BR102015020792A2 - device and process for electric motor rotor magnetization - Google Patents

Abstract

abstract device and process for electric motor rotor magnetization The present invention is situated in the fields of electrical engineering and electric motors, disclosing a device and process for electric motor rotor magnetization. Specifically, the device of the present invention comprises: a rotor housing seat; one or more sets of external coils (12) comprising magnetizing coils (22a) and protective coils (22b); and one or more sets of internal coils (13). The device of the invention provides a method for increasing the magnetic saturation level of the rotor components, which thus operates more efficiently.

Description

Invention Patent Description Report Electric Motor Rotor Magnetizing Device and Process Field of the Invention [0001] This report contains confidential knowledge, information and / or data usable in industry, commerce or the provision of services for which the holder requires it. : the protection established in item XXIX of Article 5 of the Federal Constitution; maintaining legal status of confidentiality / secrecy; the maintenance of the physical status of confidentiality / secrecy for the time provided for in Law 9.279 / 96, Industrial Property Law; and the rights provided for in Article 195 of Law 9,279 / 96.

The industrial creation described herein comprises a patent-protected invention. The present invention is in the fields of electrical engineering and electric motors. More specifically, the present invention describes a device and method for magnetizing electric motor rotors. The device and process of the invention are useful for increasing the rotor magnetic saturation level, providing greater efficiency of the motor containing said rotor.

Background of the Invention Various types of equipment utilize electric motors. These motors obey the effects of magnetism, including applied and induced magnetic field, so that they can perform the mechanical movement of rotation.

[0004] The electric motor is basically composed of two parts, a stator and a rotor. The stator is the fixed part responsible for applying a magnetic field; The rotor is the moving part that, through the applied field, makes the movement. The rotor comprises a means for generating magnetic field, which may be of permanent magnet or of materials which, with the application of an external magnetic field, acquire the magnetic characteristics.

[0005] A commonly adopted method for rotor magnetization is to apply the field through the electric motor stator itself. However, this method is disadvantageous due to the fact that the rotor magnetic block, or magnet, of the rotor is not completely saturated, presenting regions with low magnetization index, which implies in a motor with reduced efficiency. The present invention provides a solution to these problems.

From what can be seen from the researched literature, no documents were found anticipating or suggesting the teachings of the present invention, so that the solution proposed here has, in the eyes of the inventors, novelty and inventive activity in relation to the state of the art.

Summary of the Invention The present invention aims to solve the constant problems in the state of the art from a device for the magnetization of the electric motor rotor that provides the saturation increase of the magnetic blocks that compose the rotor.

[0008] The inventive concept common to all claimed protection contexts is the use of a rotor magnetization device, in which the rotor is magnetized due to the cooperative application of an external magnetic field and an internal magnetic field, increasing magnetic saturation. of rotor blocks.

In a first object, the present invention provides a device for magnetizing the electric motor rotor comprising: - a seat (11) for temporary housing of a shaftless rotor, said seat comprising; - one or more coil (s) (12) in its inner peripheral region so that it is positioned externally with respect to the rotor when it is housed in said seat; and - one or more coil (s) (13) in its central region, so that it is internally positioned (s) relative to the rotor when it is housed in said seat.

In one embodiment of the invention, the external coil assembly (42) includes magnetization (42a) and protective (42b) coils to provide radial magnetic field application to the rotor, magnetization coils (42a) and the inner coil assembly (43) acting cooperatively to increase the internal magnetic saturation of the rotor magnetic blocks (44).

In one embodiment of the invention, the outer coil assembly (42) comprises magnetizing coil pairs (42a) and protective coil pairs (42b).

In a second object, the present invention provides a process for magnetizing the electric motor rotor comprising the steps of: - temporarily housing a shaftless rotor in a seat (11) comprising: - one or more coil (s) (12) positioned (s) externally to said rotor; and - one or more coil (s) (13) in its central region, positioned internally with respect to said rotor; and - drive the outer coils and inner coils so that they cooperatively provide elevation of the rotor block saturation level.

[0013] In one embodiment of the invention, the process of the invention comprises the steps of: - temporarily housing a shaftless rotor in a seat (11) comprising: - a set of magnetizing coils (42a) positioned externally to said rotor; - a set of protective coils (42b) positioned externally to said rotor; and - one or more coil (s) (43) in its central region, internally positioned (s) relative to said rotor; and - drive the coils so that: the internal and external magnetization cooperatively provide elevation of the rotor block saturation level; and the protective ones prevent a magnetic field inverse from the rotor magnetization field from being applied and reduce magnetization or degauss the rotor.

[0014] These and other objects of the invention will be immediately appreciated by those skilled in the art and companies having an interest in the segment, and will be described in sufficient detail for reproduction in the following description.

Brief Description of the Figures In order to further define and clarify the contents of the present patent application, the following figures are presented: Figure 1 shows a top view of a device embodiment of the invention, indicating: 11, headquarters; 12, eight poles where are the external coils; 13, the location of the inner coil (s).

Figure 2 shows an embodiment of device of the present invention, in which A shows a 6/8 V-shape permanent magnet rotor; and in B the device of the invention with said rotor housed in the seat. Also indicated are: 22, the locations are the external coils; 23 the location of the inner coil (s); and 24, rotor blocks.

Figure 3 shows a top view of a schematic representation of another device embodiment of the invention, in which a BLAC 6/8 type motor used in the tests for comparison of results is housed.

Figure 4 shows another embodiment of device of the invention in which a rotor is housed. 42a, external magnetizing coils are indicated; 42b, external protective coils; 43 inner coils; and 44, rotor blocks.

[0020] Figure 5 shows the results of magnetic field effect tests applied by external magnetization (52a) and protective (52b) coils in a device devoid of internal coil (s). Note that the internal parts of the rotor block 54 have a low level of magnetic saturation.

Figure 6 shows a graph of the results obtained from the magnetic induction along the rotor block with the application of the magnetic field from the external magnetization coils (without internal coils). The horizontal axis shows the position in mm and the vertical axis the T induction.

Figure 7 shows the results of tests of the effect of the magnetic field applied by external magnetization (72a) and protective (72b) coils in the device of the invention provided with internal coils (73). Note that the internal parts of the rotor block 74 have a high level of magnetic saturation.

Figure 8 shows a graph of the results obtained with the effect of the magnetic field coming from the internal coils in the rotor block (44). The horizontal axis shows the position in mm and the vertical axis the T induction.

Figure 9 shows a graph of the results obtained with the effect of the magnetic field from the internal coils in the rotor block (44). The horizontal axis shows the position in mm and the vertical axis the T induction.

Figure 10 shows an electrical circuit used to drive the magnetization device of an embodiment of the present invention.

Figure 11 shows the load curves of the capacitor used in the circuit during magnetization.

[0027] Figure 12 shows an interconnection diagram of equipment used to perform degaussing tests.

[0028] Figure 13 shows the results of the demagnetization tests detailing the effective value of the time domain electromotive force for 2000RPM.

Figure 14 shows the results of the demagnetization tests with a larger view to detail the current levels used in the tests.

[0030] Figure 15 shows a graph of the demagnetization test results, detailing the demagnetization percentage as a function of the applied current.

Figure 16 shows a first view of an embodiment of the device of the present invention containing four external coils, two magnetizing coils and two protection coils, in which the seat is without rotor.

Figure 17 shows a second view of an embodiment of the device of the present invention containing four external coils, two magnetizing coils and two protection coils, in which the seat has housed an 8-pole rotor.

Detailed Description of the Invention The following descriptions are given by way of example and should not be construed as limiting the scope of the invention and are useful in understanding more clearly the subject matter of the present patent application.

The present invention discloses a device for magnetizing the electric motor rotor comprising: - a seat (11) for temporary housing of a shaftless rotor, said seat comprising; - one or more coil (s) (12) in its inner peripheral region so that it is positioned externally with respect to the rotor when it is housed in said seat; and - one or more coil (s) (13) in its central region, so that it is internally positioned (s) relative to the rotor when it is housed in said seat.

In one embodiment of the invention, the external coil assembly (42) includes magnetization (42a) and protective (42b) coils to provide radial magnetic field application to the rotor, magnetization coils (42a) and the inner coil assembly (43) acting cooperatively to increase the internal magnetic saturation of the rotor magnetic blocks (44).

As shown in Figure 5, the magnetic blocks (54) are subjected to the magnetic field applied by the magnetization coils (52a). The magnetic blocks (54a) are the blocks being magnetized, the magnetic blocks (54b) are the blocks that are not demagnetized at the instant of time due to the protective coils (52b). Figure 5 also illustrates the magnetic field lines incident on the device of the invention in operating mode.

As can be seen from Figure 5, the magnetic blocks 54a being magnetized are not completely saturated, having a portion with a saturation level below 0.9 T (Tesla), which is the minimum. induced magnetic field required to saturate the magnetic block (54a), the saturation level being 0.9 T, twice the remaining induction of the magnetic block. Figure 6 presents a more detailed graph showing the effect where, in one region of the magnetic block (54a) is subjected to an induction above 0.9 T, another region is subjected to an induction below 0.9 T T needed.

[0038] Figure 7 shows the result where the inner coil assembly (73) applies a magnetic field to the rotor to be added to the field applied by the external magnetizing coil assembly (72a). Thus, the rotor magnetization is carried out cooperatively implying an increase in the internal magnetic saturation of the said rotor magnetic block.

The field generated by the set of internal coils (73) is produced by applying a DC current. Thus, the internal coils 73 are of the magnetization coils type.

In one embodiment, the protective coils 72b are arranged to prevent a magnetic field inverse from the rotor magnetization field from being applied and to reduce and even degauss the rotor. In this embodiment, the protective coils 72b prevent magnetization in the opposite direction to the rotor magnetization and / or prevent demagnetization thereof.

In said embodiment, the amount of magnetizing coils (72a) in the outer coil assembly (72) is equal to the number of protective coils (72b). Figure 4 illustrates a rotor embodiment in the invention containing eight poles and four external coils (42), two of which are magnetization coils (42a) and two protective coils (42b).

Figure 8 presents a graph with the curves obtained from the magnetization of the magnetic block 74a, where it is noticeable that throughout the magnetic block 74a the induction level is above 0.9 T Figure 9 shows a graph reporting the induction level in the magnetic block 74b showing that most of the magnetic block is protected from demagnetization.

In one embodiment, the magnetic blocks 74 are magnets.

In one embodiment of the invention, the process of the invention comprises the steps of: temporarily housing a shaftless rotor in a seat (11) comprising: - a set of magnetizing coils (42a) positioned externally to said rotor; - a set of protective coils (42b) positioned externally to said rotor; and - one or more coil (s) (43) in its central region, internally positioned (s) relative to said rotor; and - drive the coils so that: the internal and external magnetization cooperatively provide elevation of the rotor block saturation level; and the protective ones prevent a magnetic field inverse from the rotor magnetization field from being applied and reduce magnetization or degauss the rotor.

In one embodiment, the rotor magnetization process of the present invention, controlled by the electrical circuit shown in Figure 10. Said circuit comprises: a capacitor C = 11.3mF; an inductor L = 108μΗ; a resistor R = 25mQ; being applied a voltage of 300V. The capacitor current, voltage and power curves are shown in figure 11, where VM1 are the voltage curves, AM1 are the current curves and PM1 are the power curves.

To evaluate the effect of motor degaussing when it goes into operation, rotor degaussing tests were performed with the presented device. For the demagnetization test, the circuit / diagram shown in figure 12 was assembled, and the following steps were performed: 1) magnetizing the magnetic blocks (44) with 100% of their potential to reach the highest possible induction level; 2) insert the magnetic blocks (44) into the rotor and perform the rotor + stator assembly on the dynamometer; 3) check the induced reference voltage, saving the waveform to make the comparison; 4) inject a DC current into the motor windings; 5) rotating the motor several times to induce a negative magnetic field in the magnetic blocks (44); 6) recheck the induced voltage, saving the waveform; 7) increase the DC current and return to step 5) until the effective value of the electromotive force is 20% below the reference level.

In a demagnetization test, the current was varied from 1A to 12A, to the point where the effective electromotive force dropped by 80% of the reference. Figures 13 and 14 show the demagnetization curves with the different levels of applied electric current, represented with voltage as a function of time. Figure 15 shows the effective electromotive force curve as a function of the applied current. Analysis of the three graphs shows that the maximum peak current to avoid a demagnetization level greater than 5% is 6A. Thus, it is concluded that the maximum effective current value that prevents demagnetization greater than 5% is 4A.

Those skilled in the art will enhance the knowledge presented herein and may reproduce the invention in the embodiments disclosed and in other embodiments within the scope of the appended claims.

Claims

Claims (7)

1. The protection, under item XXIX of article 5 of the federal constitution, of industrial creation characterized by being substantially as described on pages 1 to 9 of this report, summary page and pages of figures. 2. Maintaining the secret of industrial creation characterized by being substantially as described on pages 1 to 10 of this report, summary page and pages of figures. Apparatus for magnetising the electric motor rotor comprising: - a seat (11) for temporary housing of a shaftless rotor, said seat comprising; - one or more coil (s) (12) in its inner peripheral region so that it is positioned externally with respect to the rotor when it is housed in said seat; and - one or more coil (s) (13) in its central region, so that it is internally positioned (s) relative to the rotor when it is housed in said seat. Device according to claim 3, characterized in that the external coil assembly (12, 42) includes magnetization (42a) and protective (42b) coils. Device according to Claim 4, characterized in that it comprises four external coils, two magnetizing coils (42a) and two protection coils (42b). Method for magnetising an electric motor rotor comprising the steps of: - temporarily housing a shaft-less rotor in a device according to claim 1; and - drive the inner and outer coils so that they cooperatively provide elevation of the rotor block saturation level. Process according to claim 6, characterized in that protective coils prevent a magnetic field inverse from the rotor magnetization field from being applied and reduce magnetization or demagnetize the rotor.