The present disclosure is related to a fan, and more particularly, to an axial flow fan.
When the conventional axial flow fan is assembled, the impeller is mounted in the housing via an opening of the housing. Thus, a maximum outer diameter of the impeller cannot be larger than an inner diameter of the opening. Such structure limits the size of the maximum outer diameter of the impeller and the inner diameter of the opening, the shape of the impeller and the shape of the housing cannot be designed flexibly to suit the practical demand.
The present invention provides an axial flow fan. The axial flow fan includes an impeller and a fan frame. The impeller has a maximum outer diameter. The fan frame includes a first body and a second body. The first body includes a plurality of connecting elements and a base. The connecting elements are connected to the base. The second body is a hollow body, and used for disposing around the impeller. The second body includes a flow passage having a minimum inner diameter. The minimum inner diameter of the flow passage is not larger than the maximum outer diameter of the impeller.
The axial flow fan of the invention utilizes the first body and the second body to combine to form the fan frame so that the minimum inner diameter of the flow passage is not larger than the maximum outer diameter of the impeller. Therefore, the size of the second body does not restrict the maximum outer diameter of the impeller, and the shape of the impeller and the shape of the fan frame can be designed flexibly according to the practical demand. Furthermore, using a first combining portion and a second combining portion, the first body and the second body can be combined or disassembled.
The details of one or more embodiments of the disclosure are set forth in the accompanying drawings and the description below. Other features and advantages of the disclosure will be apparent from the description, drawings and claims.
Like reference symbols in the various drawings indicate like elements.
That is, the second body 50 is a narrow structure on the top and a wide structure on the bottom, and the minimum inner diameter D2 is on the top of the second body 50. Because the minimum inner diameter D2 of the flow passage 60 is not larger than the maximum outer diameter D1 of the impeller 20, the impeller 20 cannot be mounted from the top of the second body 50. Thus, the impeller 20 is mounted on the base 402 of the first body 40 firstly, then the second body 50 is mounted around the impeller 20. The second body 50 and the first body 40 combine to form the axial flow fan 10.
The axial flow fan 10 of the invention utilizes the first body 40 and the second body 50 to combine to form the fan frame 30 so that the minimum inner diameter D2 of the flow passage 60 is not larger than the maximum outer diameter D1 of the impeller 20. Therefore, the size of the second body 50 does not restrict the maximum outer diameter D1 of the impeller 20, and the shape of the impeller 20 and the shape of the fan frame 30 can be designed flexibly according to the practical demand.
The first body 40 further includes a first side wall 41, a first edge 42 and at least one first combining portion 43, 44. The first edge 42 is formed on the first side wall 41. The at least one first combining portions 43, 44 are formed on the first edge 42, and extend along the first side wall 41 and the first edge 42. In an embodiment, the first body 40 includes four first combining portions 43, 44. Two first combining portions 43 are the same structures, and two first combining portions 44 are the same structures.
The second body 50 includes a second side wall 51, a second edge 52 and at least one second combining portion 53, 54. The second edge 52 is formed under the second side wall 51. The at least one second combining portions 53, 54 are formed on the second edge 52, and extend along the second side wall 51 and the second edge 52. The disposing places of the at least one second combining portion 53, 54 are corresponding to those of the at least one first combining portion 43, 44 so as to combine the at least one first combining portion 43, 44 and the at least one second combining portion 53, 54, respectively. In an embodiment, the second body 50 includes four second combining portions 53, 54. Two second combining portions 53 are the same structures, and are corresponding to the two first combining portions 43. Two second combining portions 54 are the same structures, and are corresponding to the two first combining portions 44.
The second edge 52 defines a first opening 55. An inner diameter D3 of the first opening 55 is larger than the maximum outer diameter D1 of the impeller 20. As stated in the above, the impeller 20 is mounted on the base 402 of the first body 40 firstly, then via the first opening, the second body 50 is mounted around the impeller 20 so as to smoothly assemble the impeller 20 and the second body 50.
In an embodiment, the first combining portion 43 includes a first extending portion 431 extending along the first side wall 41 and the first edge 42. That is, the first extending portion 431 extends along a peripheral direction of the first side wall 41. A first guiding slot 436 is defined between the first extending portion 431 and the first edge 42. The second combining portion 53 includes a limiting protrusion 531 extending along the second side wall 51 and the second edge 52. By appropriate positioning, the second body 50 is disposed on the first body 40, and a force is exerted appropriately to rotate the first body 40 or the second body 50 so that the limiting protrusion 531 is mounted in the first guiding slot 436, and the first extending portion 431 is disposed on the limiting protrusion 531 so as to combine the first body 40 and the second body 50.
The first extending portion 431 includes a first positioning recess 432 formed on the inner wall of the first extending portion 431. The second combining portion 53 further includes a first positioning protrusion 532 formed above the limiting protrusion 531. The disposing place of the first positioning protrusion 532 is corresponding to that of the first positioning recess 432, and the shape of the first positioning protrusion 532 is corresponding to that of the first positioning recess 432. Therefore, after the limiting protrusion 531 is mounted in the first guiding slot 436, the first positioning protrusion 532 is mounted in the first positioning recess 432 to position and combine the first body 40 and the second body 50.
The first extending portion 431 further includes a first positioning hook 433 extending downward. The limiting protrusion 531 includes a second positioning hook 533 extending upward. After the limiting protrusion 531 is mounted in the first guiding slot 436, the first positioning hook 433 is disposed outside of the second positioning hook 533 so that the first positioning hook 433 and the second positioning hook 533 are locked and positioned each other to further position and combine the first body 40 and the second body 50.
The first combining portion 43 further includes a second positioning protrusion 434 disposed on an inner side of the first side wall 41, and extending inward. The second combining portion 53 further includes a second extending portion 534 formed on the second edge 52 and extending downward. The second extending portion 534 includes a second guiding slot 535. The disposing place of the second extending portion 534 is corresponding to that of the second positioning protrusion 434, and the shape of the second positioning protrusion 434 is corresponding to that of the second guiding slot 535. Therefore, when the limiting protrusion 531 is mounted in the first guiding slot 436, on the inner side of the first side wall 41, the second positioning protrusion 434 is mounted in the second guiding slot 535 so as to further position and combine the first body 40 and the second body 50.
Using the above structures of the first combining portion 43 and the second combining portion 53, the first body 40 and the second body 50 can be combined smoothly. After the first body 40 and the second body 50 are assembled, the first body 40 and the second body 50 can be disassembled by an exerted force appropriately to rotate the first body 40 and the second body 50 in a reverse direction. Thus, the first body 40 and the second body 50 can be disassembled, and the structures of the first combining portion 43 and the second combining portion 53 will not be broken.
Because the structure of the first combining portion 43 is different from that of the first combining portion 44, and the structure of the second combining portion 53 is different from that of the second combining portion 54, the first combining portion 44 and the second combining portion 54 are shown from different view angle.
Using the structure of the third positioning protrusion 441 and the second positioning recess 541, the first body 40 and the second body 50 can be combined and assembled only from a specific position so as to prevent the mistake during assembling and to improve the assembling efficiency and quality.
While the embodiment of the present invention have been illustrated and described, various modifications and improvements can be made by those skilled in the art. The embodiments of the present invention are therefore described in an illustrative but not restrictive sense. It is intended that the present invention may not be limited to the particular forms as illustrated, and all modifications that maintain the spirit and scope of the present invention are within the scope as defined in the appended claims.
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