BR202019022592Y1 - PURELY MAGNETIC TESLA TYPE MOTOR - Google Patents

Abstract

PURELY MAGNETIC TESLA TYPE MOTOR. The present utility model, entitled Purely Magnetic Tesla Type Motor, falls within the technical field of transformation, more precisely intended for the transformation of magnetic energy into mechanical energy that allows a marked thermal exchange between magnetic material and operating fluid, providing rapid magnetic state transition, thus causing an increase in the motor’s working frequency. This machine consists of a double C magnetic circuit that provides two identical magnetic poles with high field intensity, heat exchangers with a porous bed of magnetic material in different magnetic arrangements, with thermal exchange by forced convection due to the passage of fluid (now hot, sometimes cold) that changes the magnetic properties of the material, causing it to be attracted or not to the magnetic field, promoting an alternating movement through displacement in linear guides. The linear movement is transformed into rotational movement through a ratchet mechanism and can produce mechanical power or electrical energy using solar energy as a heat source or a cogeneration system by taking advantage of industrial thermal waste, that is, it is capable of operating without emitting carbon into the atmosphere.

Description

TECHNICAL FIELD OF THE INVENTION

[01] The present utility model, entitled “PURELY MAGNETIC TESLA TYPE MOTOR”, falls within the technical field of transformation, more precisely the transformation of magnetic energy into mechanical energy.

INTRODUCTION

[02] Energy is a key input for the socioeconomic development of a nation. Due to population growth and economic factors, the demand for energy has been increasing in recent years (WORLD ENERGY COUNCIL, 2016; INTERNATIONAL ENERGY AGENCY, 2018). This increase in demand is even more significant when looking at data referring to emerging countries or countries that are not members of the Organization for Economic Cooperation and Development (OECD). In projections for the coming decades, energy consumption could increase by 64% by 2040 (INTERNATIONAL ENERGY AGENCY, 2018).

[03] To meet the rapid growth in demand, it is trivial to choose well-established, cheap and easily accessible energy sources. In other words, preference is given to the use of fossil fuels for primary energy production, which culminates in increased emissions of greenhouse gases and other pollutants. Furthermore, fossil sources are not renewable and are subject to political instability which, from time to time, results in an increase in fuel prices. This scenario, associated with the projections of the Intergovernmental Panel on Climate Change (IPCC) regarding potential climate changes caused by excessive CO2 production (IPCC, 2018), motivates the research and development of alternative technologies for energy production, which can be more efficient and less polluting.

[04] Furthermore, a large part of the thermal energy generated from the burning of any fuel, fossil or renewable, is wasted when released into the atmosphere in the form of low-temperature thermal energy. The use of this wasted energy and its conversion into another form of energy (mechanical or electrical) has been widely researched and several systems have been developed. Among them, the Organic Rankine cycle (ORC: Organic Rankine Cycle), Kalina cycle, conversion through the thermoelectric effect, motors based on phase change materials (PCM: Phase Change Material engine system) and, as proposed in the utility model described in this report, thermomagnetic motors.

[05] In order to solve the low frequencies found for existing thermomagnetic motors, the developed utility model has a differentiated magnetic circuit, which provides optimized regions of field concentration and a system with a high rate of heat transfer between magnetic material and fluid, which provides greater speed to achieve the magnetic phase transition of the material and consequently, an attraction to the permanent magnet, which gives rise to linear movement in the motor.

[06] Furthermore, the utility model describes equipment that can produce mechanical power or electrical energy using solar energy as a heat source or a cogeneration system using industrial thermal waste. In other words, it is capable of operating without emitting carbon into the atmosphere.

[07] Based on equipment with peculiar characteristics, named here as PURELY MAGNETIC TESLA TYPE MOTOR, research was carried out to verify its effectiveness, as well as the equipment design.

[08] The first stage of this research concerns the design and construction of a magnetic circuit based on double C type permanent magnets composed of several blocks of permanent magnets based on NdFeB. This type of circuit has two high-field regions, which made it possible to build a purely magnetic motor. The circuit design was developed through 2D and 3D models and simulations.

[09] The second stage included the design and construction of the engine, including the magnetic heat exchangers, the pumping system, the selection and purchase of the equipment and instrumentation necessary for its operation and characterization. Next, the engine was built, and subsequently, the engine's static force diagram was characterized. Finally, preliminary dynamic tests were carried out, in which its operating frequency was measured depending on fixed operational parameters, such as temperatures in thermal sources and flow.

[010] The sizing stage of the equipment elements guarantees its adequate functioning, making it possible to establish the technical and economic viability of the Purely Magnetic Tesla Motor.

STATE OF THE TECHNIQUE

[011] Previous searches carried out reveal the existence of patent documents for the purpose of transforming magnetic energy into mechanical energy. However, they were evaluated regarding the difference in design in relation to the proposed utility model.

[012] Document US380100 (PYROMAGNETIC MOTOR) describes a pyromagnetic engine that makes use of a heat source originating from a furnace, that is, the gases arising from the burning of material in the grate circulate through the armature, which has a cylindrical body and is formed by tubes that extend through the armor made of thin plates. With the contact of the tubes and plates, the magnetic transition temperature is reached, causing rotational movement to occur due to the attraction or lack of attraction by a permanent magnet, or as recorded in the document, preferably an electromagnet.

[013] The differences between the model here called Purely Magnetic Tesla Type Motor and the device described in US380100 are in the magnetic circuit. The circuit proposed by the Purely Magnetic Tesla Motor is composed of an arrangement of magnets in double C, which provide two identical magnetic poles with high field intensity and allow a purely magnetic motor, through cylindrical heat exchangers which are in different orderings. magnetic, in addition to having a bed of magnetic particles that provide a rapid phase transition, or Curie Temperature. When this magnetic transition temperature is reached, the exchangers move along a linear guide due to the attraction by the magnetic field, providing movement to the motor, while in the device described in US380100 the magnetic circuit is formed by an armature of thin plates in cylindrical shape and tubes that function as heat exchangers. Furthermore, the Purely Magnetic Tesla Type Motor can generate mechanical energy without carbon production.

[014] In relation to the American document US396121 (THERMO MAGNETIC MOTOR), authored by Nikola Tesla, simple arrangements of a thermomagnetic motor are presented whose operation is based on the magnetic phase transition of a ferromagnetic material. The thermomagnetic engine in US396121 shows that, by employing a heat source H to heat the ferromagnetic material, and placing it between a magnetic field source N and the armature A, it would be possible to generate alternating or rotational movement through the phase transition magnetic of this material. With this, Tesla presented a qualitative solution for obtaining work through magnetic phase transition, using iron as the working material. In addition to this design, others using a spring as a motor drive element are shown in US396121.

[015] The differences are already fundamentally found in the concept of the engines. In US396121, iron is used as a magnetic material, which has a Curie temperature close to 700 °C. The use of high temperatures, however, causes damage to the permanent magnets, in addition to requiring the supply of a large amount of heat to ensure the motor functions. The material used in the Purely Magnetic Tesla Motor can be any material with phase transition, this material being processed in the form of microspheres accommodated as a porous bed in the heat exchangers.

[016] The design of the double-C magnet arrangement of the Purely Magnetic Tesla Type Motor allows for a purely magnetic motor, without the need for the use of a spring to aid in the production of movement. The magnets used in the Purely Magnetic Tesla Motor are made of NdFeB, that is, high energy. In the previous search, document US1839165 (THERMOMAGNETICALLY OPERATED DEVICE) was found, for a motor with continuous movement in only one direction, which has a ring of magnetic material that is pinned and, therefore, free to rotate. It was designed so that a portion of its circumference is under the influence of a magnetic field provided by a permanent magnet. A heat source is applied to the ring close to the magnet, and with the magnetic transition the material has a much lower magnetic attraction when compared to the colder section of the ring. This difference between the magnetic attraction forces provides rotational movement to the motor. When this heated portion moves away from the heat source, it cools down and regains magnetic properties that make it once again attracted to the magnetic field. Also presented is a system for simulating a pyromagnetic arrangement, which comprises a light source, a glass disk with an irregular surface directly covering the light source, a pin to allow rotation of the glass disk that has its convex side to Above, a continuous ring of iron-nickel alloy containing 30-40% nickel attached to the circumference of the glass disc, and a permanent magnet with one of its poles adjacent to a portion of the ring. It also has a coil located in the field of the magnet and adjacent to the ring, and means for supplying current to the coil so that the ring is heated enough to lose its magnetic properties and said glass disk is rotated due to the attraction between the magnet and the coldest portion of the ring.

[017] The differences already begin in relation to the heating processes of the magnetic material, since in US1839165 conditions similar to those of a pyromagnetic engine are simulated by adapting a system with a glass disc and a lamp. In the Purely Magnetic Tesla Motor, the magnetic material is heated by passing hot water through the porous bed made up of magnetic material. Differences are also found in the cooling system of the magnetic material to recover its magnetic properties. In US1839165, a natural regime of temperature drop of the magnetic ring is considered due to displacement to a region distant from the heat source, while, in the Purely Magnetic Tesla Type Motor, the temperature drop in the magnetic material occurs due to the flow of water frozen in direct contact with the particle bed, which allows a rapid magnetic transition.

[018] Application US3445740 (STEP-BY-STEP THERMO-MAGNETC MOTOR) describes a multi-position thermomagnetic motor, with its rotor comprising a structure that provides a group of salient poles. The salient poles are permanent magnets, which are associated with a cylindrical group of magnetizable stator members, each made of an alloy whose magnetic permeability decreases with heating. When all stator members are at room temperature, the rotor has each of its poles associated individually with one of the stator members. Each associated stator member is flanked by two inactive stator members. By heating all members of the stator simultaneously, the rotor is unlocked and free to move in any direction. The rotor has extended radial bars perpendicular to each other. Thermal or electrical energy is imparted to the stator bars. The rotor and stator are coaxially mounted.

[019] The differences presented are that, in US3445740, the movement is generated due to the heating of the metal bars by electrical energy and the rotor, which has protruding poles, ends up not developing magnetic attraction for this heated bar (paramagnetic), moving to the adjacent “inactive” bar with lower temperature (ferromagnetic). In the Purely Magnetic Tesla Motor, linear movement is generated by the attraction of heat exchangers in different magnetic arrangements, each by its respective magnetic pole. Furthermore, the magnetic circuit in US3445740 is formed by a rotor with protruding poles, magnetic material busbars and heating using electrical energy, while, in the Purely Magnetic Tesla Type Motor, there is a magnetic circuit composed of permanent magnets. of NdFeB in double C configuration.

[020] In US3743866 (ROTARY CURE POINT MAGNETIC ENGINE), a rotary magnetic motor is described that uses gadolinium, a material with magnetic transition around room temperature, to distort the magnetic field flux lines and thus cause relative movement between a rotor and a stator. Magnets are mounted on the rotor and stator, and the gadolinium is arranged in the form of blades spaced between the poles of certain magnets with channels formed between these blades to direct the flow of a refrigerant fluid. An electrical circuit is used to intermittently induce an electrical current through the blades, increasing the temperature until the magnetic transition stops being attracted by the magnet and allowing movement to begin. Subsequently, the electrical circuit is opened to allow the coolant to cool the blades below the Curie Temperature so that the flow lines are captured by the flow distortion devices.

[021] The machines differ in engine concepts. In US3743866, there are gadolinium blades heated by an electrical circuit and attracted by permanent magnets arranged around the rotor and stator. In the Purely Magnetic Tesla Motor, a magnetic circuit with a double C magnet configuration is used, with two identical magnetic poles, which promote the attraction of the magnetic material when cooled by a flow of ice water, and reduce magnetic attraction. when a flow of hot water passes through the porous bed of this material, causing heat exchangers in different magnetic arrangements to move along the linear guide.

[022] The previous search also found document US 4730137 (ENERGY CONVERSION SYSTEM), which presents a machine for transforming magnetic energy into mechanical energy. The motor comprises two structures, a rotor (insulating fiberglass or epoxy material) and a fixed support. The magnetic material is coupled to the rotor, which is mounted on a shaft with a bearing. The material is shaped like a rim, which can be continuous or spaced around the rotor. The magnet is mounted on the fixed support, and has a north pole located close to the surface of the rotor, so that the magnetic material rotates with the proximity of the magnetic pole. The heating (a flame, solar energy with the aid of lenses) is carried out locally in the material so that a decrease in magnetic attraction occurs, which will result in rotation in the mobile structure due to the attraction of the portion of magnetic material in the cooled region, producing so the moment. The magnetic material passes through a heat exchanger and loses temperature, becoming attracted to the magnet again.

[023] The differences are found in the engine ideas. In US4730137, a ring-shaped magnetic material attached to the rotor is disclosed. Localized heating promotes its movement due to the absence of magnetic attraction of the hot portion. Subsequently, it reaches a stationary heat exchanger, which reduces the temperature of the magnetic material ring, causing it to be attracted to the permanent magnet again. In the case of the Purely Magnetic Tesla Motor, there is an arrangement of NdFeB permanent magnets in double C, and two porous bed heat exchangers composed of magnetic material in different magnetic orderings, with thermal exchange by forced convection due to the passage of liquid (sometimes cold, sometimes hot) which changes the magnetic properties of the material, causing it to be attracted or not to its respective magnetic pole, providing an alternating movement.

[024] In previous searches, document US008242662B2 (SPECIAL THERMO MAGNETIC MOTOR DEVICE) was also found, which describes a device that is composed of a base, a heating system to heat the magnetic pads above the Curie temperature, a system magnetic with a base and a short circuit bar, a rotating disc assembly with magnetic pads and a shaft with output for different types of mechanisms for transforming rotary movement into linear movement.

[025] The difference appears in the concept of machines. In US00824266B2, there is localized heating by flames from magnetic tablets coupled to a disc. As the magnetic material heats up, it becomes paramagnetic and is no longer attracted to the magnet, giving rise to movement due to the attraction of the pads at lower temperatures (ferromagnetic). The reduction in temperature and consequent restoration of magnetic properties occurs due to displacement to positions far from the heat source. In the Purely Magnetic Tesla Motor, thermal exchange is carried out forcedly by the flow of fluid that comes into direct contact with a bed of microparticles of magnetic material. The configuration of the magnets is also different, as in the Purely Magnetic Tesla Type Motor there is a double C configuration, which provides two identical magnetic poles with high field intensity, whereas, in US00824266B2, only one magnetic pole region is develops.

[026] The document US008304957B2 (THERMOMAGNETIC GENERATOR DEVICE AND ENERGY CONVERTING METHOD) was also highlighted in the search for priors, which deals with a generator to convert thermal energy into electrical energy. The magnetic circuit includes at least one portion composed of a magnetic material. A temperature variation device modifies the temperature in the portion of magnetic material to thus change the reluctance of the magnetic circuit. A coil is mounted around the magnetic circuit, and electrical energy is induced in response to a changing magnetic flux in the magnetic circuit.

[027] The differences are already found in the fundamental principle. In US008304957B2, the generation of electrical energy is done directly, which is achieved as a response to the change in the magnetic reluctance of the circuit due to the heating of the magnetic material. For the Purely Magnetic Tesla Motor, there is the conversion of magnetic energy into mechanical energy, with mechanical energy coming from the linear displacement of the heat exchangers in different magnetic arrangements, due to the attraction of the particles that make up the bed, each of which interacts with their respective magnetic pole.

[028] In US008754569B2 (THERMO-MAGNETIC POWER GENERATION SYSTEM), another document found during previous searches, an energy generating device is presented consisting of a thermomagnetic component and a hot and cold water circulation system that are reused by the system .

[029] The differences are already found in the engine concept. In US008754569B2, there are portions of a thermomagnetic material, solid blocks that will be alternately heated or cooled by liquids coming from hot or cold sources. In this way, the regions have different working temperatures and the liquid flow occurs through channels present in the magnetic segments. For US008754569B2, the sources of the magnetic fields are permanent magnets, solenoids or a set of these. This device appears with the concept of parts of a cylinder. In the case of the Purely Magnetic Tesla Motor, mechanical energy is generated through alternating movement in the motor due to the magnetic transition of the porous magnetic material present in the heat exchangers through direct contact with the fluid forcedly flowed by a pump. For the Purely Magnetic Tesla Type Motor, the magnetic field is provided by a double-C magnet configuration.

[030] Still in the search for precedents, document BR102012012824-1 A2 (ROTATING THERMOMAGNETIC DEVICE AND USE THEREOF) was found, which basically consists of magnets in the shape of rectangular parallelepipeds that are fixed to a movable cylindrical table (attempts to form a cylindrical Halbach), which in turn is coupled to a shaft. This set of magnets and shaft form the rotor of the thermomagnetic motor. Furthermore, it is composed of magnetic plates that form cylindrical sectors separated by 120° and remain stationary, forming the motor stator. The rotor is made up of 6 plates of magnetic material in the shape of a circular sector and with internal channels for circulation of the working fluid. The motor can be constructed with multiple inner and outer layers of magnet arrays.

[031] The difference is basically in their conceptions, since in BR102012012824-1 A2, there is a movable cylindrical table composed of magnetic plates with cylindrical sectors and the fluid passes through these plates through channels. The stator is formed by stationary magnetic plates with 120° phase shift. In turn, in the Purely Magnetic Tesla Motor, there is linear displacement, in a guide, of the two heat exchangers, these being cylindrical containers with porous beds of magnetic particles. Another difference is noted in the arrangement of the magnets, as in BR102012012824-1 A2 there is a cylindrical Halbach arrangement, whereas, in the Tesla Type Magnetic Motor, this arrangement is in double C.

[032] In the search for precedents, document BR102012012822-5 A2 (LINEAR RECIPROCATIVE THERMOMAGNETIC DEVICE AND USE THEREOF) was found, which basically consists of heat exchanger plates, which are kept stationary together with magnets that are fixed to a table which has linear relative movement in relation to the heat exchanger plates. The plates have internal cavities or channels for thermal exchange and function as heat exchangers between the fluid and the plate material. There is also a connecting rod-crank mechanism at the end for converting linear movement into rotational movement, attached to the table, and the crank serves as a flywheel. The permanent magnets have a linear Halbach configuration and act on stationary plates of magnetic material that promote reciprocal movement of the magnets coupled to the linear table.

[033] The primary difference is present in the engine concept. In BR102012012822-5 A2, the heat exchanger is composed of magnetic material in the form of plates with channels for the passage of the operating fluid. The heat exchange system is stationary, while the table moves linearly with the set of magnets in linear Halbach configuration and the transformation from linear to rotary movement is carried out by a connecting rod-crank mechanism. In the Purely Magnetic Tesla Motor, the set of magnets is in a double-C configuration, stationary, attached to the structure, while the operating fluid passes through the particle bed that makes up the cylindrical-shaped heat exchanger system. different magnetic arrangements that move on linear guides. In the Purely Magnetic Tesla Motor, the conversion from linear to rotary movement is carried out using a system called ratchet.

[034] The search for anteriority also revealed non-patent references. The works of STAUSS, H. (1959) and ELLIOTT, J. (1959) present a thermomagnetic generator that can be represented by a sample or "working body" between the poles of a permanent magnet. The body is alternately magnetized and demagnetized by a heating/cooling cycle operating around the Curie temperature. The resulting change in flux gives rise to a voltage in a coil wound around the body. These authors already had permanent magnets with better properties available, such as Alnico alloys, and used gadolinium as a magnetic material. The differences between what was revealed by the authors and the Purely Magnetic Tesla Type Motor reside in the fact that the thermomagnetic generator has the simple design of an energy generator with a coil wound to the magnetic material with heating and cooling of it to change the magnetic reluctance for generation. of voltage, whereas the Purely Magnetic Tesla Motor has an optimized magnetic circuit of the Purely Magnetic Tesla Motor, in heat exchange at high rates from the magnetic heat exchanger with porous bed. Thus, the proposed model has the advantage of increasing the operating frequency through the use of porous bed magnetic heat exchangers. Magnetic Circuit with two identical poles with high field intensity.

[035] The work of MURAKAMI, K.; NEMOTO, M. (1972) presents a device consisting of a rotor and a stator, in the same way as a common electric motor. The rotor is made of acrylic resin plate and its radius is 250 mm. On the circumference of the rotor, 65 temperature-sensitive magnetic parts (2 x 4.5 x 20 mm) are mounted with thin brass pins. The Curie temperature of magnetic parts is approximately 50°C. On four of the temperature-sensitive magnetic parts, arranged at equal intervals, thermocouples were fixed and rotor temperature measurement was carried out. The differences are found in the optimized magnetic circuit of the Purely Magnetic Tesla Motor, which produces two identical magnetic poles with high field intensity, in heat exchange at high rates from the magnetic heat exchanger with a porous bed, providing an increase in frequency.

[036] KARLE, A. (2001) modeled and simulated the operation of a Curie wheel using Alnico as a permanent magnet and a 30% NiFe alloy (commercially known as thermoflux) as magnetic material, which has Tc around 90°C. Karle's proposal also included the use of solar radiation as a source of hot heat. The designed engine was considered economically unfeasible, since both the mechanical energy produced and the efficiency found were low. Therefore, a large engine would be needed to produce useful mechanical power values, which would increase the costs of this machine. The proposed work was numerical. The differences are found in the optimized magnetic circuit of the Purely Magnetic Tesla Motor, which produces two identical magnetic poles with high field intensity, in heat exchange at high rates from the magnetic heat exchanger with a porous bed, providing an increase in frequency.

[037] The authors TAKAHASHI, Y.; YAMAMOTO, K.; NISHIKAWA, M. (2006) again based on the Curie wheel, they modeled and built a motor that had three NdFeB permanent magnets around its rotor. In this system, water at temperatures of 95°C and 11°C were used in hot and cold sources, respectively. The authors were able to generate a net power of 3.7 W operating at a frequency of 0.4 rps. The total power produced was 5.4 W, however 1.7 W was lost due to friction and electromagnetic braking in the Rotor. The differences are found in the optimized magnetic circuit of the Purely Magnetic Tesla Motor, which produces two identical magnetic poles with high field intensity, in heat exchange at high rates from the magnetic heat exchanger with a porous bed, providing an increase in frequency.

[038] UJIHARA, M.; CARMAN, G.; LEE, D. (2007) built a small tesla motor (dimensions of 20x20x60mm) with spring return, which used Gd as magnetic material and NdFeB magnets. The author concluded that the proposed engine could work with a temperature gradient of 10 K between the hot and cold sources. Comparing this engine with a thermoelectric generator, which used the Seebeck effect and could generate energy from a temperature gradient in the range < 100 K for the same temperature gradient, the author concluded through simulations that the proposed Tesla engine it would achieve considerably greater efficiency than thermoelectric generators, producing between 18.5 and 36.1 mW/cm2 compared to the 12 mW/cm2 of the thermoelectric system. The differences are found in the optimized magnetic circuit of the Purely Magnetic Tesla Motor, which produces two identical magnetic poles with high field intensity, in the exchange of heat at high rates from the magnetic heat exchanger with a porous bed, providing an increase in frequency, production of energy without carbon generation with purely magnetic motor.

[039] The article written by IWASAKI, N.; KITAMURA, H.; KITAMURA, M.; NAKATSUGAWA, J.; WNOMOTO, Y. (2013) reports the results of the miniaturization project of a permanent magnet synchronous motor, for which a design technique based on thermomagnetic field coupling analysis is used. This article reports the results of the miniaturization project of a permanent magnet synchronous motor, for which a design technique based on thermomagnetic field coupling analysis is used. Motor composed of a rotor and a stator, the rotor with permanent magnets and the stator with hot or cold fluid flow passing through spaces present in the stator geometry. The differences are found in the optimized magnetic circuit of the Purely Magnetic Tesla Motor, which produces two identical magnetic poles with high field intensity, in the exchange of heat at high rates from the magnetic heat exchanger with a porous bed, providing an increase in frequency, production of energy without carbon generation.

[040] FERREIRA, L. D. R.; BESSA, C.V.X.; GAMA, S. DA SILVA (2014) studied different stationary heat exchangers using microchannels. Different arrangements are simulated by the author using a CFD tool. The primary difference with the article is the use of a porous bed, providing higher thermal exchange rates than any exchanger arrangement with microchannels.

[041] ALVES, C. S.; COLMAN, F.C.; FOLEISS, G. L.; SZPAK, W.; VIEIRA, G. T. F. (2013) and ALVES, C. S., COLMAN, F. C., FOLEISS, G. L., SZPAK, W., VIEIRA, G. T. F., BENTO, A. C. (2014) modeled and simulated the operation of a Curie engine using solar energy as a source of heat. The authors also designed the engine components, determining the geometry necessary to focus the sun's rays. The operation simulation was carried out considering three different materials: the 30% FeNi alloy, the gadolinium element (Gd) and the MnAs alloy. The performance analysis was carried out by comparing the results obtained with these materials, with greater power being observed using MnAs as the rotor material. The differences are found in the optimized magnetic circuit of the Purely Magnetic Tesla Motor, which produces two identical magnetic poles with high field intensity, in heat exchange at high rates from the magnetic heat exchanger with a porous bed, providing an increase in frequency.

[042] The authors TRAPANESE, M.; CIPRIANI, G.; DI DIO, V.; FRAZNITTA, V.; VIOLA, A. (2015) studied the optimization of a Curie wheel using CFD. The machine's rotor was built by inserting a Gd alloy inside the tube. Hot and cold spots were obtained using hot and cold air. The stator had magnets producing the magnetic field. The differences are found in the optimized magnetic circuit of the Purely Magnetic Tesla Motor, which produces two identical magnetic poles with high field intensity, in heat exchange at high rates from the magnetic heat exchanger with a porous bed, providing an increase in frequency.

[043] IWASAKI, N.; KITAMURA, H.; KITAMURA, M..; ENOMOTO, Y. (2016) designed a magnetic gear motor using coupled thermomagnetic analysis. Since iron loss increases as engine speed increases, design values balance the increase in torque density with the reduction in core iron loss. The motor corresponds to a simple arrangement of rotor and stator, with coupled magnetic gear. The differences are found in the optimized magnetic circuit of the Purely Magnetic Tesla Motor, which produces two identical magnetic poles with high field intensity, in heat exchange at high rates from the magnetic heat exchanger with a porous bed, providing an increase in frequency.

[044] In turn, BESSA, C. V.X.; FERREIRA, L. D. R; HORIKAWA, O.; MONTEIRO, J. C. B.; GAMA, S. (2017) carried out a numerical study of thermal hysteresis in thermomagnetic motors. They concluded that this thermal hysteresis increases the separation between the heating and cooling curves in the temperature-entropy diagram. As a consequence, thermomagnetic motors using magnetic materials with large thermal hysteresis show greater specific work than motors using materials with narrow or zero thermal hysteresis. If the hysteresis is large, a significant amount of thermal energy is accumulated in the material before the ferromagnetic to paramagnetic transition, and some of this thermal energy is converted into work. In this case, the storage of high thermal energy implies a high production of work. The large thermal hysteresis also allows the application of thermomagnetic motors in conditions of greater temperature differences, with greater energy density without affecting the efficiency relative to the Carnot efficiency when compared to motors using second-order magnetic transitions and narrow thermal hysteresis materials. Theoretical work without presenting an engine concept. The Purely Magnetic Motor works with any magnetic material with first or second order transition.

[045] Work at a conference requested by patent BR 102012 012822-5 A2 (LINEAR RECIPROCATIVE THERMOMAGNETIC DEVICE AND USE THEREOF) which cites a hot thermal source such as sunlight and a cold source, air as ambient temperature. Magnetic material is Gadolinium and NdFeB magnet. The differences are found in the optimized magnetic circuit of the Purely Magnetic Tesla Motor, which produces two identical magnetic poles with high field intensity, in heat exchange at high rates from the magnetic heat exchanger with a porous bed, providing an increase in frequency.

ADVANTAGES OF THE INVENTION

[046] In general, the Purely Magnetic Tesla Motor presents advantages in relation to previous inventions, as it allows a marked thermal exchange between magnetic material and operating fluid, which provides a rapid transition of magnetic state, thus promoting high frequencies to the motor. Furthermore, it has the capacity to reuse the working fluid, each one returning to its respective storage tank. The heating of the working fluid from the hot source can be carried out by any industrial waste thermal source.

[047] The purpose of the Purely Magnetic Tesla Motor is to allow magnetic energy to be transformed into mechanical energy.

[048] In this way, this invention allows: • energy transformation by means of a purely magnetic motor, without the presence of springs, or gravity to aid the movement; • the use of two identical poles with high magnetic field intensity; • high heat transfer rate between magnetic material (porous bed) and operating fluid; • transformation of linear movement into rotary movement by the ratchet mechanism; • provide high engine working frequencies.

BRIEF DESCRIPTION OF FIGURES

[049] For a better understanding of the object of this utility model patent application, references will be made to the attached drawings, in which: • FIGURE 1 shows the schematic drawing of the thermomagnetic motor and its components; • FIGURE 2 shows the Coupler; • FIGURE 3 illustrates the components of the magnetic heat exchanger; • FIGURE 4 shows the double C magnetic circuit and its components; • FIGURE 5 shows an exploded view of the magnetic motor without the movement conversion mechanism coupling; • FIGURE 6 illustrates the mechanism for transforming linear movement into rotational; • FIGURE 7 shows the magnetic motor with its mechanism for converting linear to rotational motion.

DETAILED DESCRIPTION OF THE INVENTION

[050] The text that follows elucidates the equipment design phase, divided between Main Engine Components/Operation and Equipment Development.

[051] The thermomagnetic motor has as its main components the magnetic circuit (2), the heat exchanger composed of the magnetic material (called magnetic heat exchanger or TCM) (3), pumps (17), a source (18) and a heat sink (19) and measuring instruments: flow transducer (20), thermocouples (21), solenoids (22) and position sensors (23). The heat source (18) can use solar energy or a cogeneration system by taking advantage of industrial thermal waste, combustion gases or steam waste with operating temperatures of up to 150 °C. The heat sink (19) can operate with any working fluid with temperatures between 0 and 40 °C. Both working fluids circulate through the magnetic heat exchangers (3) through the pumps (17) of the pumping system (17), (FIGURE 1).

[052] The pumping system has a flow rate regulated by a bypass. The pumps (17) are connected to the hot and cold flow distribution system. The distribution system consists of solenoid valves (22) activated by position sensors (23). Such sensors send a signal to the solenoids indicating whether the respective TCM (3) is in the low or high field region, and thus directs the cold or hot flow, respectively. In this way, the set of position sensors and solenoids is what guarantees synchronism between the magnetic cycle and the flows. The instrumentation is basically composed of thermocouples (21), located at different points of the engine. The flow is measured by two volumetric flow transducers (20). The flow transducers are positioned at the outlet of the circulation pumps. By using the by-pass, the volumetric flow rate used in the engine can be varied, which will be readily measured by the flow transducers (FIGURE 1). Finally, load cells are used to evaluate the force produced by the engine. The data acquisition system consists of a microcontroller (hardware) and software. The system reads temperature data from thermocouples (21), volumetric flow from flow transducers (20) and position (23) from TCMs (3) and thus controls the entry and exit of hot and cold flows from the closing and opening solenoid valves connected to it. This system is also responsible for interpreting the results obtained by the load cells converting electrical signals into force (FIGURE 1).

[053] The Equipment Development stage will be divided into its main components: 1. Magnetic heat exchanger (TCM); 2. Pumping system; 3. Magnetic Circuit.

[054] The magnetic heat exchanger (3), in an analogy with a conventional engine, acts as a piston. TCM (3) is a porous medium composed of magnetic material processed into microspheres housed in a housing. A porous medium with low porosity, in general, has a high heat transfer surface area, which increases heat transfer rates, and consequently, the engine operating frequency.

[055] In the heat exchanger, a fixed bed of compacted spheres of any magnetic material with first or second order phase transition is used, with a Curie temperature between 20 and 80°C. The spheres have a diameter of less than 1000 microns and are packaged in a G10 fiberglass tube. The bed is kept compacted through the use of couplers (24) ensuring a porosity between 36 and 37%, (FIGURE 2).

[056] The connection between the couplers (24) and the piping that distributes the hot and cold flows is made by quick couplings. A stainless steel U-shaped adapter (25) connects the magnetic heat exchanger (TCM) structure to the linear guides. The latter ensures that the TCM, when interacting with the applied field, moves only along the x-axis, with low friction, and does not move in other directions. If the TCM has even a small displacement on the y-axis, this may result in obstructions to the linear movement on the x-axis, or the TCM may come into contact with one of the faces of the magnetic pole and generate friction. The heat exchanger structure includes U-shaped adapters (25) at the ends for fixing to linear guides, the G10 tube (26) where the magnetic material balls are packaged, couplers (24) and quick couplers (27) , (FIGURE 3).

[057] The pumping system for heating and cooling the TCM (3) consists of hoses with thermal insulation made of elastomeric rubber, quick-connect connections and solenoid valves.

[058] The design and assembly procedure of the magnetic circuit were adapted from the work of Schafer (SCHAFER, B. Development of a magnetocaloric test apparatus. Dissertação (Mestrado) - Universitat der Bundeswehr München, Neubiberg, August 2016.). The designed magnetic circuit has a double-C configuration, and is an association of blocks of NdFeB permanent magnets (28), where the white arrows indicate the direction of remanence. To close the circuit and guide the magnetic flux lines between the two magnetic poles, a soft ferromagnetic material with high relative permeability (μr), such as Fe, FeCo or steel alloys, is used. (29). The regions of paramagnetic materials (30) have a structural function (FIGURE 4).

[059] The present model uses three different types of permanent magnet blocks, which are used for different purposes, and are named as follows: • Main Magnets; • Lateral Concentrators; • Front concentrators.

[060] The Main Magnets are positioned in the center of the magnetic pole and are responsible for generating the magnetic field in a main direction and in a specific volume. Concentrating magnets (side and front) are used to reduce edge effects, and thus guarantee a more intense and homogeneous magnetic field in the generated field volume.

[061] In the final design of the double C magnetic circuit, it is possible to check the holes and other structural details. An interesting feature included in the design of the magnetic circuit (2) is the possibility of changing the magnetic gap using adjustment screws (31). While the magnets on the lower base (32) are fixed, the upper base (1) can be moved up and down, consequently varying the intensity of the magnetic flux. The magnetic heat exchanger system (3) moves in linear guides (4) due to the attraction by the field generated in the magnetic circuit (2), (FIGURE 5).

[062] To transform linear movement into rotational movement to produce momentum, a ratchet mechanism is used, adjusted on a base (5). Attached to this base are two leveling supports (6) for the bearings (7), through which the shaft (8) passes. The bearings are supported by a bushing (13). The movement is generated due to the mechanism, which has a structure that moves linearly, consisting of a side plate (9), an elongated bar (10) that is connected to the short bar (11) and the lock (12). The bearings (14) are used to couple the long bar to the actuator cylinder (15). The linear movement is then converted into rotational by the contact of the locks (12) with the gear teeth (16), (FIGURE 6).

[063] The complete set, motor and its mechanism (FIGURE 7), is capable of transforming magnetic energy into momentum, taking advantage of the accentuated thermal exchange between magnetic material and operating fluid, which provides a rapid transition of magnetic state, causing thus an increase in motor frequency.

Claims (1)

1) PURELY MAGNETIC TESLA TYPE MOTOR, characterized by being made up of (1) upper base, (2) magnetic circuit, (3) magnetic heat exchanger, (4) linear guides, (5) base of the movement conversion mechanism , (6) leveling supports, (7) rolling bearings, (8) shaft, (9) side plate, (10) elongated bar, (11) short bar, (12) mechanism lock, (13) bushing, ( 14) bearing, (15) actuator cylinder, (16) gear, (17) pump, (18) heat source, (19) heat sink, (20) flow transducer, (21) thermocouples, (22) solenoids , (23) position sensors, (24) couplers, (25) U-adapters, (26) G10 glass tube, (27) quick coupler, (28) permanent magnets, (29) soft ferromagnetic material, (30) paramagnetic material, (31) magnetic gap adjustment screws, (32) fixed base.