RU157218U1 - MOTOR-HEATING ENGINE - Google Patents

Abstract

Magnetothermal motor containing a stator made in the form of two parallel fixed disks of non-metallic material, a magnetic system of two opposite-pole permanent magnets located on the edges of the stator disks and facing one another with the formation of an inter-pole gap, a shaft located rotationally coaxial to the stator, rotor made in the form of a disk mounted on the shaft between the stator disks and provided with active elements made in the form of ferromagnetic plates attached to the rotor disk and around its circumference with the possibility of passing through the interpolar gap during its rotation, the coolant supply unit and the refrigerant supply unit, characterized in that the magnetic system is made of sets of different-pole permanent magnets, each set consists of two permanent magnets having different magnetic induction and composed in one row, while the magnets are located in increasing magnetic induction, and the coolant supply unit is located opposite the pole gap of the magnets with the largest magnetic induction.

Description

The utility model relates to the field of energy, designed to convert thermal energy into mechanical and / or electrical energy and can be used in the engine industry to create engines and generators of electric energy, including autonomous energy supply systems.

Known magnetothermal motor comprising a stator made in the form of two parallel fixed disks of non-metallic material, a magnetic system of two opposite-pole permanent magnets located on the edges of the stator disks and facing one another with the formation of an interpolar gap, a shaft located rotatably coaxially with the stator, a rotor made in the form of a disk mounted on a shaft between the stator disks and provided with active elements made in the form of ferromagnetic plates attached to along its circumference with the possibility of passing through the interpolar gap during rotation of the rotor disk, the coolant supply unit and the refrigerant supply unit (RF patent for utility model No. 134249, IPC F03G 7/00, publ. 2013),

However, the known motor is characterized by insufficient power for converting magnetothermal energy into mechanical and / or electrical energy due to the use of only one set (one brand) of different-pole permanent magnets with a constant magnitude of magnetic induction. As a result, along the length of the interpolar gap there is no continuous and continuous increase in the magnitude of the magnetic induction and, as a consequence, remains constant, and the force of the action of the poles of the permanent magnets on the ferromagnetic plates of the rotor disk does not grow, which reduces the power of converting magnetothermal energy into mechanical and / or electrical and thereby limits the scope of the known engine.

The objective of this utility model is to increase the mechanical and / or electrical power of a magnetothermal engine by accelerating the rotation of the rotor disk.

The technical result achieved by the proposed utility model is a continuous increase in the magnitude of the magnetic induction along the length of the pole gap of the permanent magnets by performing a magnetic system of sets of multi-pole permanent magnets. Each set consists of two permanent magnets having different magnetic induction and arranged in one row. In this case, the magnets are located in increasing magnetic induction, and a tube of hot water is located opposite the pole gap of the magnets with the greatest magnetic induction.

The problem is solved in that in a magnetothermal motor containing a stator made in the form of two parallel fixed disks of nonmetallic material, a magnetic system of two opposite-pole permanent magnets located on the edges of the stator disks and facing one another with the formation of an interpolar gap, a shaft located coaxial to the stator with the possibility of rotation, a rotor made in the form of a disk mounted on a shaft between the stator disks and provided with active elements made in the form of a ferromagnet plates attached to the rotor disk around its circumference with the possibility of passing through the interpolar gap when it rotates, the coolant supply unit and the refrigerant supply unit, according to the utility model, the magnetic system is made of sets of different pole permanent magnets, each set consists of two permanent magnets having different magnetic induction and arranged in one row, while the magnets are located in increasing magnetic induction, and the tube with hot water is located opposite the pole gap of the magnets with the most Olsha magnetic induction.

The proposed magnetothermal engine allows you to increase the mechanical or electrical power and expand its scope.

In FIG. 1 shows the proposed magnetothermal engine.

In FIG. 2 is a section AA of FIG. one.

In FIG. Figure 3 shows a general view of a magnetic system composed of permanent magnets of various powers

In FIG. 4 is a table showing the brands of magnets and their power

In FIG. Figure 5 shows a graph of the variation in the magnetic induction of magnets of various grades along the length of the pole gap of permanent magnets.

In FIG. 6 is a graph of the change in magnetic induction along the length of the inter-pole gap of permanent magnets, where curve B is obtained for a magnetic system composed of one set of different-pole permanent magnets, and curve B is for the magnetic system of the proposed magnetothermal engine.

The proposed magnetothermal motor contains a stator made in the form of two parallel fixed disks 1, 2 of non-metallic material, a magnetic system of two opposite-pole permanent magnets 3 located on the edges of the stator disks 1, 2 and facing one another with the formation of an interpolar gap 4, shaft 5 located coaxially to the stator with the possibility of rotation using bearings 6, a rotor made in the form of a disk 7 mounted on the shaft 5 between the disks 1, 2 of the stator and equipped with active elements made in the form of a fer magnetic plates 8 attached to the disk 7 of the rotor around its circumference with the possibility of passing through the interpolar gap 4 when it is rotated, the coolant supply unit 9 and the refrigerant supply unit 10. The magnetic system 3 has an inter-pole gap 4 and is made of sets of different-pole permanent magnets, each set consists of two permanent magnets having different magnetic induction and arranged in one row, while the magnets are arranged in increasing magnetic induction (Fig. 3) and this growth occurs in the direction of rotation of the disc 7 of the rotor. The coolant supply unit 9 is located opposite the interpolar gap of the magnets 12 with the greatest magnetic induction and is made in the form of a tube for supplying hot water, and the coolant supply unit 10 is located at an angle of 15 ° ÷ 330 ° from the magnets 3 in the direction of rotation of the rotor disk 7 and is made in the form tubes for supplying cold water. Tubes for supplying hot and cold water are installed on the outside of the rotor disk 7 and are fixed to the fixed disk 2 of the stator. The ferromagnetic plate 8 can be located perpendicular to the disk 7 of the rotor. To facilitate the disk 7 of the rotor can be made with through holes 13.

The inventive magnetothermal engine operates as follows. Due to the fact that the magnetic system is made up of sets of opposite-pole permanent magnets, each set consists of two permanent magnets having different magnetic induction and arranged in one row, while the magnets are arranged in increasing magnetic induction, the active elements are ferromagnetic plates 8 in between the pole gap 4 magnets 3 are accelerated in the direction of rotation of the disk 7 of the rotor due to the emerging gradient of magnetic induction in section 11, where a set of magnets with increasing magnetic induction is located, and in e 12, where the magnet with maximum magnetic induction is located, they are heated by hot water. Hot water through the node 9 under a small pressure is continuously supplied to the section 12, where the magnet with maximum magnetic induction is located, into the interpolar gap 4. As a result, the active elements are the ferromagnetic plates 8, which are currently in the area of the section of 12 magnets with the maximum magnetic by induction, they are heated to a temperature at which they become paramagnetic (demagnetized). At the same time, magnets 3 attract an adjacent ferromagnetic plate 8, which has not yet been heated by the action of hot water. As a result, the demagnetized plates 8 are pushed out of the zone of the magnet portion 12 with maximum magnetic induction (from the pole gap 4) with a force directly proportional to the magnetization jump of the plates 8 and the magnitude of the magnetic induction gradient in the pole gap 4 of the magnets 3. Since the ferromagnetic plates 8 are attached to the disk 7 of the rotor, then the rotor together with the shaft 5 rotates due to the pulse received from the plates 8, and in the area of the section of 12 magnets with maximum magnetic induction (in the pole gap 4) are prob (adjacent) of the plate 8, has not been subjected to heating hot water. The cooling zone of the ferromagnetic plates 8 covers the area beyond the magnets 3 (outside the range of magnetic forces) in the direction of rotation of the rotor disk 7, which greatly facilitates the effective heat removal from the heated plates 8 with cold water to a temperature at which they completely restore their original magnetic state, and the cycle repeats. All active elements - ferromagnetic plates 8 in each of the stages of their separate, sequential heating - cooling acquire a mechanical impulse transmitted by them to the rotor disk 7 of the magnetothermal engine in the direction of its rotation. The angular velocity of rotation of the rotor disk 7 is determined by the resulting force acting on it, the magnitude of which is directly proportional to the magnetic field gradient per unit length of magnets 3 in the interpolar gap 4, the total mass of active elements - ferromagnetic plates 8, simultaneously falling under the magnetic field, the magnitude of the magnetization jump ferromagnetic plates 8, which is practically realized in the heating - cooling cycle, the rate of phase transition from the ferromagnetic state to the paramagnetic state and vice versa.

The choice of the range of the angle of supply of cold water 15 ° ÷ 330 ° is due to the fact that at angles less than 15 ° and more than 330 ° from the magnets 3 in the direction of rotation of the rotor disk 7, a partial hit of cold water on the portion 12 of the magnets with the maximum magnetic induction of the pole gap 4, which will in due time cool the ferromagnetic plates 8 located at that moment on it, as a result, forces will appear that counteract the rotation of the rotor disk 7.

The selection of a specific material of the ferromagnetic plates 8 is due to the choice of coolant and refrigerant, as well as the value of the phase transition temperature (Curie point) of the ferromagnet from the ferromagnetic state to the paramagnetic state. With the selected coolant and refrigerant (hot and cold water), gadolinium Gd, which has a phase transition temperature (Curie point) close to room temperature (20 ° C), is optimal as a material for plates 8. When using gadolinium plate 8 there is no need to heat water to high temperatures (up to 80 ° C).

Using the utility model will increase the mechanical and / or electrical power of the magnetothermal engine and expand its scope, which will undoubtedly give an economic effect.

Claims (1)

Magnetothermal motor containing a stator made in the form of two parallel fixed disks of non-metallic material, a magnetic system of two opposite-pole permanent magnets located on the edges of the stator disks and facing one another with the formation of an inter-pole gap, a shaft located rotationally coaxial to the stator, rotor made in the form of a disk mounted on the shaft between the stator disks and provided with active elements made in the form of ferromagnetic plates attached to the rotor disk and around its circumference with the possibility of passing through the interpolar gap during its rotation, the coolant supply unit and the refrigerant supply unit, characterized in that the magnetic system is made of sets of different-pole permanent magnets, each set consists of two permanent magnets having different magnetic induction and composed in one row, while the magnets are located in increasing magnetic induction, and the coolant supply unit is located opposite the pole gap of the magnets with the largest magnetic induction.

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