This application is the National Stage of International Application No. PCT/JP2015/055673, filed 26 Feb. 2015, having the title “BENT PIPE STRUCTURE” which claims the benefit of and priority to Japanese Application No. 2014-055591, filed on 18 Mar. 2014, the contents of all of which are incorporated by reference as if fully set forth herein.
The present invention relates to a bent pipe structure to be employed in a bent part of piping that configures a fluid flow path.
Patent Document 1 (Japanese Patent Application Laid-Open (JP-A) No. 2001-219453) describes a bent pipe molding mold configured from an outer mold and an inner mold. The outer mold, which forms an outer face of the bent pipe, is configured by a two-piece split mold structure for molding the outer face of the bent pipe. The inner mold, which forms an inner face of the bent pipe, has a structure that is configured by members capable of being separated from each other or combined with each other in directions relatively approaching or moving apart along a direction of an axial line of the bent pipe.
However, in the configuration described in Patent Document 1, a curved portion at a bend direction inside of a bend of a pipe body is configured by a sharp corner (namely, R=0) rather than by a circular arc shape. Therefore, there is an increase in pressure drop in fluid flowing through the bend.
An object of the present invention is, in a bend of a pipe body, to mitigate an increase in pressure drop in fluid flowing through the bend.
A bent pipe structure of a first aspect of the present invention includes a pipe body that includes a bend, and a cross-sectional area enlargement portion that is formed by configuring a curved portion with a circular arc shape at an inner circumferential face on a bend direction inside of the bend so as to enlarge a cross-sectional area of a flow path of the pipe body. The cross-sectional area enlargement portion includes a pair of side face portions that face each other along an orthogonal direction orthogonal to an axial line of the pipe body, and a bottom face portion that couples lower ends of the side face portions together. When viewed along the direction of the axial line, the cross-sectional area enlargement portion is formed in a curved shape that protrudes toward an outer circumferential side of the pipe body. The bent pipe structure satisfies the following relationships, wherein P (mm) denotes the inner diameter of the pipe body, H (mm) denotes the separation distance between the pair of side face portions, as viewed along the direction of the axial line, and R (mm) denotes the radius of the curved portion:
R=1 when P=6 and H=1,
R=1 when P=6 and H=2,
R=1 or greater and R=2 or less when P=6 and H=3,
R=1 when P=6 and H=4,
R=3 or greater and R=5 or less when P=16 and H=5,
R=3 or greater and R=5 or less when P=16 and H=7,
R=3 or greater and R=7 or less when P=16 and H=9,
R=3 or greater and R=7 or less when P=16 and H=11,
R=3 or greater and R=5 or less when P=16 and H=13,
R=3 when P=16 and H=15,
R=7 when P=23 and H=8,
R=7 when P=23 and H=10,
R=7 when P=23 and H=12,
R=7 when P=23 and H=14,
R=7 or greater and R=10 or less when P=23 and H=16,
R=7 when P=23 and H=18, and
R=7 when P=23 and H=20.
According to the above configuration, the cross-sectional area enlargement portion is formed by configuring the curved portion of the inner circumferential face with a circular arc shape at the inner circumferential face on a bend direction inside of the bend of the pipe body so as to enlarge a cross-sectional area of the flow path of the pipe body. Moreover, when viewed along the direction of the axial line, the cross-sectional area enlargement portion is formed in a curved shape that protrudes toward an outer circumferential side of the pipe body.
The bent pipe structure satisfies specific relationships, where P (mm) denotes the inner diameter of the pipe body, H (mm) denotes the separation distance between the pair of side face portions, as viewed along the direction of the axial line, and R (mm) denotes the radius of the curved portion.
Accordingly, an increase in pressure drop in fluid flowing through the bend may be mitigated at the bend of the pipe body.
A bent pipe structure of a second aspect of the present invention includes a pipe body that includes a bend and a cross-sectional area enlargement portion that is formed by configuring a curved portion with a circular arc shape at an inner circumferential face on a bend direction inside of the bend so as to enlarge a cross-sectional area of a flow path of the pipe body. The cross-sectional area enlargement portion includes a pair of side face portions that face each other along an orthogonal direction orthogonal to an axial line of the pipe body, and a bottom face portion that couples lower ends of the side face portions together. When viewed along the direction of the axial line, the side face portions are formed with straight lines and the bottom face portion is formed in a curved shape that protrudes toward an outer circumferential side of the pipe body. The bent pipe structure satisfies the following relationships, wherein P (mm) denotes the inner diameter of the pipe body, H (mm) denotes the separation distance between the pair of side face portions, as viewed along the direction of the axial line, and R (mm) denotes the radius of the curved portion.
R=2 or greater and R=3 or less when P=6 and H=1,
R=2 when P=6 and H=2,
R=7 or greater and R=11 or less when P=16 and H=5,
R=7 or greater and R=9 or less when P=16 and H=7,
R=7 or greater and R=16 or less when P=23 and H=6,
R=10 or greater and R=13 or less when P=23 and H=8,
R=10 or greater and R=13 or less when P=23 and H=10,
R=10 or greater and R=13 or less when P=23 and H=12, and
R=10 when P=23 and H=14.
According to the above configuration, the cross-sectional area enlargement portion is formed by configuring the curved portion of the inner circumferential face with a circular arc shape at the inner circumferential face on a bend direction inside of the bend of the pipe body so as to enlarge a cross-sectional area of the flow path of the pipe body. Moreover, when viewed along the direction of the axial line, the side face portions are formed with straight lines and the bottom face portion is formed in a curved shape that protrudes toward an outer circumferential side of the pipe body.
The bent pipe structure satisfies specific relationships, where P (mm) denotes the inner diameter of the pipe body, H (mm) denotes the separation distance between the pair of side face portions, as viewed along the direction of the axial line, and R (mm) denotes the radius of the curved portion.
Accordingly, an increase in pressure drop in fluid flowing through the bend may be mitigated at the bend of the pipe body.
The present invention is, in a bend of a pipe body, capable of mitigating an increase in pressure drop in fluid flowing through the bend.
Explanation follows regarding an example of a bent pipe structure according to a first exemplary embodiment of the present invention, with reference to
Bent Pipe Structure
As illustrated in
Both end portions 12B of the pipe body 12 are open, and, for example, both end portions 12B are respectively coupled to a hose 18.
As illustrated in
The recess 16 enlarges the cross-sectional area of the flow path at the bend 14, such that when a fluid such as a liquid passes through the inside of the bend 14 (namely, a fluid flowing along arrow W in
Explanation follows regarding the recess 16 of the pipe body 12 in comparison to a pipe body 102 of a bent pipe 100 of a comparative example (namely, a conventional form).
First, explanation is given regarding the pipe body 102 of the bent pipe 100 according to the comparative example.
As illustrated in
A cross-section of the bend 104, sectioned along the bend 104 as viewed along an orthogonal direction that is orthogonal to the direction of the axial line 13 (a direction orthogonal to the first straight line portion 13A and the second straight line portion 13B, and the direction into the page in
In contrast thereto, as illustrated in
A cross-section of the bend 14, sectioned as viewed along the axis orthogonal direction (a cross-section along line J-J in
Specifically, the recess 16 is configured from a pair of side face portions 16B that face each other along the axis orthogonal direction (the arrow Y direction in
Note that as illustrated in
Bent Pipe Molding Mold
Explanation follows regarding a mold employed in molding the pipe body 12.
As illustrated in
As illustrated in
Each hinged core 34 is inserted into the respective grooves 32 of the primary cores 30 so as to be capable of sliding relative to the primary core 30 along the direction of the axial line 13 of the pipe body 12. Note that the inner circumferential face 15 of the pipe body 12 is molded by curved molding faces 30B of the primary cores 30 and curved molding faces 34A of the hinged cores 34. A base portion 36 at one length direction side of each hinged core 34 and a swinging portion 38 at another length direction side of each hinged core 34 are coupled together by a hinge 40.
As illustrated in
Leading ends 38A of the swinging portions 38 of the respective hinged cores 34 correspond to the undercut portion of the recess 16 that is to be formed in the inner circumferential face 15 on the bend direction inside of the bend 14 of the pipe body 12, and have curved shapes that engage with the recess 16.
Namely, in the molding position illustrated in
As illustrated in
As illustrated in
In order to mold the pipe body 12 using the bent pipe molding mold 20 of the present exemplary embodiment, first, a synthetic resin is injected into the space formed between the outer mold 22 and the inner mold 24, and the pipe body 12 of the bent pipe that includes the recess 16 is molded. Then, the outer mold 22 is removed and the inner mold 24 is separated from the pipe body 12.
When this is performed, the pair of primary cores 30 are separated by each being pulled, with respect to each of the pair of hinged cores 34, from the molding position illustrated in
Evaluation
Next, explanation follows regarding an evaluation method, evaluation specifications, evaluation items, and evaluation results that were evaluated by analyzing the pipe body 12 according to the first exemplary embodiment and the pipe body 102 according to the comparative example.
1. Evaluation Method
Analysis was performed using ANSYS Fluent from ANSYS Japan K.K.
The flow rate of fluid flowing through the inside of the pipe body was set to 50 L/min.
The fluid (medium) density of fluid flowing through the inside of the pipe body was set to 1.046 kg/m3 and the fluid (medium) viscosity was set to 0.00191 Pa·s, so as to configure the fluid as cooling water with a 30% concentration (Long Life Coolant: LLC).
2. Evaluation Specifications
(1) The following specifications were used for the present exemplary embodiment.
A pipe body 12 having an inner diameter of 6 mm, a recess 16 having a width H of 1 mm, and a curved portion 14A having a curvature R of 1 mm.
A pipe body 12 having an inner diameter of 6 mm, a recess 16 having a width H of 2 mm, and a curved portion 14A having a curvature R of 1 mm.
A pipe body 12 having an inner diameter of 6 mm, a recess 16 having a width H of 3 mm, and a curved portion 14A having a curvature R of 1 mm or 2 mm.
A pipe body 12 having an inner diameter of 6 mm, a recess 16 having a width H of 4 mm, and a curved portion 14A having a curvature R of 1 mm.
A pipe body 12 having an inner diameter of 16 mm, a recess 16 having a width H of 5 mm, and a curved portion 14A having a curvature R of 3 mm or 5 mm.
A pipe body 12 having an inner diameter of 16 mm, a recess 16 having a width H of 7 mm, and a curved portion 14A having a curvature R of 3 mm or 5 mm.
A pipe body 12 having an inner diameter of 16 mm, a recess 16 having a width H of 9 mm, and a curved portion 14A having a curvature R of 3 mm, 5 mm, or 7 mm.
A pipe body 12 having an inner diameter of 16 mm, a recess 16 having a width H of 11 mm, and a curved portion 14A having a curvature R of 3 mm, 5 mm, or 7 mm.
A pipe body 12 having an inner diameter of 16 mm, a recess 16 having a width H of 13 mm, and a curved portion 14A having a curvature R of 3 mm or 5 mm.
A pipe body 12 having an inner diameter of 16 mm, a recess 16 having a width H of 15 mm, and a curved portion 14A having a curvature R of 3 mm.
A pipe body 12 having an inner diameter of 23 mm, a recess 16 having a width H of 8 mm, and a curved portion 14A having a curvature R of 7 mm.
A pipe body 12 having an inner diameter of 23 mm, a recess 16 having a width H of 10 mm, and a curved portion 14A having a curvature R of 7 mm.
A pipe body 12 having an inner diameter of 23 mm, a recess 16 having a width H of 12 mm, and a curved portion 14A having a curvature R of 7 mm.
A pipe body 12 having an inner diameter of 23 mm, a recess 16 having a width H of 14 mm, and a curved portion 14A having a curvature R of 7 mm.
A pipe body 12 having an inner diameter of 23 mm, a recess 16 having a width H of 16 mm, and a curved portion 14A having a curvature R of 7 mm or 10 mm.
A pipe body 12 having an inner diameter of 23 mm, a recess 16 having a width H of 18 mm, and a curved portion 14A having a curvature R of 7 mm.
A pipe body 12 having an inner diameter of 23 mm, a recess 16 having a width H of 20 mm, and a curved portion 14A having a curvature R of 7 mm.
(2) The following specifications were used for the comparative example.
A pipe body 102 having an inner diameter of 6 mm, and a curved portion 104A having a curvature R of 0 mm (a sharp corner).
A pipe body 102 having an inner diameter of 16 mm, and a curved portion 104A having a curvature R of 0 mm (a sharp corner).
A pipe body 102 having an inner diameter of 23 mm, and a curved portion 104A having a curvature R of 0 mm (a sharp corner).
3. Evaluation Items
(1) The inflow pressure when fluid flows into a pipe body 12 (in (Pa)), and the outflow pressure when fluid flows out from the pipe body 12 (out (Pa)), were derived.
(2) The difference between the inflow pressure and the outflow pressure was derived as the pressure drop (pressure drop (kPa)).
(3) The proportional reduction of pressure drop (pressure drop (%)) in the pipe body 12 according to the present exemplary embodiment, with respect to the pressure drop in a pipe body 102 according to the comparative example of the same internal diameter, was derived.
4. Evaluation Results
(1) Evaluation results of the present first exemplary embodiment for a pipe body 12 configured with an inner diameter of 6 mm are listed in the table in
(2) Evaluation results of the present first exemplary embodiment for a pipe body 12 configured with an inner diameter of 16 mm are listed in the table in
(3) Evaluation results of the present first exemplary embodiment for a pipe body 12 configured with an inner diameter of 23 mm are listed in the table in
Summary
As is apparent from the evaluation results above, the proportional reductions in pressure drop in the pipe body 12 are all positive numerical values. Namely, due to forming the recess 16 configured with a curvature R and a width H as described in the evaluation specifications above in the pipe body 12, an increase in pressure drop in fluid flowing through the bend 14 can be suppressed compared to in the pipe body 102 according to the comparative example.
Second Exemplary Embodiment
Next, explanation follows regarding an example of a bent pipe structure according to a second exemplary embodiment of the present invention, with reference to
Bent Pipe Structure
As illustrated in
A cross-section of the bend 64, sectioned as viewed along the axis orthogonal direction (a cross-section taken along line K-K in
Specifically, the recess 66 is configured from the pair of side face portions 66B and the bottom face portion 66A described above. In the cross-section illustrated in
Evaluation
Next, explanation follows regarding evaluation specifications and evaluation results that were evaluated by analyzing the pipe body 62 according to the second exemplary embodiment and the pipe body 102 according to the comparative example.
1. Evaluation Specifications
(1) The following specifications were used for the present exemplary embodiment.
A pipe body 62 having an inner diameter of 6 mm, a recess 66 having a width H of 1 mm, and a bend portion 64A having a curvature R of 2 mm or 3 mm.
A pipe body 62 having an inner diameter of 6 mm, a recess 66 having a width H of 2 mm, and a bend portion 64A having a curvature R of 2 mm.
A pipe body 62 having an inner diameter of 16 mm, a recess 66 having a width H of 5 mm, and a bend portion 64A having a curvature R of 7 mm, 9 mm, or 11 mm.
A pipe body 62 having an inner diameter of 16 mm, a recess 66 having a width H of 7 mm, and a bend portion 64A having a curvature R of 7 mm or 9 mm.
A pipe body 62 having an inner diameter of 23 mm, a recess 66 having a width H of 6 mm, and a bend portion 64A having a curvature R of 7 mm, 10 mm, 13 mm, or 16 mm.
A pipe body 62 having an inner diameter of 23 mm, a recess 66 having a width H of 8 mm, and a bend portion 64A having a curvature R of 10 mm or 13 mm.
A pipe body 62 having an inner diameter of 23 mm, a recess 66 having a width H of 10 mm, and a bend portion 64A having a curvature R of 10 mm or 13 mm.
A pipe body 62 having an inner diameter of 23 mm, a recess 66 having a width H of 12 mm, and a bend portion 64A having a curvature R of 10 mm or 13 mm.
A pipe body 62 having an inner diameter of 23 mm, a recess 66 having a width H of 14 mm, and a bend portion 64A having a curvature R of 10 mm.
(2) The following specifications were used for the comparative example (these being similar to those of the first exemplary embodiment)
A pipe body 102 having an inner diameter of 6 mm, and a curved portion 104A having a curvature R of 0 mm (a sharp corner).
A pipe body 102 having an inner diameter of 16 mm, and a curved portion 104A having a curvature R of 0 mm (a sharp corner).
A pipe body 102 having an inner diameter of 23 mm, and a curved portion 104A having a curvature R of 0 mm (a sharp corner).
2. Evaluation Results
(1) Evaluation results of the present second exemplary embodiment for a pipe body 62 configured with an inner diameter of 6 mm are listed in the table in
(2) Evaluation results of the present second exemplary embodiment for a pipe body 62 configured with an inner diameter of 16 mm are listed in the table in
(3) Evaluation results of the present second exemplary embodiment for a pipe body 62 configured with an inner diameter of 23 mm are listed in the table in
Summary
As is apparent from the above evaluation results, the proportional reductions in pressure drop in the pipe body 62 are all positive numerical values. Namely, due to forming the pipe body 62 with the recess 66 configured with a curvature R and a width H as described in the evaluation specifications, an increase in pressure drop in fluid flowing through the bend 64 can be suppressed compared to in the pipe body 102 according to the comparative example.
Note that although detailed explanation has been given regarding specific exemplary embodiments of the present invention, the present invention is not limited to these exemplary embodiments, and it would be obvious to a person having ordinary skill in the art that various other exemplary embodiments are possible within the scope of the present invention. For example, the mold configuration explained in the above exemplary embodiments is merely exemplary, and the pipe body may be molded using nested molds or the like.
Number | Date | Country | Kind |
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2014-055591 | Mar 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2015/055673 | 2/26/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2015/141435 | 9/24/2015 | WO | A |
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Entry |
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Written Opinion of the ISA of PCT/JP2015/055673 date of completion May 8, 2015. |
Number | Date | Country | |
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20180128408 A1 | May 2018 | US |