The present disclosure relates to a brush motor in which a coil is energized from a brush through a commutator.
Conventionally, a brushed DC motor in which the number of coils is larger than the number of field magnetic poles has been known. An example of such a motor is a four-pole/six-slot motor having a concentrated-winding structure (structure in which an electric wire of coils is individually wound around teeth, respectively) having four field magnetic poles and six iron core grooves (slots). In this motor, coils as many as the number of iron core grooves are provided, and six coils more than four, which is the number of field magnetic poles, are incorporated (see JPH11-69747).
In the motor including the coils having the concentrated-winding structure, in a case where the number of coils is larger than the number of field magnetic poles, a blade angle in a cross section perpendicular to a rotation axis of the motor becomes smaller than a magnet angle. As a result, a magnet magnetic flux is insufficiently picked up, and there is a problem that it is difficult to effectively utilize the magnetic flux. In addition, in a case where a coil having a straddling winding structure in which an electric wire is wound so as to straddle a plurality of teeth is adopted, there is a problem that it is difficult to increase torque because a coil end bulges so that winding resistance increases.
One object of the present disclosure is to provide a brush motor that has been created in light of the above problems and is capable of achieving downsizing and high torque with a simple configuration. Note that the present disclosure is not limited to this object, and it is also possible to position, as another object of the present disclosure, achieving functions and effects that are derived from each configuration illustrated in “DETAILED DESCRIPTION” to be described later, the functions and effects being hardly obtained by conventional techniques.
A brush motor according to an embodiment of the present disclosure includes: a rotor core provided in a rotor; s teeth provided in the rotor core; s concentrated-winding coils with electric wires being respectively wound around the teeth; a commutator provided on the rotor in a relatively non-rotatable manner; c commutator pieces provided in the commutator and connected to the coils; p pairs of magnet magnetic poles provided on a stator and arranged to face the teeth; and a brush that is brought into sliding contact with the commutator pieces to supply a current to the coils, in which the following inequality A and inequality B hold.
0.5<p/s<1 (Inequality A)
s<c (Inequality B)
According to the disclosed technology, the magnet magnetic flux can be sufficiently picked up, and the downsizing and the high torque can be achieved with a simple configuration.
The stator 3 is provided with a magnet 4 (permanent magnet) for forming a magnetic field to be applied to the rotor 6. The magnet 4 has p pairs of magnet magnetic poles 5 formed in a curved surface shape. A shape of the magnet magnetic pole 5 is, for example, an arc surface shape or a shape similar thereto. The magnet magnetic poles 5 are attached along an inner peripheral surface of the housing 2 and arranged at predetermined intervals in the circumferential direction (circumferential direction of a circle centered on the rotation axis C in a cross section perpendicular to the rotation axis C). An orientation of a magnetic field is set to a direction from the outside to the inside of the housing 2 or the opposite direction (direction from the inside to the outside). In the present disclosure, the magnet magnetic poles 5 are arranged such that orientations of the magnetic fields are reversed between the adjacent magnet magnetic poles 5.
The magnet 4 illustrated in
The rotor 6 is provided with a core 10 (rotor core) and a commutator 8 (commutator) that are fixed to the shaft 20 in a relatively non-rotatable manner. The core 10 is formed by laminating a plurality of steel plates having the identical shape. A lamination direction of the steel plates is identical to an extending direction of the rotation axis C. The core 10 is provided with s teeth 11 having a shape radially protruding from the rotation axis C in the cross section perpendicular to the rotation axis C. Electric wires are wound respectively around the teeth 11 to form s coils 7 (concentrated-winding coils).
The commutator 8 is a member for energizing the coil 7 at an appropriate position according to a rotation angle of the rotor 6 in an appropriate orientation. The commutator 8 is provided with c commutator pieces 9 formed in a curved surface shape. A shape of the commutator piece 9 is formed in, for example, an arc surface shape or a shape similar thereto. These commutator pieces 9 are adjacently arranged in the circumferential direction along an outer peripheral surface of the shaft 20. Each of the commutator pieces 9 and each of the coils 7 are connected by a power supply circuit 23. A circuit structure of the power supply circuit 23 will be described later.
A brush 21 (brush) is provided in the periphery of the commutator 8 so as to be in contact with the surface of the commutator piece 9. The brush 21 is attached to one end of a brush arm 22 and is supported in a state of being elastically pressed against the commutator piece 9. In addition, a pair of the brushes 21 and a pair of the brush arms 22 are provided. The other ends of the brush arms 22 pass through, for example, the lid member, extend to the outside of the housing 2 and serve as terminals for power supply.
The brushes 21 are provided so as to be in contact with any one of the c commutator pieces 9.
Regarding the relationship among the p pairs of magnet magnetic poles 5, the s coils 7, and the c commutator pieces 9, values of p, s, and c are set such that the following inequalities hold in the present disclosure. That is, a value obtained by dividing the number p of sets (the number of pairs including two as one set) of the magnet magnetic poles 5 by the number s of the coils 7 is set to be larger than 0.5 and smaller than 1. In addition, the number s of the coils 7 is set to be smaller than the number c of the commutator pieces 9.
0.5<p/s<1 (Inequality A)
s<c (Inequality B)
Note that, “p<s<2p” is obtained if Inequality A is transformed. Therefore, it suffices that the number s of the coils 7 is set to be larger than the number p of sets of the magnet magnetic poles 5 and smaller than the total number 2p of the magnet magnetic poles 5.
The core 10 of the brush motor 1 according to the first example includes a commutating pole 14. The commutating pole 14 is a portion radially extending from the rotation axis C of the rotor 6 to reinforce a flow of a magnetic flux, and is provided integrally with the core 10. As illustrated in
Note that both ends of the magnetized region when a plurality of magnetic poles is magnetized in the ring magnet or the single magnet piece have an angle at which the magnetic flux density decreases from a center position (magnetization center position) of each magnetic pole, and the magnetic flux density first becomes zero. The relationship between a magnetic flux density distribution of the ring magnet and the magnet angle θM is illustrated in
In addition, a range in which one blade 13 faces the magnet 4 in the cross section perpendicular to the rotation axis C is expressed by an angle with respect to the rotation axis C, and this is referred to as a blade angle θW. That is, a central angle of a fan shape surrounded by the blade 13 and line segments connecting both ends of the blade 13 to the rotation axis C in the cross section perpendicular to rotation axis C is defined as the blade angle θW. In the brush motor 1 of the first example, the blade angle θW is preferably set to the magnitude of the magnet angle θM or more (θW≥θM). As a result, the magnet magnetic flux is easily picked up by the teeth 11, and the magnetic flux is effectively utilized.
In
On the other hand, in the brush motor 1 (with four poles and three slots) of the first example, the number of coils is three, and thus, the blade angle θW increases as illustrated in
On the other hand, the brush motor 1 of the first example includes the commutating pole 14 and the slit 17 that is relatively narrow, and thus, the flow of the magnetic flux becomes continuous. For example, as indicated by a black arrow in
According to the brush motor 1 of the first example, the following effects can be obtained.
(1) In the brush motor 1 of the first example, the values of p, s, and c are set such that 0.5<p/s<1 and s<c hold. As a result, the size of the brush motor 1 can be easily reduced, or the higher torque can be achieved with the same size (the same volume), for example, as compared with an existing brush motor as illustrated in
In addition, since a width direction of the slit 17 approaches parallel to a winding direction of the winding as compared with the existing brush motor, the net slit width W can be increased, and the winding can be easily wound. In addition, the number of winding steps decreases, and labor and cost required for manufacturing can be reduced.
(2) In the brush motor 1 of the first example, the blade angle θW is set to be equal to or larger than the magnet angle θM as illustrated in
(3) As illustrated in
(4) In the brush motor 1 of the first example, the coils 7 are connected in an annular shape as illustrated in
(5) The brush motor 1 of the first example includes the two pairs of magnet magnetic poles 5, the three coils 7, and the six commutator pieces 9, and thus, the combination of (p, s, c) is (2, 3, 6). With such a configuration, the brush motor 1 having the high torque can be achieved with a simple configuration in which the number of coils is small, and the downsizing is easy due to an increase in magnetic flux.
A commutating pole 14 provided on a core 10 of the brush motor 41 according to the second example includes a commutating pole column 15 and a commutating pole blade 16. As illustrated in
Each of the commutator pieces 9 and each of the coils 7 are connected by a power supply circuit 42.
Positions of these commutator pieces C1, C5, and C9 are shifted by 120 degrees with respect to a rotation axis C. Therefore, a potential of the point Q1 becomes identical every time the rotation axis C rotates by ⅓. Similarly, a point Q2 between the second coil and the third coil is short-circuit connected to commutators pieces C2, C6, and C10. In addition, a point Q3 between the third coil and the fourth coil is short-circuit connected to commutator pieces C3, C7, and C11, and a point Q4 between the fourth coil and the first coil is short-circuit connected to commutator pieces C4, C5, and C12. In addition, positions of brushes B1 and B2 are shifted by 180 degrees with respect to the rotation axis C.
According to the brush motor 41 of the second example, similar effects as those of the first example can be obtained. For example, downsizing can be performed more easily or higher torque can be achieved with the same size as compared with an existing brush motor. In addition, higher torque can be obtained as compared with the brush motor 1 of the first example. Meanwhile, the number of winding steps decreases with a concentrated-winding structure, and labor and cost required for manufacturing can be reduced as compared with an existing brush motor (for example, a brush motor with six poles and twelve slots) in which the number of magnet magnetic poles 5 is identical to that of the brush motor 41 of the second example and the number of coils is larger. Further, a coil end can be reduced with the concentrated-winding structure, and winding resistance can be reduced. In addition, the pulsation of a current can be increased as compared with the first example, and the use of the pulsation of the current enables sensorless control that does not require an additionally required sensor magnet.
Each of the commutator pieces 9 and each of the coils 7 are connected by a power supply circuit 52.
Positions of these commutator pieces C1, C6, and C11 are shifted by 120 degrees with respect to a rotation axis C. Therefore, a potential of the point R1 becomes identical every time the rotation axis C rotates by ⅓. Similarly, a point R2 between the second coil and the third coil is short-circuit connected to commutator pieces C2, C7, and C12. Further, a point R3 between the third coil and the fourth coil is short-circuit connected to commutator pieces C3, C5, and C13, a point R4 between the fourth coil and the fifth coil is short-circuit connected to commutator pieces C4, C9, and C14, and a point R5 between the fifth coil and the first coil is short-circuit connected to commutator pieces C5, C10, and C15. In addition, positions of brushes B1 and B2 are shifted by 180 degrees with respect to the rotation axis C.
According to the brush motor 51 of the third example, similar effects as those of the first example and the second example can be obtained. For example, downsizing can be performed more easily or higher torque can be achieved with the same size as compared with an existing brush motor. In addition, higher torque can be obtained as compared with the brush motors 1 and 41 of the first example and the second example. Further, as compared with the first example and the second example, the pulsation of the torque can be reduced, vibration can be reduced to enhance the controllability.
The above examples are merely examples, and there is no intention to exclude applications of various modifications and technologies that are not explicitly described in the present examples. The configurations of the present examples can be variously modified and implemented within a scope not departing from the gist thereof. In addition, the configurations of the present examples can be selected as necessary, or can be appropriately combined with various configurations included in known technologies.
Number | Date | Country | Kind |
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2021-077067 | Apr 2021 | JP | national |