Individual embodiments according to the invention are presented for illustration and not as limitations of technical solutions. Those skilled in the art will find or be able to discover, using no more than routine experimentation, many equivalents to specific embodiments of the invention. Such equivalents will also fall within the scope of the following patent claims. The optimal design of the structure and the selection of its elements cannot be a problem for an expert familiar with the state of the art, therefore these features have not been dealt with in detail.

Example 1

In this example of a specific embodiment of the subject of the invention, the first construction of an induction magneto-mechanical generator of electrical energy with a weakened initiation mechanical reaction is described, as shown in fig. 1. It consists on the one hand of a fixed frame 1, the front end of which has a set of front external permanent magnets 2 and the back end has a set of rear external permanent magnets 3. It also consists of a movable frame 4, the front end of which has a set of front internal permanent magnets 5 and the rear face has a set of rear internal permanent magnets 6. The movable frame 4 has a rectilinear bearing on the guide rods 10 of the fixed frame 1. In the space between the front and rear faces of the movable frame 4, an induction coil 7 with a core 8 is firmly placed. the frame 4 is connected to the action member 9 with rectilinear reciprocating movement.

An essential feature of the solution is the mutual arrangement of the system of front internal permanent magnets 5, in which the permanent magnet 5 on the left side has a magnetic orientation S to the core 8 of the induction coil 7 and the permanent magnet 5 on the right side has a magnetic orientation J to the core 8 of the induction coil 7. in the system of rear internal permanent magnets 6, the permanent magnet 6 on the left side has a magnetic orientation J to the core 8 of the induction coil 7 and the permanent magnet 6 on the right side has an orientation S to the core 8 of the induction coil 7.

The mutual arrangement of the system of front external permanent magnets 2 is also important, in which the permanent magnet 2 on the left side has a magnetic orientation J to the movable frame 4 and the permanent magnet 2 on the right side has a magnetic orientation S to the movable frame 4. Meanwhile, in the system of rear external permanent magnets of magnets 3, the permanent magnet 3 on the left side has a magnetic orientation S to the movable frame 4 and the permanent magnet 3 on the right side has a magnetic orientation J to the movable frame 4.

Example 2

In this example of a specific embodiment of the subject of the invention, the second design of the induction magneto-mechanical generator of electrical energy with a weakened initiation mechanical reaction is described, as shown in fig. 2. The device is sufficiently described in its essential features already in example 1. The only difference is that the movable frame 4 is connected to the movable frame 4 via the pivot bearing, which is the connecting rod.

Example 3

In this example of a specific embodiment of the subject of the invention, a third design of the induction magneto-mechanical generator of electrical energy with a weakened initiation mechanical reaction is described, as shown in fig. 1 and 2. In the system of the front external permanent magnets 2 of the fixed frame 1 and the rear external permanent magnets 3 of the fixed frame 1 and at the same time in the system of the front internal permanent magnets 5 of the movable frame 1 and the rear internal permanent magnets 6 of the movable frame 1, their magnetic orientation S is changed on S and S on S.

Example 4

In this example of a specific embodiment of the subject of the invention, a method of excitation of an induction magneto-mechanical generator of electrical energy with a weakened initial mechanical reaction is described. It is based on the fact that the repulsive forces of the front external permanent magnets 2 and the rear external permanent magnets 3 of the fixed frame 1, oriented towards the front internal permanent magnets 5 and the rear internal permanent magnets 6 of the movable frame 4, will cause in both extreme positions of the movement of the movable frame 4 a balanced operation of the movable of the frame 4 with the expenditure of the minimum supply of mechanical energy necessary for the generation of induced voltage in the induction coil 7, the core 8 of which is in the magnetic force interaction of the alternately approaching and receding front internal permanent magnets 5 and rear internal permanent magnets 6 of the movable frame 4.

Industrial applicability

The industrial applicability of the design of the induction magneto-mechanical generator of electrical energy with a weakened initial mechanical reaction and the method of its excitation according to the invention is primarily in the electrical industry.

Claims (2)

1. Induction magneto-mechanical electric energy generator consisting of a fixed frame (1), the front face of which has a set of front external permanent magnets (2) and the back face has a set of rear external permanent magnets (3), as well as a movable frame (4) ), the front end of which is equipped with a system of front internal permanent magnets (5) and the rear end is equipped with a system of rear internal permanent magnets (6), while the movable frame (4) has a rectilinear reciprocating bearing on the guide rods (10) of the fixed frame (1) ; in the space between the front and rear faces of the movable frame (4), an induction coil (7) with a core (8) is firmly placed, characterized by the fact that in the system of front internal permanent magnets (5), the permanent magnet (5) on the left side has a magnetic orientation S to the core (8) of the induction coil (7) and the permanent magnet (5) on the right side has a magnetic orientation J to the core (8) of the induction coil (7); whereas in the system of rear internal permanent magnets (6) the permanent magnet (6) on the left side has a magnetic orientation J to the core (8) of the induction coil (7) and the permanent magnet (6) on the right side has a magnetic orientation S to the core (8) induction coil (7); in the system of front external permanent magnets (2), the permanent magnet (2) on the left side has a magnetic orientation J to the movable frame (4) and the permanent magnet (2) on the right side has a magnetic orientation S to the movable frame (4); while in the system of rear external permanent magnets (3), the permanent magnet (3) on the left side has a magnetic orientation S to the movable frame (4) and the permanent magnet (3) on the right side has a magnetic orientation J to the movable frame (4). 2. A method of excitation of an induction magneto-mechanical generator of electrical energy, characterized in that the repulsive forces of the front external permanent magnets (2) and the rear external permanent magnets (3) of the fixed frame (1) oriented towards the front internal permanent magnets (5) and the rear internal permanent magnets by the magnet (6) of the moving frame (4) in both extreme positions of the movement of the moving frame (4) will cause a balanced operation of the moving frame (4) with the expenditure of minimal supply of mechanical energy necessary for the generation of induced voltage in the induction coil (7), whose core (8) is in the magnetic force interaction of the alternately approaching and receding front internal permanent magnets (5) and rear internal permanent magnets (6) of the movable frame (4).