This application claims the benefit of the Chinese Patent Application No. 201420735934.5 filed on Nov. 28, 2014 in the State Intellectual Property Office of China, the whole disclosure of which is incorporated herein by reference.
1. Field of the Invention
The present disclosure relates to a fixing structure, and particularly, to a spring fixing structure.
2. Description of the Related Art
However, the louver 3 is not mounted on the body when it is packed and delivered. As such, in the case that the splayed spring 2 is placed perpendicular to the louver 3, two ends of the splayed spring 2 splay outwards, so that it is not convenient to receive the splayed spring 2 in the louver 3. Thus in the prior art, the connection between the splayed spring 2 and the louver 3 is a moveable connection, so that the splayed spring 2 can be laid and received in the louver 3, thereby saving a packing space.
However, the splayed spring 2 will shake during transportation because the louver 3 is not mounted on the body and the connection between the splayed spring 2 and the louver 3 is a moveable connection. As such, other components such a spiral casing, fan blades or the like may easily be hooked by the splayed spring 2 due to its shake, so that the splayed spring 2 is stretched and deformed, which adversely affects mounting of the louver 3 on the body.
An object of the present invention is to provide a spring fixing structure, which can be easily disposed on the louver and prevent the spring from being deformed.
In order to achieve the above object, the present disclosure provides a spring fixing structure, comprising a louver provided with a stopping member and a louver fixation portion thereon, and a spring disposed on the louver, the spring comprising a spring fixation portion fixed on the louver fixation portion and two arcuate spring legs, wherein the stopping member is provided with a retaining mechanism for retaining the spring.
According to an embodiment, an imaginary line is defined by linearly extending a bottom of the spring fixation portion in a direction in which the spring legs extend in a horizontal direction of the louver, and a perpendicular distance from the stopping member to the imaginary line is smaller than a perpendicular distance from the highest points of both of the two arcuate spring legs to the imaginary line when the spring is horizontally laid on the louver.
According to an embodiment, the retaining mechanism is a retaining tab provided on the stopping member.
According to an embodiment, the stopping member is in a form of a cross bar.
According to an embodiment, the corners of the retaining tab are chamfered or rounded.
According to an embodiment, the retaining tab is located at a position corresponding to the highest point of the arcuate spring leg.
According to an embodiment, the corners of the retaining tab are chamfered or rounded.
According to an embodiment, the retaining mechanism is a recess or notch provided in the stopping member, the recess or notch being located at a position corresponding to the highest point of the arcuate spring leg.
According to an embodiment, a hanging part is provided on a side of the retaining tab facing the imaginary line to protrude downwards.
The advantage of the embodiments of the present disclosure is that the spring can be easily mounted on the louver and prevented from being deformed.
As shown in
The spring fixation portion 21 near a center of the spring 2 is fixed to the louver fixation portion 5 of the louver 3; then, in order that the spring 2 can be, after being laid, fixed to the retaining mechanism, such as the retaining tabs 6, of the stopping member 4, arranged near the highest points 222 of the two spring legs 22, a force is applied to the spring legs 22 by a worker so that the spring legs 22 are deformed so as to enter the retaining mechanism. Thereafter, the force is released and the deformed spring legs 22 rebound and contact the stopping member 4 due to its resilience.
An imaginary line 7 is defined by extending the louver fixation portion 5 in a horizontal direction parallel to the spring 2. When the spring 2 is laid horizontally on the louver 3, a perpendicular distance from the stopping member 4 to the imaginary line 7 is smaller than a perpendicular distance b from the highest points 222 of both of the two arcuate spring legs 22 to the imaginary line 7.
In the present disclosure, a direction parallel to a main surface of the louver 3 is called as a horizontal direction. Further, a direction perpendicular to the main surface of the louver 3 is called as a vertical direction. Furthermore, the imaginary line 7 is a line linearly extended from the bottom 223 of the spring fixation portion 21 along an extension direction of the spring legs 22 and in the horizontal direction of the louver 3. The imaginary line 7 is opposite to the highest points 22 of the spring legs 22 and is on the side of the lowest points 221 of the spring legs 22. In addition, since the two spring legs 22 are arcuate, the two spring legs 22 have the highest points 222 and the lowest points 221 relative to the imaginary line 7.
When the spring 2 is horizontally laid on the louver 3, the perpendicular distance a from the stopping member 4 to the imaginary line 7 is smaller than the perpendicular distance b from the highest points 222 of both of the two arcuate spring legs 22 to the imaginary line 7. Firstly, a force is applied by the worker so that the spring legs 22 are horizontally deformed towards the louver fixation portion 5. When the spring legs 22 are deformed so that the perpendicular distance b from the highest point 222 to the imaginary line 7 is smaller than the perpendicular distance a from the stopping member 4 to imaginary line 7, an additional force is applied by the worker to slightly press the spring legs 22 downwards, thereby spring legs 22 can be located between the retaining tabs 6 integrated with stopping member 4 and the louver 3. Then, no force is applied by the worker to the spring legs 22, the spring 2 will rebound towards the stopping member 4 under a spring force generated due to deformation; since the stopping member 4 and the retaining tabs 6 are respectively arranged in the horizontal direction and the vertical direction in which the spring 2 moves, the spring 2 will not move further after contacting the stopping member 4 or the retaining tabs 6. Thus the spring 2 can not return to its original shape, but rather, is tightly received in a space formed by the stopping member 4 and the retaining tabs 6 and cannot come off the space.
Although the spring 2 is received in the space formed by the stopping member 4 and the retaining tabs 6 and cannot come off from the space, the spring force generated by the spring 2 is large because the spring 2 is in the deformed state. As such, the stopping member 4 is formed in a cross-bar shape, so that the strength of the stopping member 4 may be increased and the contact areas between spring legs 22 and the stopping member 4 may be increased. As a result, the spring 2 can be more firmly clamped and fixed on the stopping member 4.
In addition, as shown in
Further, when a length of the stopping member 4 is set to be equal to or larger than that of the spring 2, the retaining tab 6 may be provided on the stopping member 4 corresponding to any portion of the spring legs 22. However, the retaining tab 6 needs to have a sufficient length in order to limit the spring 2 from rebounding in the vertical direction after being deformed. The length of the retaining tab 6 varies depending on positions. The length means a length of the retaining tab 6 extending towards the imaginary line 7 in the horizontal direction, which length will be changed according the shape of the arcuate spring leg 22. That is, the nearer the retaining tab 6 is provided relative to the highest point 222 of the arcuate spring leg 22, the shorter the length of the retaining tab 6 may be; in contrast, the nearer the retaining tab 6 is provided relative to the lowest point 221 of the arcuate spring leg 22, the longer the length of the retaining tab 6 is.
Further, the longer the retaining tab 6 is, the smaller the strength of the retaining tab 6; moreover, the force for deforming the spring leg 22 will be larger in order to receive the spring leg 22 in the space formed by the retaining tab 6 and the louver 3. Thus, when the retaining tab 6 is provided on the stopping member 4 at a position corresponding to the highest point 222 of the arcuate spring leg 22, the length of the retaining tab 6 may be set to be shortest, a material for manufacturing the retaining tab 6 may be smallest, and the strength of the retaining tab 6 may be largest. In other words, the force for deforming the spring leg 22 may be smallest, resulting in the easiest operation for the worker.
The corners of the retaining tab 6 are all rounded or chamfered. The deformation of the spring 2 needs to be manually operated by the worker, thus it is likely that the worker may contact the retaining tab 6; when a plurality of chamfers are provided on the corners of the retaining tab 6, the chamfered retaining tab 6 is not sharp, thus the hand of the worker will not be easily scratched even if the worker contacts the retaining tab 6. In addition, the area of the retaining tab 6 is reduced compared to its original shape, which can reduce the possibility that the worker contacts the retaining tab 6, thereby greatly improving safety of operation.
The difference between the second embodiment and the first embodiment is only in that the retaining mechanism of the first embodiment comprises the retaining tabs 6 (see
Also, during mounting, a force is applied by the worker to horizontally deform the spring legs 22 towards the louver fixation portion 5. The spring legs 22 are deformed so that the perpendicular distance b from the highest point 222 to the imaginary line 7 is smaller than the perpendicular distance a from the stopping member 4 to imaginary line 7. Then, no force is applied by the worker to the spring legs 22, the spring 2 will generate a resilient force due to deformation so that the spring 2 rebounds towards the stopping member 4. At this time, since the recesses or notches 8 are provided in the stopping member 4 at the positions corresponding to the highest points 222 of the arcuate spring leg 22, the highest points 222 of the spring leg 22 will contact the recesses or notches 8, then the spring 2 is clamped into the recesses or notches 8 under the resilient force. Therefore, the spring 2 can be simply disposed on the louver 3 and prevented from being deformed.
Number | Date | Country | Kind |
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201420735934.5 | Nov 2014 | CN | national |