KR830001026Y1 - Small motor - Google Patents

Abstract

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Description

Small motor

1 is a perspective view illustrating a relationship between a brush and a motor case in an embodiment of a conventional small motor.

FIG. 2 is a front view of the brush shown in FIG. 1 fixed to a mother case and viewed from the direction of arrow (a) shown in FIG.

3 is a perspective view of an embodiment of a brush used in the male motor of the present invention.

Figure 4 is a front view showing another second embodiment of the present invention.

5 is a front view showing another third embodiment of the present invention.

The present invention is designed to reinforce rigidity by installing a rigid reinforcement at the bend of the brush base of the brush, especially the brush base of the brush and the commutator sliding part, and to install the auxiliary support part supporting the lower side of the bent part as necessary to eliminate unnecessary fluctuations of the commutator sliding part. The present invention relates to a small motor which prevents frictional wear of the commutator to improve the life of the motor.

The commutator wear, which is the biggest factor that influences the durability of small motors, is mechanical wear caused by friction with the brush and electrical wear caused by arc occurring between the commutator and the brush. Especially when the mechanical wear and the electrical wear overlap, the wear is extreme. Since the commutator is rotating, the surface of the commutator is not smooth or vibrations during rotation cause the brush to be in poor contact with the commutator surface, which promotes arcing and aggravates abrasion. Therefore, it is necessary to keep the commutator and the brush in good contact at all times, so the brush must be in contact with the commutator with proper pressure.

The brush 1 used in a general small motor is made of a brush base 2, 2 'and a commutator sliding part 3 by a thin plate material of an elastic conductive material, for example, beryllium alloy, as shown in FIG. 3 ') bent at a certain angle and integrally constructed. These brushes 1 and 1 'have terminal portions 4 and 4', bending fixing portions 5 and 5 'and fixing holes 6 and 6', respectively. The motor case cover 7 is provided with brush supports 8, 8 'and 9, 9' for supporting the brushes 1, 1 ', so that the brush supports 8, 8' and 6, 6 'are opposed to each other. Brush mounting holes 10 and 10 'are formed in the gap. In attaching the brushes 1, 1 'to the motor case cover, the brushes 1, 1' are inserted in the directions of arrows a, a 'of Fig. 1, respectively. At this time, the terminal portions 4, 4 'are drawn out of the motor case cover 7 through the terminal through holes (not shown) provided in the brush installation holes. Since the opposing intervals of the brush supports 8, 8 'and 9, 9' are determined according to the plate thickness of the brush bases 2, 2 ', the brush bases 2, 2' are formed on the brush supports 8, 8 '. And 9, 9 'are supported by the brushes 1, 1' and the motor case cover 7, respectively. In addition, the bent fixing parts 5, 5 ', which are bent from the brush parts 2, 2', are fixed to the projections 11, 11 'provided on the brush support parts 9, 9'. After the fitting, the head of the protrusions 11 and 11 'may be locked to the motor case cover 7 more firmly to the brushes 1 and 1'. FIG. 2 is a front view in which the brush 1 is supported by the motor case cover 7 and the commutator sliding part 3 is elastically contacted with the commutator 12 in the direction of arrow (a) of FIG. 1 as described above. Is shown. The commutator sliding part 3 extends in a straight line in the state of no water velocity, ie, in a state where it is not in contact with the commutator 12 as shown in FIG. However, as shown in FIG. 2, by contacting and installing the commutator 12, it becomes curved, and the pressurization by elasticity arises with respect to this commutator 12. As shown in FIG. In addition, by appropriately selecting the bending angle θ of the commutator sliding part 3 and the brush base 2 in the unbound state, such a pressing pressure can be optimized.

However, due to the rotation of the commutator 12, friction is generated between the commutator 12 and the commutator sliding part 3, so that the commutator sliding part 3 is tangential to the contact portion with the commutator 12 due to this friction. Receives the power of In other words, when the commutator 12 rotates in the direction of the arrow F in FIG. 2, the commutator sliding part 3 receives the force in the direction of the arrow T at the tip, as indicated by the dotted line A. FIG.

When the direction of rotation of the commutator 12 is in the direction of the arrow R, the curvature of the commutator sliding part 3 is pushed up, that is, a result of the force being applied in the direction of the arrow C. It is as shown in. In any of the above cases, if the degree of curvature or elongation exceeds a certain limit, the curve or elongation rapidly returns to its original state, that is, the illustrated state.

In this way, during the rotation of the commutator 12, the commutator sliding part 3 repeats the above-mentioned speech return (elongation). Thus, at this return, the commutator sliding part 3 rapidly passes through the surface of the commutator 12, so that the surface of the commutator 12 is subjected to mechanical local wear due to friction. The local wear of the commutator 12 causes arcing, and electrical abrasion caused by the arc becomes more severe. In order to solve this problem, in consideration of the shape of the commutator sliding part (3), when the commutator sliding part (3) is bent in advance in contact with the commutator (12), the rectifier sliding part (3) is almost straight. This prevents the repetitive operation of the curved (extension) return.

However, since the plate thickness of the brush used in the ordinary small motor is about 0.08 mm, and the mechanical strength is weak, the commutator sliding part 3 is rotated by the rotation of the commutator 12 as shown in FIG. The bending portion 13 itself of the brush portion 2 and the commutator sliding portion 3 is subject to oscillation or fluctuation upon being subjected to the tension in the direction or the compression force in the direction of the arrow C, or the bending portion 13 The bending angle [theta] is changed, and the like occurs. For this reason, it was not sufficient to prevent deformation of the brush as shown by the dotted line A or B in FIG.

The object of the present invention is to install the rigid reinforcement at the bend of the brush base and the commutator sliding part to reinforce the bent portion, thereby preventing the undesirable fluctuation of the commutator sliding part and reducing the frictional wear of the commutator to improve the durability life. It is to provide a small motor.

Another object of the present invention is to provide a small motor that prevents undesirable fluctuation of the commutator sliding part by providing an auxiliary support for supporting the bent portion in the brush support to reduce the frictional wear of the commutator to improve the durability life. It is.

Another object of the present invention is to use a commutator by using a brush configured to make the commutator sliding part in advance in an unrestrained state of the brush so that the commutator sliding part is in a substantially straight state when the commutator sliding part is elastically contacted with the commutator. It is to provide a small motor that prevents undesirable sliding of the sliding portion to reduce the frictional wear of the commutator.

In FIGS. 3 to 5 showing embodiments of the present invention, the brush 1 includes a brush base 2, a commutator sliding part 3, a terminal 4, a bending fixing part 5, It consists of a fixing hole (6), a motor case cover (7) and a brush support (9), a brush installation hole (10), a protrusion (11), a bent portion (13), and a rigid reinforcement part (14) and an auxiliary support part (15). It is. 5 also shows the commutator 12.

As described with reference to Fig. 2, one of the causes of the undesirable fluctuation of the commutator sliding part 3 is that the position of the bent part 13 itself varies. Therefore, in the present invention, even when a force in the direction of the arrow (C or T) of FIG. 2 occurs in the commutator sliding part 3 in accordance with the rotation of the commutator 12 by reinforcing the bent part 13, the bend angle (θ) does not change. That is, the brush 1 used in the small motor of the present invention reinforces the bent part 13 by installing the rigid reinforcement part 14 in the bent part 13 as shown in FIG. 3. Stiffness is given to (1). The rigid reinforcement portion 14 shown in the embodiment of FIG. 3 is an elongated recess provided bent at an almost right angle on the auxiliary support portion 15 with respect to the bent portion 13. In the manufacture of the brush 1, the recessed part is formed in advance at the boundary between the brush base 2 and the commutator sliding part 3 by a long thin stroke. Thus, when the brush portion 2 and the commutator sliding portion 3 are bent at the bent portion 13 so that the bulging side of the recess is inward, a brush 1 as shown in FIG. 3 is formed. The brush 1 formed in this manner can prevent the bending part 13 from being unstable in the commutator sliding part 3 as described in FIG. 2 by being rigidly reinforced by the rigid reinforcing part 4. have.

In the embodiment of Fig. 3, an embodiment in which one rigid reinforcement portion 14 is provided is shown. However, a plurality of rigid reinforcement portions 14 may be provided, and the reinforcement portion 14 is not limited to a blown-out type. It is needless to say that the same structure (eg, bending side edge) may be used to reinforce rigidity.

Further, in order to further ensure the rocking of the commutator sliding part 3, the reinforcement part 14 which provided the auxiliary support part 15 in the brush support part 9 and installed in the said bend part 13 as needed like FIG. ), And the plate thickness of the brush base portion 2 is selected to be about 0.08 mm, so that the brush installation hole 10 is molded so that the terminal portion 4 of the brush base 2 is properly tightened and press-fitted. It is virtually impossible to do. In other words, the mounting hole 10 is larger than the thickness of the brush, and the terminal portion 4 and the brush base 2 of the brush 1 are easily shaken in the mounting hole 10. The shaking support can be prevented by providing the auxiliary supporting part 15 so as to support the rigid reinforcing part 14 provided in the brush bent part 13 from the lower side.

Accordingly, the bent portion 13 by the reinforcement portion 14 and the auxiliary support portion 15 is more firmly supported and does not rock or shake, and the commutator sliding portion 3 in the high-speed rotation of the commutator 12 is a commutator. Unnecessary sliding friction with respect to the contact point with (12) is prevented.

In addition, as described with reference to FIG. 2, when the commutator sliding part 3 receives the force in the direction of the arrow T or C by the rotation of the commutator 12 in the direction of arrow F or R of FIG. 4. The commutator sliding part 3 is curved as shown in FIG. In order to prevent this curvature, it is preferable that the said commutator sliding part 3 is linear like FIG. 4 in the state which the commutator sliding part 3 elastically contacted the commutator 12. FIG. Therefore, in consideration of the shape of the commutator sliding part 3, the commutator sliding part 3 is bent in advance in an unbounded state as shown by the dotted line D in FIG. 4 to elastically contact the commutator 12. It helps to prevent the bending by making it almost straight when done.

Another third embodiment of the present invention is shown in FIG. In this embodiment, the central portion of the brush base 2 is supported by the central projection 16 provided on the brush support 9, and both shaft portions of the brush base 2 are supported on both sides K of the brush support 8. The brush base 2 is an embodiment that is elastically supported at three points by the bending force. In this case, even when the brush 1 is supported at three points, as in the case of the embodiment of FIGS. 3 and 4, the rigidity of the brush base 2 and the bent portion 13 of the commutator sliding part 3 is reinforced. By installing the portion 14 or extending the bridging portion 9 as necessary, the auxiliary supporting portion 15 for supporting the rigid reinforcing portion 14 is formed and supported as shown in FIG. The same effect as in the embodiment of 4 degrees is further enhanced.

As described above, according to the present invention, the rigid reinforcing portion 14 is formed in the brush base bent portion 13 of the brush 1 of the small motor, and the brush bent portion 13 is attached to the auxiliary support 15 as necessary. The commutator sliding part 3 is linearly supported when the commutator sliding part 3 is bent in an unbounded state and elastically contacted with the commutator 12 by supporting from below. Also, in the contact point between the commutator sliding part 3 and the commutator, the occurrence of sliding friction due to undesired irregularities can be prevented, thereby reducing the local damage of the commutator and improving the durability life.

Claims (1)

The brush base and the commutator sliding part form a brush formed by a conductive elastic body having a bent portion bent at a predetermined angle, and the brush base of the brush is supported by the brush support part installed on the motor case cover, and the commutator sliding part of the brush In a small motor configured to be in direct elastic contact with the commutator of the motor, the brush 1 is provided with a rigid reinforcement 14 for reinforcing the rigidity of the brush in the brush bent portion 13, the motor case cover (7) The auxiliary support part 15 supporting the brush bent portion is installed in the brush, and the brush is curved in the commutator direction in the commutator direction in the uncommitted state in advance, and the commutator sliding part is linearly in contact with the commutator. Small motor, characterized in that consisting of.