The present disclosure relates generally to power tools and more particularly to power tools having housings with enhanced impact resistance.
The statements in this section merely provide background information related to the present disclosure and may not constitute prior art.
A typical type of power tool includes a housing in which a motor is received. The motor drives a tool portion or tool holding portion that extends out of the housing. The housing may be a clamshell type of housing having two halves which are joined to each other. It should be understood that the housing may be other than a clamshell type of housing.
The housing of the power tool is generally made of synthetic resin and has a thin wall construction to provide a light-weight power tool to reduce a user's fatigue in operating the power tool.
In accordance with one aspect of the present disclosure, a power tool has a housing. A portion of the housing surrounds at least a part of a motor. At least portions of the housing surrounding the motor include a double wall having an interior wall spaced from an exterior wall. In an aspect of the present disclosure, the portion of the housing that surrounds the motor is an end portion of the housing.
Further areas of applicability will become apparent from the description provided herein. It should be understood that the description and specific examples are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.
The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way.
The following description is merely exemplary in nature and is not intended to limit the present disclosure, application, or uses. Corresponding reference numerals indicate corresponding parts throughout the several views of the drawings.
Referring to
The motor 14 is illustratively a permanent magnet motor having a stator assembly 20 having magnets (not shown) surround an armature 22, which is also the rotor of motor 14. Armature 22, which is also the rotor of motor 14, includes a shaft 24 (
The tool housing 12 may be a clamshell housing having two housing halves 13 (only one of which is shown in
Turning to
The end portion 80 has a double-wall structure and includes an interior wall 82 and an exterior wall 84. The interior wall 82 and the exterior wall 84 are spaced with a space 85 therebetween. The interior wall 82 and the exterior wall 84 merge and are connected at a connecting portion 86. In the illustrative aspect shown in
The space 85 between the interior wall 82 and the exterior wall 84 isolates the interior wall 82 from exterior wall 84 so that when the exterior wall 84 deflects when the power tool 10 is dropped to the ground, the force transmitted to interior wall 82 is reduced. The ribs 88 help increase the deflecting strength of the exterior wall 84 and also absorb a part of the impact energy. With the exterior wall 84 and the ribs 88 absorbing a significant portion of the impact energy, less of the impact energy is transferred to the interior wall 82 and then to the motor 14. Therefore, the tool housing 12 with the double-wall end portion 80 has enhanced impact resistance to protect the motor 14 without significantly increasing the weight of the power tool 10. In an aspect, the end portion 80 having the double wall structure surrounds the commutator and brushes of motor 14 as maintaining the alignment of the brushes and commutator is important and this alignment tends to be sensitive to impact.
With the presence of the space 85 between the interior wall 82 and the exterior wall 84, the tool housing 12 also has the advantage of improved air circulation. Because the space 85 provides more room for air ventilation, the heat generated from the motor 14 can be dissipated relatively quickly to the ambient environment.
It should be understood and appreciated that while the end portion 80 of tool housing 12 is shown to extend over the entire rear portion 58 of the motor 14, the end portion 80 can extend over only a part of the rear portion 58. Alternatively, the end portion 80 can extend over a significant part of the motor 14 to more effectively protect the motor 14 against dropping.
Further, while the end portion 80 of tool housing 12 has been described and shown as an integral part of the tool housing 12, it should be understand and appreciated that the end portion 80 can be made as a separate component and coupled to the rest of tool housing 12 by any conventional fastening means, such as bosses and screws.
Referring to
The motor 14 is illustratively a permanent magnet motor as described above. As discussed above, it should be understood that motor 14 could be a motor such as a universal series motor in which the stator includes laminations in which field windings are wound. Also, while motor 14 is shown as a frameless motor, it should be understood that motor 14 could be a motor having a frame.
The tool housing 312 may be a clamshell housing having two housing halves 313 (only one of which is shown in
Turning to
The end portion 380 has a double-wall structure and includes an interior wall 382 and an exterior wall 384. The interior wall 382 and the exterior wall 84 are spaced with a space 385 therebetween. In the illustrative aspect shown in
The space 385 between the interior wall 382 and the exterior wall 384 isolates the interior wall 382 from exterior wall 384 so that when the exterior wall 384 deflects when the power tool 30 is dropped to the ground, the force transmitted to interior wall 382 is reduced. The ribs 388 help increase the deflecting strength of the exterior wall 384 and also absorb a part of the impact energy. With the exterior wall 384 and the ribs 388 absorbing a significant portion of the impact energy, less of the impact energy is transferred to the interior wall 82 and then to the motor 14. Therefore, the tool housing 312 with the double-wall end portion 380 has enhanced impact resistance to protect the motor 14 without significantly increasing the weight of the power tool 310. In an aspect, the end portion 380 having the double wall structure surrounds the commutator and brushes of motor 14 as maintaining the alignment of the brushes and commutator is important and this alignment tends to be sensitive to impact.
With the presence of the space 385 between the interior wall 382 and the exterior wall 384, the tool housing 312 also has the advantage of improved air circulation. Because the space 385 provides more room for air ventilation, the heat generated from the motor 14 can be dissipated relatively quickly to the ambient environment.
It should be understood and appreciated that while the end portion 380 of tool housing 312 is shown to extend over the entire rear portion 58 of the motor 14, the end portion 380 can extend over only a part of the rear portion 58. Alternatively, the end portion 380 can extend over a significant part of the motor 14 to more effectively protect the motor 14 against dropping.
Further, while the end portion 380 of tool housing 312 has been described and shown as an integral part of the tool housing 312, it should be understand and appreciated that the end portion 380 can be made as a separate component and coupled to the rest of tool housing 312 by any conventional fastening means, such as bosses and screws.
The description of the invention is merely exemplary in nature and, thus, variations that do not depart from the gist of the invention are intended to be within the scope of the invention. Such variations are not to be regarded as a departure from the spirit and scope of the invention.
This application claims the benefit of U.S. Provisional Application No. 60/001,875, filed on Nov. 5, 2007. The entire disclosure of the above application is incorporated herein by reference.
Number | Date | Country | |
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61001875 | Nov 2007 | US |