Motor with Heat Dissipation Structure

Abstract

A motor includes a housing, a front cover, a rotating shaft, and a cooling fan. The front cover is formed with multiple air guiding fins and multiple first inlet holes. The housing is formed with multiple air intercepting fins and multiple second inlet holes. In use, one portion of the air current generated by the cooling fan can be guided by the air guiding fins to pass through the first inlet holes to enter the motor's housing. Another portion of the air current can be intercepted by the air intercepting fins to pass through the second inlet holes to enter the motor's housing. The way of dissipating heat through multiple paths allows the heat generated in the motor to be dissipated more effectively, so that heat is not easy to accumulate in the motor.

Claims

1. A motor including a housing, a front cover, a rotating shaft, and a cooling fan, wherein the housing defines therein an inner space with a front opening and has a rear closure wall opposite to the front opening, the rear closure wall defining a central hole and a plurality of outlet holes; the front cover, which is substantially disk-shaped, closes the front opening of the housing and has a central hub defining a central hole and has a peripheral portion formed around the central hub; the rotating shaft is mounted across the inner space of the housing, the rotating shaft having a first end which is inserted through the central hole of the rear closure wall and having a second end which is inserted through the central hole of the hub of the front cover; the cooling fan is fixed to the second end of the rotating shaft, so that the cooling fan is rotated together with the rotating shaft; wherein the improvement comprises: the front cover is pressed to form a plurality of air guiding fins, which are bent from the peripheral portion of the front cover such that a plurality of first inlet holes are defined next to the corresponding air guiding fins, whereby one portion of a whirling, ongoing air current generated by the cooling fan can be guided by the air guiding fins to pass through the first inlet holes of the front cover and thus to enter the housing for dissipating heat therein.

2. The motor of claim 1, wherein the air guiding fins extends generally towards the cooling fan, at a predetermined angle of (1) to a reference plane (V) with which the front cover is coincident, the predetermined angle (1) being greater than 90 degrees.

3. The motor of claim 1, wherein the housing is pressed to form a plurality of air intercepting fins, which are bent outwardly such that a plurality of second inlet holes are defined next to the corresponding air intercepting fins.

4. The motor of claim 3, wherein the air intercepting fins extend generally towards the cooling fan, at a predetermined angle of (2) to a cross-sectional plane (C) of the housing which is perpendicular to the rotating shaft, the predetermined angle (2) being greater than 90 degrees.

5. The motor of claim 1, wherein the front cover is coupled to the housing through a mounting collar which is provided with two opposite sheaths at one side, and two mounting tubes at an opposite side, wherein the two sheaths allows two electrical terminal blades provided in the housing to insert therethrough, while the two mounting tubes allows two fixing dowel rods provided in the housing to insert therein, so that the front cover is fixed in place and closes the front opening of the housing.

6. The motor of claim 5, wherein the front cover defines at its outer edge two opposite cutouts which are capable of engaging with the sheaths of the mounting collar, so as to fix the front cover in place.

7. The motor of claim 6, wherein the front cover defines a plurality of fixing holes, through which a plurality of screws are engaged with other portions of the housing, so that the front cover is fixed more firmly.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0008] FIG. 1 shows an exploded view of a motor according to one embodiment of the present invention.

[0009] FIG. 2 shows a 3-dimensional view of the motor.

[0010] FIG. 3 shows another 3-diemensional view of the motor, which is viewed from a different angle than FIG. 2.

[0011] FIG. 4 shows a working view of the motor, which demonstrates the air current being guided by the air guiding fins to enter the associated inlet holes of the front cover.

[0012] FIG. 5 shows a plan view of the motor.

[0013] FIG. 6 shows a sectional view of the motor, which demonstrates a first airflow path (A) for one portion of the air current for dissipating the heat generated in the motor.

[0014] FIG. 7 shows another plan view of the motor, which is viewed from a different angle than FIG. 5.

[0015] FIG. 8 shows a sectional view of the motor taken along line D-D in FIG. 7, which demonstrates a second airflow path (B) for another portion of the air current for dissipating the heat generated in the motor.

[0016] FIG. 9 shows a working view of the motor, which demonstrates the air current flowing out of the motor's housing via the outlet holes thereof to take away the heat generated in the motor.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0017] Since the structure and operation of a motor has been known widely, a detailed description thereof is not provided in the following paragraphs.

[0018] Referring first to FIGS. 1 through 3, a motor according to one embodiment of the present invention is shown, which generally includes a housing 1, a mounting collar 5, a front cover 6, a rotating shaft 8, and a cooling fan 7. The housing 1 defines therein an inner space 15 with a front opening 10 and has a rear closure wall 11 opposite to the front opening 10. The rear closure wall 11 defines a central hole, in which a bearing may be mounted, and a plurality of outlet holes 14 around the central hole. The surrounding wall of the housing 1 is pressed to form a plurality of air intercepting fins 12, which are bent outwardly such that a plurality of inlet holes 13 are defined next to the corresponding the air intercepting fins 12. The air intercepting fins 12 extend generally towards the front opening 10 of the housing 1 or the cooling fan 7, at a predetermined angle of (2) to a cross-sectional plane (C) of the housing 1 which is perpendicular to the rotating shaft 8 (see FIG. 7), wherein the predetermined angle (2) is greater than 90 degrees. Furthermore, a rotor 2, coils 3 and magnets 4, which are necessary elements for a motor, are provided in the inner space 15 of the housing 1 (see FIG. 6). The rotating shaft 8 is mounted across the inner space 15 of the housing 1, wherein the rotating shaft 8 has a first end 80 which is inserted through the central hole of the rear closure wall 11 for connecting with a transmission mechanism (not shown) for providing necessary mechanical power. The rotating shaft 8 has a second end 89 which is inserted out of the front opening 10 of the housing 1 to be fitted with the cooling fan 7, as will be further illustrated below. A magnetically permeable sleeve 9, being made of metal, is closely fitted around the outer surface of the housing 1, so that the performance of the motor can be increased.

[0019] The mounting collar 5 is provided with two opposite sheaths 51, 52 at one side and two mounting tubes 53, 54 at the other side or the opposite side, wherein the two sheaths 51, 52 allows two electrical terminal blades 81, 82 provided in the housing 1 to insert therethrough, while the two mounting tubes 53, 54 allows two fixing dowel rods 83, 84 provided in the housing 1 to insert therein, so that the front cover 6 can be coupled to the housing 1 and thus closes the front opening 10 of the housing 1.

[0020] The front cover 6, which is substantially disk-shaped, has a central hub 60 defining a central hole 61 and has a peripheral portion formed around the central hub 60. The front cover 6 is pressed to form a plurality of air guiding fins 63, which are bent from the peripheral portion of the front cover 6 such that a plurality of inlet holes 64 are defined next to the corresponding guiding fins 63. The air guiding fins 63 extend generally towards the cooling fan 7, so that they are at a predetermined angle of (1) to a reference plane (V), which is perpendicular to the rotating shaft 8 or with which the front cover 6 is coincident (see FIG. 6), wherein the predetermined angle (1) is greater than 90 degrees. Furthermore, the front cover 6 defines at its outer edge two opposite cutouts 62 which are capable of engaging with the sheaths 51, 52 of the mounting collar 5, so as to fix the front cover 6 to the mounting collar 5 which is in turn fixed to the housing 1. In addition, the front cover 6 defines a plurality of fixing holes 65, through which a plurality of screws can be engaged with other portions of the housing 1 (not shown), so that the front cover 6 can be fixed more firmly. While the front cover 6 is being coupled to the housing 1 by the mounting collar 5, the second end 89 of the rotating shaft 8 can be inserted through the central hole 61 of the central hub 60 of the front cover 6, wherein a bearing (not shown) may be provided in the central hub 60 of the front cover 6 and fitted with the second end 89 of the rotating shaft 8.

[0021] The cooling fan 7 defines a central hole 70, into which the second end 89 of the rotating shaft 8 extending out of the central hole 61 of the front cover 6 can be fitted, so that the fan 7 is attached to and rotated together with the rotating shaft 8.

[0022] FIGS. 2 and 3 show one embodiment of the motor being assembled from the housing 1, the mounting collar 5, the front cover 6, and the cooling fan 7. When the motor is started, the cooling fan 7 can be rotated together with the rotating shaft 8 to generate a whirling, ongoing air current towards the front cover 6, so that the air at the right side of the cooling fan 7 can be forced to flow into the left side of the cooling fan 7 (see FIG. 5). In particular, the air current can enter the inner space 15 of the housing 1 through multiple paths, so that the heat generated in the housing 1 can be dissipated more effectively (see FIGS. 4, 6, 7 and 8). A central portion of the air current generated by the cooling fan 7 can be guided by the air guiding fins 63 of the front cover 6 to pass through the associated inlet holes 64 and thus to enter the inner space 15 of the housing 1. While the motor is running, the central portion of the air current may follow a first airflow path (A) to dissipate the heat generated in the housing 1 (see FIGS. 4 and 6). An outer portion of the air current generated by the cooling fan 7, which is outside the area surrounded by the air guiding fins 63 of the front cover 6, can be intercepted by the air intercepting fins 12 to pass through the associated inlet holes 13 of the housing 1 and thus to enter the inner space 15 of the housing 1. While the motor is running, the outer portion of the air current may follow a second airflow path (B) to increase the capacity of dissipating the heat generated in the housing 1 (see FIG. 8). The air entering the inner space 15 of the housing 1 can flow out of the housing 1 via the outlet holes 14 of the rear closure wall 11 of the housing 1 (see also FIG. 9), and thus the heat generated in the housing 1 can be taken away with the air. The two airflow paths (A) (B) allow the heat generated in the housing 1 to dissipate more effectively, so that the temperatures of the rotor 2, coils 3, and magnets 4 can be restrained more effectively.

[0023] As a summary, the air intercepting fins 12 and the associated inlet holes 13 of the housing 1 allow the motor of the present invention to provide an airflow path (B) for dissipating the heat generated in the housing 1, while the air guiding fins 63 and the associated inlet holes 64 allow the motor to provide another airflow path (A) to increase the capacity of dissipating heat. Since the air current generated by the cooling fan 7 can enter the inner space 15 of the housing 1 via both airflow paths (A) (B) to timely and effectively dissipate the heat generated in the housing 1, so that heat is not easy to accumulate in the housing 1 of the motor; therefore, maximum power output of the motor can be achieved, and the performance and service life of the motor can be increased. Thus, even though the motor is operated in a high-temperature environment, it will not burn out. These features render the motor of the present invention useful and inventive.