The present invention relates generally to a cooling fan, and more particularly to a fan frame body structure, which can guide the high-pressure airflow produced at the outlet of the fan to jet to the inlet so as to achieve multiple noise-lowering effects.
The noise made by the fan in operation is always one of the problems existing in the field of fans to be improved. The conventional technical means for solving the fan noise problem is to use a circuit to control the rotational speed or change the fan structure. A conventional technique employs an airflow jet disposed on the dynamic blades or the frame wall of the static blades to restrain the vortex. However, it is necessary to add an external connected airflow jet source to the fan. This cannot be achieved in a limited space. In addition, the extra external connected airflow jet source will lead to increase of the cost.
It is therefore tried by the applicant to provide a fan frame body structure, which can lower the noise of the fan in operation without using any additional equipment.
It is therefore a primary object of the present invention to provide a fan frame body structure, in which a self-airflow jet structure is disposed on the fan frame body so that when the fan operates, the noise made at the airflow passage inlet or outlet can be lowered and the airflow amount can be increased.
To achieve the above and other objects, the fan frame body structure of the present invention includes a first frame body. The first frame body has a first upper end, a first lower end, a first frame wall and a first main flow way. The first main flow way passes through the first frame body and is formed with a first main inlet and a first main outlet respectively at the first upper end and the first lower end. A first subsidiary flow way is disposed in the first frame wall. The first subsidiary flow way is in parallel the first main flow way. The first subsidiary flow way is positioned on outer side of the first main flow way and has a first subsidiary outlet and a first subsidiary inlet. The first subsidiary outlet is positioned at the first upper end of the first frame body in flush with and in adjacency to the first main inlet. The first subsidiary inlet is adjacent to the first lower end of the first frame body in communication with the first main flow way.
In the structural design of the present invention, the first subsidiary flow way is formed in the first frame wall. When the airflow flows in from the first main inlet of the first frame body and flows to the first main outlet, the airflow will pour from the first subsidiary inlet into the first subsidiary flow way and finally exhaust from the first subsidiary outlet. The airflow is jetted to the first main inlet of the first frame body. Therefore, the problem of noise made by the fan in operation is greatly improved and the airflow amount is increased.
In addition, the first subsidiary flow way is disposed in parallel to the first main flow way. This facilitates the demolding operation of the first frame body, which is made by means of injection molding.
The structure and the technical means adopted by the present invention to achieve the above and other objects can be best understood by referring to the following detailed description of the preferred embodiments and the accompanying drawings, wherein:
Please refer to
A first subsidiary flow way 104 is disposed in the first frame wall 102. The first subsidiary flow way 104 is spaced from the first main flow way 103 in parallel thereto. The first subsidiary flow way 104 is positioned on outer side of the first main flow way 103 and has a first subsidiary outlet 1040 and a first subsidiary inlet 1041. The first subsidiary outlet 1040 is positioned at the first upper end 100 of the first frame body 10 in flush with and in adjacency to the first main inlet 1030. The first subsidiary inlet 1041 is adjacent to the first lower end 101 of the first frame body 10 in communication with the first main flow way 103.
To speak more specifically, the first frame wall 102 has a first section 102a and a second section 102b. The first section 102a is adjacent to the first main flow way 103. The first subsidiary flow way 104 is positioned between the first and second sections 102a, 102b. In addition, the first subsidiary flow way 104 is partitioned from the first main flow way 103 by the first section 102a.
Moreover, a first fan impeller seat 11 is disposed in the first main flow way 103. The first fan impeller seat 11 has multiple first connection members 111 radially outward extending from the first fan impeller seat 11. The first connection members 111 are connected with the first frame wall 102 to support the first fan impeller seat 11 at the first main outlet 1031. A first bearing cup 110 vertically extends from the center of the first fan impeller seat 11. A first fan impeller set 12 is fitted around the first bearing cup 110. A first bearing 13 is disposed in the first bearing cup 110. The first fan impeller set 12 has a first hub 120 and multiple first blades 121 disposed on an outer circumference of the first hub 120. A first shaft 14 is inserted in the center of the inner side of the first hub 120. The first shaft 14 is rotatably disposed in the first bearing 13.
Accordingly, by means of the design of the present invention, the airflow 4 at the first main outlet 1031 is guided to enter the first subsidiary flow way 104 from the first subsidiary inlet 1041 and finally exhaust from the first subsidiary outlet 1040. The airflow 4 is jetted to the first main inlet 1030 of the first main flow way 103 of the first frame body 10. Therefore, the noise made at the first main inlet 1030 of the first frame body 10 can be greatly reduced and the airflow amount is increased.
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A third subsidiary flow way 304 is disposed in the third frame wall 302. The third subsidiary flow way 304 is spaced from the third main flow way 303 in parallel thereto. The third subsidiary flow way 304 is positioned on outer side of the third main flow way 303 and has a third subsidiary inlet 3040 and a third subsidiary outlet 3041. The third subsidiary inlet 3040 is positioned at the third lower end 301 of the third frame body 30 and slightly lower than the third main inlet 3030 in parallel thereto. The third subsidiary outlet 3041 is adjacent to the third end 300 of the third frame body 30. The first and third subsidiary flow ways 103, 304 of the first and third frame bodies 10, 30 are in communication with each other or not in communication with each other. In this embodiment, the first and third subsidiary flow ways 103, 304 of the first and third frame bodies 10, 30 are in communication with each other for illustration purposes.
The bottom sections of the first and third frame bodies 10, 30 are serially connected with each other. The first and third connection members 111, 311 are disposed on the serially connected sections. The airflow 4 flows into the first and third main flow ways 103, 303 from the upper first main inlet 1030 of the first frame body 10. Then the airflow 4 flows to the first main outlet 1031. Due to the first and third connection members 111, 311, the airflow 4 is boosted to create greater pressure. Part of the airflow 4 flows from the first subsidiary inlet 1041 into the first subsidiary flow way 104 to exhaust from the first subsidiary outlet 1040. Then the airflow 4 is jetted to the upper first main inlet 1030 of the first main flow way 103 of the first frame body 10. Other part of the airflow 4 flows to the lower third subsidiary inlet 3040 of the third frame body 30 into the third subsidiary flow way 304 to exhaust from the third subsidiary outlet 3041. Then the airflow 4 is jetted to the lower third main outlet 3031 of the third main flow way 303 of the third frame body 30. Therefore, the problem of noise made at the upper first main inlet 1030 of the first frame body 10 and the lower third main outlet 3031 of the third frame body 30 is improved. Accordingly, after serially connected, the upper first frame body 10 and the lower third frame body 30 have self-airflow jetting effect.
This can greatly improve the noise problem of the fan in operation. In conclusion, in comparison with the conventional fan, the present invention has the following advantages:
The present invention has been described with the above embodiments thereof and it is understood that many changes and modifications in such as the form or layout pattern or practicing step of the above embodiments can be carried out without departing from the scope and the spirit of the invention that is intended to be limited only by the appended claims.
The present application is a continuation of U.S. patent application Ser. No. 16/920,432, filed on Jul. 3, 2020.
Number | Date | Country |
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202301183 | Jul 2012 | CN |
202520644 | Nov 2012 | CN |
103967812 | Aug 2014 | CN |
106979178 | Jul 2017 | CN |
108412816 | Aug 2018 | CN |
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20180125221 | Nov 2018 | KR |
M565243 | Aug 2018 | TW |
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Entry |
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Search Report dated Jan. 21, 2021 issued by Taiwan Intellectual Property Office for counterpart application No. 109122262. |
Search Report dated Mar. 29, 2021 issued by China National Intellectual Property Administration for counterpart application No. 202010620975X. |
Number | Date | Country | |
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20230016990 A1 | Jan 2023 | US |
Number | Date | Country | |
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Parent | 16920432 | Jul 2020 | US |
Child | 17948242 | US |