This non-provisional patent application claims priorities under 35 U.S.C. §119(a) from Patent Application No. 201210336520.0 filed in The People's Republic of China on 12 Sep., 2012 and Patent Application No. 201210336532.3 filed in The People's Republic of China on 12 Sep., 2012.
This invention relates to a commutator for brush motors and in particular, to a spark suppressing arrangement for the commutator.
A brush motor typically includes a stator and a rotor. The rotor includes a shaft, a rotor core fixed on the shaft, a commutator fixed on the shaft adjacent the rotor core, and rotor windings wound about the teeth of the rotor core and electrically connected to the commutator. The stator includes stator magnetic poles, power terminals and at least a pair of brushes in sliding contact with segments of the commutator. External power is supplied to the rotor windings via the power terminals, the brushes and the commutator. When electrified, the rotor windings form rotor magnetic field which interacts with stator magnetic field to drive the rotor to rotate.
During commutation, when a brush leaves a segment of the commutator, the current passing through the corresponding rotor winding changes abruptly, thereby generating a large induced electromotive force and a strong electric field across an air gap between the brush and the segment. The air around the brush and the segment may be ionized under the strong electric field to form a discharge path and generate sparks. The spark may damage the slide contact between the brush and the commutator, which increases the worn of the brush and the commutator. Hence there is a desire for a commutator with diminished spark.
Accordingly, in one aspect thereof, the present invention provides a commutator for a brush motor includes a cylindrical insulating base, a plurality of segments disposed on an outer surface of the insulating base, circumferentially spaced from each other, and defining a plurality slots between adjacent segments, and a plurality of insulating outgas elements capable of releasing a gas having a lower conductivity than air and disposed on the outer surface of the cylindrical insulating base. Each outgas element is located between a corresponding pair of the plurality of segments, having a gas releasing surface between the corresponding pair of segments and lower than outer surfaces of the corresponding pair of segments.
Preferably, said plurality of outgas elements at least partly extend into the plurality of slots between adjacent segments.
Preferably, at least one of two opposite side surfaces of a pair of adjacent segments has a recess, and an outgas element of said plurality of outgas elements extends into the recess.
Preferably, the gas release surface of one of said plurality of outgas elements has a side surface defining a circumferential gap with one of two opposite side surfaces of a corresponding pair of adjacent segments.
Preferably, one of said plurality of outgas elements extends into a groove in the outer surface of said cylindrical insulating base and is radially confined by inner surfaces of a corresponding pair of adjacent segments.
Preferably, the gas releasing surface of one of said plurality of outgas elements is lower than or aligned with inner surfaces of a corresponding pair of adjacent segments.
Preferably, the gas releasing surface of one of said plurality of outgas elements includes an uneven surface.
Preferably, two opposite side surfaces of a pair of adjacent segments are inclined relative to a radial direction of said cylindrical insulating base, and a distance between the two opposite side surfaces gradually increases along the radial direction.
Preferably, said plurality of outgas elements and said cylindrical insulating base are formed as a monolithic member.
Preferably, said plurality of outgas elements and said cylindrical insulating base are detachably assembled together.
Preferably, said plurality of outgas elements are made of a same material as said cylindrical insulating base.
Preferably, said plurality of outgas elements and said cylindrical insulating base are made of different materials.
Preferably, said plurality of outgas elements are made of a thermal plastic material capable of spontaneously releasing a gas having a conductivity lower than air.
Preferably, said plurality of outgas elements are made of Polyamide 66.
Preferably, said cylindrical insulating base is made of a thermosetting material.
According to a second aspect, the present invention provides a method for making a commutator, comprising identifying an insulating base, disposing a plurality of segments circumferentially spaced on an outer surface of the insulating base, and disposing a plurality of insulating outgas elements capable of releasing a gas having a conductivity lower than that of air and spaced on the outer surface of the insulating base between corresponding pairs of adjacent segments with gas releasing surfaces lower than outer surfaces of the segments.
Preferably, disposing a plurality of insulating outgas elements further includes disposing an outgas element of the plurality of outgas elements at least partially in a slot between a corresponding pair of adjacent segments.
Preferably, disposing a plurality of segments includes disposing a plurality of segments at circumferential intervals, disposing a plurality of insulating outgas elements includes disposing an outgas element of the plurality of outgas elements at least partially in a slot between a corresponding pair of adjacent segments, and identifying an insulating base includes disposing an insulating base on the outgas elements and inner surfaces of the segments.
Preferably, identifying an insulating base further includes forming a plurality of grooves on the outer surface of the insulating base, disposing a plurality of segments further includes placing two adjacent segments on opposite sides of a groove of the plurality of grooves on the outer surface of the insulating base, and disposing a plurality of insulating outgas elements further includes disposing an outgas element of the plurality of outgas elements at least partially in a corresponding groove on the outer surface of the insulating base.
Preferably, disposing a plurality of segments includes providing a metal ring, identifying an insulating base includes disposing an insulating base on an inner surface of the metal ring, the insulating base having a plurality of grooves or holes on an outer periphery thereof, disposing a plurality of insulating outgas elements includes disposing the plurality outgas elements in the plurality of grooves or holes, and disposing a plurality of segments further includes forming a plurality of through slots in the metal ring to form the segments and expose the outgas elements.
Preferably, disposing a plurality of segments includes providing a metal ring, disposing a plurality of insulating outgas elements includes disposing the plurality outgas elements on an inner surface of the metal ring, identifying an insulating base includes disposing an insulating base on the outgas elements and an inner surface of the metal ring, and disposing a plurality of segments further includes forming a plurality of through slots in the metal ring to form the segments and expose the outgas elements.
Various embodiments of the invention are described, by way of example only, with reference to the drawings, in which identical or related structures, elements, or parts may be labeled with the same reference numerals throughout the figures. Dimensions of components and features shown in the figures are generally chosen for convenience and clarity of presentation and are not necessarily shown to scale.
In accordance with an embodiment of the present invention, a plurality of axially extending grooves 20 are formed in the outer surface of the insulating base 12 at regular intervals in the circumferential direction. The segments 14 are arranged between adjacent grooves 20. The circumferential distance between two opposite side surfaces 22 of two adjacent segments 14 is smaller than the circumferential width of the groove 20 so that the opposite side surfaces 22 of the adjacent segments 14 and the corresponding groove 20 define an inverted T-shaped slot. An inverted T-shaped insulating outgas element 24 is disposed in the inverted T-shaped slot.
Preferably, the outgas elements 24 and the insulating base 12 are made of different materials. In accordance with a preferred embodiment, the outgas elements 24 are made of a thermal plastic material such as, for example, Polyamide 66 that is sometimes also referred to as PA66, which is able to spontaneously release a gas with conductivity lower than air. The portion of the outer surface of an outgas element 24 between two corresponding adjacent segments 14 forms a gas releasing surface 26. The gas releasing surface 26 is radially lower than the outer surfaces 28 of the segments 14, so that the gas releasing surface 26 and the opposite side surfaces 22 of two adjacent segments 14 define a space 30 through which the gas released from the outgas element 24 spreads. The inverted T-shaped configuration makes the outgas elements 24 radially confined and prevents the outgas elements 24 from being thrown out during the high speed rotation of the commutator 10. It also increases the size of the outgas elements 24, thereby prolonging the usable life of the outgas elements 24 and/or increasing the gas released from the outgas elements 24.
The commutator 10 may be formed by following an exemplified method described infra. The segments 14, the ring 16, the outgas elements 24 and the insulating base 12 with the grooves 20 are separately fabricated firstly. The outgas elements 24 are then inserted into the grooves 20 in the outer surface of the insulating base 12. After that, the segments 14 are assembled on the outer surface of the insulating base 12 and between adjacent outgas elements 24, and the ring 16 is sleeved on the outer surfaces of the segments 14 to radially confine the segments 14 on base 12.
According to another exemplified method, the outgas elements 24 are inserted into the inverted T-shaped slots defined by the opposite side surfaces 22 of two adjacent segments 14 and corresponding groove 20 in the base 12 after the segments 14 are assembled on the outer surface of the insulating base 12.
In the above described exemplified methods, the outgas elements 24 are independently formed and inserted into corresponding grooves 20 in the base 12 so that the outgas elements 24 and the insulating base 12 form pieces detachable from each other. According to another exemplified method, the outgas elements 24 are injection-molded in the grooves 20 in the insulating base 12, before or after assembling the segments 14 to the insulating base 12, so that the outgas elements 24 and the insulating base 12 form an inseparable or undetachable single piece.
In the above described method, the through slots 42 are formed after the outgas elements 24 are inserted into the holes 50 or the grooves in the insulating base 12. According to another exemplified method, the through slots 42 are formed to connect with the holes 50 or the grooves in the insulating base 12 before the outgas elements 24 are inserted into the holes 50 or the grooves.
in above described methods, the outgas elements 24 are independently formed and then inserted into corresponding holes 50 or grooves so that the outgas elements 24 and the insulating base 12 are detachable from each other. Alternatively, the outgas elements 24 are injection-molded in the holes 50 or the grooves in the insulating base 12 so that the outgas elements 24 and the insulating base 12 form an inseparable or undetachable single piece.
In above described methods, the outgas elements 24 are independently formed and then inserted into the position slots 56. In another exemplified method, the outgas elements 24 are directly injection-molded in the position slots 56.
According to another embodiment of the present invention, the outgas elements 24 are connected together by a connecting ring. After the insulating base 12 is molded on the outgas elements 24 and the segments 14, the connecting ring can be kept or removed.
The commutator in accordance with embodiments of the present invention is especially suitable for high power motor applications. Under this situation, the insulating base 12 may be made of a thermosetting material to provide stable support for the segments 14 in an environment with high temperature. The outgas elements 24 are preferably made of insulating material that can spontaneously release gas with lower conductivity than air under non-high temperature condition and release more such gas under high temperature condition. It should be understood that the commutator in accordance with embodiments of the present invention is also applicable to the low power motors.
In the description and claims of the present application, each of the verbs “comprise”, “include”, “contain” and “have”, and variations thereof, are used in an inclusive sense, to specify the presence of the stated item but not to exclude the presence of additional items.
Although the invention is described with reference to one or more preferred embodiments, it should be appreciated by those skilled in the art that various modifications are possible. Therefore, the scope of the invention is to be determined by reference to the claims that follow.
For example, two opposite side surfaces 22 of the adjacent segments 14 may be inclined relative to the radial direction and the distance between the two side surfaces 22 gradually increases along the direction from the inner surface 44 to the outer surface 28 of the segments 14.
For another example, the gas releasing surface 26 may be uneven so as to increase the surface area and amount of gas released.
Number | Date | Country | Kind |
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201210336520.0 | Sep 2012 | CN | national |
201210336532.3 | Sep 2012 | CN | national |