This U.S. National stage application claims priority under 35 U.S.C. § 119(a) to Japanese Patent Application No. 2015-215169, filed in Japan on Oct. 30, 2015, the entire contents of which are hereby incorporated herein by reference.
The present invention relates to a cross-flow fan and particularly a cross-flow fan equipped with blades made of resin.
Cross-flow fans used in indoor units of air conditioning systems, for example, have plural blades that extend in the longitudinal direction of the cross-flow fan and are disposed between annular partition plates disposed on both longitudinal direction ends of the cross-flow fan. Additionally, as disclosed in JP-A No. 2014-47772, for example, there are cases where a reinforcement ring is disposed between support plates to reinforce the strength of the plural blades.
The cross-flow fan disclosed in JP-A No. 2014-47772 has an auxiliary ring disposed in the longitudinal direction middle section of the blades, but with this configuration also, owing to an increase in the diameter of the fan blocks and a lengthening of the blade length to improve performance in recent years, there is a tendency for shifts to become greater in the positions of the distal ends of the blades of each fan block because of, for example, thermal contraction of the resin when molding the fan blocks. When positional shifts occur in the distal ends of the blades of the fan blocks in this way, not only does it become difficult to align the fan blocks when joining together the fan blocks by ultrasonic welding, for example, and require extra manufacturing time, but alignment of the distal ends of the blades must be forcibly performed, so it becomes easier for torsion to arise in the blades, resulting, for example, in the occurrence of noise and a reduction in blowing performance.
It is a problem of the present invention to provide a cross-flow fan that is inexpensive and has good performance.
A cross-flow fan pertaining to a first aspect of the invention is a cross-flow fan that is made of resin and includes a first fan block and a second fan block that are joined together, wherein the first fan block is equipped with a disc-shaped or annular first support plate, plural first blades having first one-side distal ends connected to the first support plate, and a first outer peripheral ring having a first ring portion that interconnects outer ends of the plural first blades in the neighborhood of first other-side distal ends of the plural first blades located on the opposite side of the first one-side distal ends, the second fan block is equipped with a disc-shaped or annular second support plate, plural second blades having second one-side distal ends connected to the second support plate, and a second outer peripheral ring having a second ring portion that interconnects outer ends of the plural second blades in the neighborhood of second other-side distal ends of the plural second blades located on the opposite side of the second one-side distal ends, the second other-side distal ends of the plural second blades are joined to the first support plate, and the first support plate and the second outer peripheral ring are disposed in close proximity to each other.
According to the cross-flow fan pertaining to the first aspect, because the second other-side distal ends of the plural second blades are joined to the first support plate, and the first support plate and the second outer peripheral ring are disposed in close proximity to each other, shifts in the positions of the second other-side distal ends of the plural second blades of the second fan block can be prevented by the second outer peripheral ring, so when aligning the plural second blades and the first support plate there is no longer the need to correct shifts in the positions of the plural second blades that have shifted positions.
A cross-flow fan pertaining to a second aspect of the invention is the cross-flow fan of the first aspect, wherein the first support plate, the plural first blades, and the first outer peripheral ring of the first fan block are integrally molded, and the second support plate, the plural second blades, and the second outer peripheral ring of the second fan block are integrally molded.
According to the cross-flow fan pertaining to the second aspect, because the first support plate, the plural first blades, and the first outer peripheral ring are integrally molded and the second support plate, the plural second blades, and the second outer peripheral ring are integrally molded, the first one-side distal ends of the plural first blades of the first fan block are fixed by the first support plate and the first other-side distal ends are fixed by the first outer peripheral ring, so that it becomes difficult for the first fan block to become deformed. Furthermore, the second one-side distal ends of the plural second blades of the second fan block are fixed by the second support plate and the second other-side distal ends are fixed by the second outer peripheral ring, so that it becomes difficult for the second fan block to become deformed. As a result, the dimensional accuracy of the first fan block and the second fan block when joining together the first fan block and the second fan block is improved.
A cross-flow fan pertaining to a third aspect of the invention is the cross-flow fan of the first aspect or the second aspect, wherein the second other-side distal ends of the plural second blades of the second fan block are positioned in a place where they project toward the opposite side of the second one-side distal ends from the second outer peripheral ring.
According to the cross-flow fan pertaining to the third aspect, because the second other-side distal ends of the plural second blades are positioned in a place where they project toward the opposite side of the second one-side distal ends from the second outer peripheral ring, it becomes possible to ensure that the second outer peripheral ring and first support plate are not joined together while joining together the second other-side distal ends of the plural second blades and the first support plate of the first fan block using ultrasonic welding, for example, the joining together of the first fan block and the second fan block can be performed strongly and inexpensively, and the occurrence of noise can be suppressed by not joining together the second outer peripheral ring and the first support plate.
A cross-flow fan pertaining to a fourth aspect of the invention is the cross-flow fan of any of the first aspect to the third aspect, wherein the first support plate has a down-step portion at which the section of the first support plate corresponding to the second outer peripheral ring is sunken below the section of the first support plate corresponding to the inner peripheral side of the second outer peripheral ring, and the second outer peripheral ring enters the down-step portion, thereby reducing the longitudinal direction thickness with which the first support plate and the second outer peripheral ring lie on top of each other.
According to the cross-flow fan pertaining to the fourth aspect, because the second outer peripheral ring enters the down-step portion of the first support plate, thereby reducing the longitudinal direction thickness with which the first support plate and the second outer peripheral ring lie on top of each other, workability can be improved while suppressing a worsening of air flow resistance caused by the first support plate and the second outer peripheral ring and stopping a worsening of power consumption.
A cross-flow fan pertaining to a fifth aspect of the invention is the cross-flow fan of the fourth aspect, wherein the down-step portion of the first support plate is sunken deeper than the longitudinal direction thickness of the second outer peripheral ring in the longitudinal direction.
According to the cross-flow fan pertaining to the fifth aspect, because the down-step portion of the first support plate is sunken deeper than the longitudinal direction thickness of the second outer peripheral ring in the longitudinal direction, the thickness of the section where the second outer peripheral ring and the first support plate lie on top of each other can be made thin up to the thickness of the first support plate, and a worsening of air flow resistance can be sufficiently suppressed.
A cross-flow fan pertaining to a sixth aspect of the invention is the cross-flow fan of either the fourth aspect or the fifth aspect, wherein the first support plate further has welding ribs that are welded to the second other-side distal ends of the plural second blades, and the welding ribs are formed in such a way as to extend to the down-step portion, with the height of sections of the welding ribs positioned in the down-step portion being lower than the height of sections of the welding ribs on the inner peripheral side of the down-step portion.
According to the cross-flow fan pertaining to the sixth aspect, because the welding ribs are formed in such a way as to extend to the down-step portion, with the height of the sections of the welding ribs positioned in the down-step portion being lower than the height of the sections of the welding ribs on the inner peripheral side of the down-step portion, projection of welding burrs into the down-step portion can be suppressed while strongly connecting the first support plate and the plural second blades to each other by ultrasonic welding.
A cross-flow fan pertaining to a seventh aspect of the invention is the cross-flow fan of any of the first aspect to the sixth aspect, wherein the second outer peripheral ring has an outer radius that is the same as or smaller than an outer radius of the first support plate.
According to the cross-flow fan pertaining to the seventh aspect, because the second outer peripheral ring has the outer radius that is the same as or smaller than the outer radius of the first support plate, in comparison to a case where the outer radius of the second outer peripheral ring is larger than that of the first support plate, the risk of contact with a casing that covers the outer portion of the cross-flow fan, for example, can be suppressed.
A cross-flow fan pertaining to an eighth aspect of the invention is the cross-flow fan of any of the first aspect to the seventh aspect, wherein the second outer peripheral ring further has reinforcement ribs that are connected to negative pressure surfaces of the plural second blades but are not connected to pressure surfaces of the plural second blades.
According to the cross-flow fan pertaining to the eighth aspect, because the second outer peripheral ring has the reinforcement ribs that are connected to the negative pressure surfaces of the plural second blades but are not connected to the pressure surfaces of the plural second blades, the ability to withstand external force applied to the second blades can be enhanced.
A cross-flow fan pertaining to a ninth aspect of the invention is the cross-flow fan of any of the fourth aspect to the sixth aspect, wherein the first support plate further has thinned portions provided in such a way as not to not reach the down-step portion.
According to the cross-flow fan pertaining to the ninth aspect, because the first support plate has the thinned portions provided in such a way as not to reach the down-step portion, the cross-flow fan can be made lighter while maintaining its strength, and the second blades can be strongly connected to the first support plate by ultrasonic welding, for example.
In the cross-flow fan pertaining to the first aspect of the invention, a cross-flow fan that is inexpensive, because time and effort when manufacturing the cross-flow fan are saved, can be provided, and a cross-flow fan that has good performance, because a reduction in the performance of the cross-flow fan caused by shifts in the positions of the second other-side distal ends of the second blades is suppressed, can be provided.
In the cross-flow fan pertaining to the second aspect of the invention, the accuracy of the alignment between the first fan block and the second fan block can be improved.
In the cross-flow fan pertaining to the third aspect of the invention, it becomes easy to provide a cross-flow fan that is strong and inexpensive, has good performance, and in which there is little noise.
In the cross-flow fan pertaining to the fourth aspect of the invention, high performance can be realized inexpensively.
In the cross-flow fan pertaining to the fifth aspect of the invention, a cross-flow fan that is inexpensive and has a sufficiently high performance can be provided.
In the cross-flow fan pertaining to the sixth aspect of the invention, a reduction in the performance of the cross-flow fan caused by welding burrs can be prevented.
In the cross-flow fan pertaining to the seventh aspect of the invention, the risk of deformation of and damage to the second outer peripheral ring can be suppressed.
In the cross-flow fan pertaining to the eighth aspect of the invention, a cross-flow fan that is inexpensive and sturdy can be provided.
In the cross-flow fan pertaining to the ninth aspect of the invention, a cross-flow fan that is sturdy and light can be inexpensively provided.
A cross-flow fan pertaining to an embodiment of the invention will be described below using, as an example, a cross-flow fan installed in an indoor unit of an air conditioning system.
(1) Cross-Flow Fan Inside Indoor Unit
The indoor heat exchanger 4 is configured by a front-side heat exchanger 4a and a back-side heat exchanger 4b that are coupled to each other so as to form an inverted V-shape as seen in a side view. In a plan view seen from the top surface of the body casing 2, the front-side heat exchanger 4a is disposed in a position opposing the substantially front half of the air inlet 2a, and the back-side heat exchanger 4b is disposed in a position opposing the substantially back half of the air inlet 2a. Both the front-side heat exchanger 4a and the back-side heat exchanger 4b are configured by lining up numerous plate fins parallel to the width direction of the indoor unit 1 and attaching them to heat transfer tubes. When the room air that has been sucked in from the air inlet 2a and has traveled through the air filter 3 passes between the plate fins of the front-side heat exchanger 4a and the back-side heat exchanger 4b, heat exchange takes place and air conditioning is performed.
On the downstream side of the indoor heat exchanger 4, the cross-flow fan 10, which is shaped substantially like an open cylinder, extends longly along the width direction of the body casing 2 and, together with the indoor heat exchanger 4, is provided parallel to the width direction of the body casing 2. The cross-flow fan 10 is equipped with an impeller 20, which is disposed in a space surrounded in such a way as to be sandwiched by the inverted V-shaped indoor heat exchanger 4, and a fan motor (not shown in the drawings), which is for driving the impeller 20. The cross-flow fan 10 generates an airflow by rotating the impeller 20 in direction A1 (a clockwise direction) indicated by the arrow in
An outgoing air passage leading to an air outlet 2b downstream of the impeller 20 of the cross-flow fan 10 has a back surface side configured by a scroll member 2c. The scroll member 2c has a width that is substantially the same as that of the open portion of the air outlet 2b in the body casing 2 as seen in a front view. The upper end of the scroll member 2c is positioned higher than the upper end of the impeller 20 and, as seen in a side view, is positioned in a place offset more toward the back surface side than a central axis of the open cylinder-shaped impeller 20. The lower end of the scroll member 2c is coupled to the open end of the air outlet 2b. A guide surface of the scroll member 2c exhibits a smoothly curved shape having a center of curvature on the side of the cross-flow fan 10 as seen in a cross-sectional view in order to smoothly and quietly guide to the air outlet 2b the air blown out from the impeller 20.
(2) General Structure of Impeller of Cross-Flow Fan
In
As shown in
In
When the first fan block 301 and the second fan block 302 shown in
(3) Detailed Configuration of Fan Blocks
The fan blocks 30 pertaining to the present embodiment each comprise the plural blades 40, the support plate 50, and the outer peripheral ring 60, which are integrally molded by injection molding, for example, using a thermoplastic resin as the main material. In
(3-1) Blades
The plural blades 40 extend in the longitudinal direction (the direction along the central axis O) from a first surface 51 of the annular support plate 50. Both outer ends 40a and inner ends 40b of the blades 40 shown in
The blades 40 each have a negative pressure surface 43 and a pressure surface 44. As shown in
Among the plural blades 40 is one blade 40 having a cutout portion (not shown in the drawings) formed in its other-side distal end 42. The cutout portion is for positioning the first support plate 501 of the first fan block 301 and the plural second blades 402 of the second fan block 302. Because the cutout portion is there, it becomes easy to position the plural second blades 402, which are disposed so as to have rotational asymmetry as described above, and the first support plate 501.
(3-2) Support Plate
In
In the second surface 52 of the support plate 50, a down-step portion 55 is formed along an outer periphery 50a of the support plate 50. A cross section along line II-II of
A cross section along line of
Outer ends 53a of the recess portions 53 of the support plate 50 are located on the inner side of the outer periphery 50a of the support plate 50. Consequently, a distance L1 from the center of the support plate 50 (a point on the central axis O) to the outer ends 53a of the recess portions 53 is smaller than the radius r1 of the outer periphery 50a but is the same as or slightly larger than a distance L3 from the central axis O to the outer ends 40a of the blades 40. Inner ends 53b of the recess portions 53 of the support plate 50 are located on the outer side of the inner periphery 50b of the support plate 50. Consequently, a distance L2 from the center of the support plate 50 to the inner ends 53b of the recess portions 53 is larger than the radius r2 of the inner periphery 50b but is slightly smaller than a distance L4 from the central axis O to the inner ends 40b of the blades 40. In this way, because the radius r1 of the outer periphery 50a of the support plate 50 is set larger than the distance L3 between the outer ends 40a of the blades 40 and the central axis O, and the radius r2 of the inner periphery 50b of the support plate 50 is set smaller than the distance L4 between the inner ends 40b of the blades 40 and the central axis O, the strength with which the support plate 50 supports the blades 40 becomes greater.
In the principal plane 54 of the support plate 50, thinned portions 57 are formed between adjacent recess portions 53. In
(3-3) Outer Peripheral Ring
In
As shown in
In
Furthermore, a depth D5 from the principal plane 54 of the first support plate 501 to the upper surface of the down-step portion 55 is larger than a thickness D6 of the second outer peripheral ring 602. In other words, this means that, in the longitudinal direction of the cross-flow fan 10, the down-step portion 55 is sunken deeper than the thickness D6 of the second outer peripheral ring 602. Because of this structure, even when the second outer peripheral ring 602 is provided, in the longitudinal direction of the cross-flow fan 10, the second outer peripheral ring 602 and the first support plate 501 fall in the range of the thickness D1 of the first support plate 501.
In order for the second outer peripheral ring 602 to fit the confines of the recess portions 53 of the first support plate 501, the width (r3-r4) of the second ring portion 612 of the second outer peripheral ring 602 is set smaller than the width W1 of the down-step portion 55. Furthermore, in order for the triangular second reinforcement ribs 62 of the second outer peripheral ring 602 to fit within the down-step portion 55, widened portions 55a corresponding to the triangular shapes of the second reinforcement ribs 622 are formed in the down-step portion 55. The width of the widened portions 55a is larger than the width W1.
As shown in
As shown in
As shown in
(4) Example Modifications
(4-1)
In the above embodiment, a case was described where the radius r3 of the outer periphery 61a of the ring portion 61 was the same as the radius r1 of the outer periphery 50a of the annular support plate 50, but the radius r3 of the outer periphery 61a of the ring portion 61 may also be set smaller than the radius r1 of the outer periphery 50a of the support plate 50.
(4-2)
In the above embodiment, a case was described where the radius r4 of the inner periphery 61b of the ring portion 61 was slightly larger than the distance L3 from the central axis O to the outer ends 40a of the blades 40, but the radius r4 may also be configured to be equal to the distance L3 so that the inner periphery 61b of the ring portion 61 is tangential to the outer ends 40a of the blades 40.
(4-3)
In the above embodiment, a case was described where the shape of the outer peripheral ring 60 was annular, but the shape of the outer peripheral ring 60 is not limited to being annular and, for example, may also be a polygonal shape having the same number of angles as the number of blades 40, and may also be a shape having serrations (numerous notches) made in its outer peripheral end.
(5) Characteristics
(5-1)
As described above, in the cross-flow fan 10, the second other-side distal ends 422 of the plural second blades 402 of the second fan block 302 are joined to the first support plate 501 of the first fan block 301 by ultrasonic welding, and the first support plate 501 and the second outer peripheral ring 602 are disposed in close proximity to each other. Because the cross-flow fan 10 is configured in this way, shifts in the positions of the second other-side distal ends 422 of the plural second blades 402 of the second fan block 302 can be prevented by the second outer peripheral ring 602, so when aligning the plural second blades 402 and the first support plate 501 there is no longer the need to correct shifts in the positions of the plural second blades 402. In this way, the cross-flow fan 10 that is inexpensive, because time and effort when manufacturing the cross-flow fan 10 are saved, can be provided, and the cross-flow fan 10 that has good performance, because a reduction in the performance of the cross-flow fan 10 caused by shifts in the positions of the second other-side distal ends 422 of the second blades 402 of the second fan block 302 is suppressed, can be provided.
It will be noted that although in the above embodiment a case was described where the first support plate 501 and the second support plate 502 were annular, even if the first support plate 501 and the second support plate 502 are disc-shaped, they can be formed in the same way as in the case where they are annular, and even in the case of using disc-shaped support plates, the same effects as in the case of using the annular first support plate 501 and second support plate 502 are achieved.
(5-2)
In the cross-flow fan 10, the first support plate 501, the plural first blades 401, and the first outer peripheral ring 601 are integrally molded by injection molding. Likewise, the second support plate 502, the plural second blades 402, and the second outer peripheral ring 602 are integrally molded by injection molding. Because of this integral molding, the first one-side distal ends 411 of the plural first blades 401 of the first fan block 301 are fixed by the first support plate 501 and the first other-side distal ends 421 are fixed by the first outer peripheral ring 601, so that it becomes difficult for the first fan block 301 to become deformed. Furthermore, the second one-side distal ends 412 of the plural second blades 402 of the second fan block 302 are fixed by the second support plate 502 and the second other-side distal ends 422 are fixed by the second outer peripheral ring 602, so that it becomes difficult for the second fan block 302 to become deformed. As a result, the dimensional accuracy of the first fan block 301 and the second fan block 302 when joining together the first fan block 301 and the second fan block 302 is improved. As a result, the accuracy of the alignment between the first fan block 301 and the second fan block 302 can be improved. For example, when handling the first fan block 301 and the second fan block 302 with robot arms or suction pads, even when stress acts from the robot arms or the suction pads on these, deformation of the first fan block 301 and the second fan block 302 can be suppressed, so automation can be easily carried out because of the improvement in alignment accuracy.
(5-3)
Because the second other-side distal ends 422 of the plural second blades 402 are positioned in a place where they project toward the opposite side of the second one-side distal ends 412 from the second outer peripheral ring 602, it becomes possible to ensure that the second outer peripheral ring 602 and the first support plate 501 are not joined together while joining together the second other-side distal ends 422 of the plural second blades 402 and the first support plate 501 of the first fan block 301 using ultrasonic welding, for example. As a result, the joining together of the first fan block 301 and the second fan block 302 can be performed strongly and inexpensively, the occurrence of noise can be suppressed by not joining together the second outer peripheral ring 602 and the first support plate 501, and the cross-flow fan 10 that is inexpensive, has good performance, and in which there is little noise can be provided.
(5-4)
The second outer peripheral ring 602 enters the down-step portion 55 of the first support plate 501, thereby reducing the longitudinal direction thickness in which the first support plate 501 and the second outer peripheral ring 602 lie on top of each other. As a result, workability can be improved while suppressing a worsening of air flow resistance caused by the first support plate 501 and the second outer peripheral ring 602 and stopping a worsening of power consumption, and at the same time high performance can be realized inexpensively.
(5-5)
Because the down-step portion 55 of the first support plate 501 is sunken deeper than the longitudinal direction thickness D6 of the second outer peripheral ring 602 in the longitudinal direction, the thickness of the section where the second outer peripheral ring 602 and the first support plate 501 lie on top of each other can be made thin up to the thickness D1 of the first support plate 501. As a result, a worsening of air flow resistance can be sufficiently suppressed, so the cross-flow fan 10 that is inexpensive and has a sufficiently high performance can be provided.
(5-6)
Furthermore, in the cross-flow fan 10, the welding ribs 56 are formed in such a way as to extend to the down-step portion 55, with the height H2 of the outer peripheral sections 56a positioned in the down-step portion 55 being formed lower than the height H3 of the inner peripheral sections 56b located on the inner peripheral side of the down-step portion 55. Because the welding ribs 56 have this structure, projection of welding burrs into the down-step portion 55 can be suppressed while strongly connecting the first support plate 501 and the plural second blades 402 to each other by ultrasonic welding, and a reduction in the performance of the cross-flow fan 10 caused by welding burrs that have entered between the first support plate 501 and the second outer peripheral ring 602 and so forth can be prevented.
(5-7)
Because the second outer peripheral ring 602 of the cross-flow fan 10 has the radius r3 of the outer periphery 61a (the outer radius of the second outer peripheral ring 602) that is the same as or smaller than the radius r1 of the outer periphery 50a of the first support plate 501 (the outer radius of the first support plate 501), in comparison to a case where the outer radius of the second outer peripheral ring 602 is larger than that of the first support plate 501, the risk of contact with a casing that covers the outer portion of the cross-flow fan 10, for example, can be suppressed, and the risk of deformation of and damage to the second outer peripheral ring 602 can be suppressed.
(5-8)
Because the second outer peripheral ring 602 has the second reinforcement ribs 622 which are reinforcement ribs that are connected to the negative pressure surfaces 43 of the plural second blades 402 but are not connected to the pressure surfaces 44 of the plural second blades 402, the ability to withstand external force applied to the second blades 402 can be enhanced. As a result, a cross-flow fan that is inexpensive, sturdy, and includes the first fan block 301 and the second fan block 302 suited to manufacturing automation, for example, can be provided.
(5-9)
Because the first support plate 501 has the thinned portions 57 provided in such a way as not to reach the down-step portion 55, the cross-flow fan 10 can be made lighter while maintaining its strength, and the second blades 402 can be strongly connected to the first support plate 501 by ultrasonic welding, for example. As a result, the cross-flow fan 10 that is sturdy and light can be inexpensively provided.
Patent Document 1: JP-A No. 2014-47772
Number | Date | Country | Kind |
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2015-215169 | Oct 2016 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2016/081683 | 10/26/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2017/073593 | 5/4/2017 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3385511 | Wentling | May 1968 | A |
4067094 | Ittner | Jan 1978 | A |
6179566 | Andulics | Jan 2001 | B1 |
6761040 | Ahn | Jul 2004 | B2 |
7220101 | Chen | May 2007 | B2 |
7422418 | Ishijima | Sep 2008 | B2 |
9995316 | Hall | Jun 2018 | B2 |
20150252816 | Nakai | Sep 2015 | A1 |
20170002827 | Uda | Jan 2017 | A1 |
20170051760 | Uda | Feb 2017 | A1 |
Number | Date | Country |
---|---|---|
2-102396 | Apr 1990 | JP |
2002-257078 | Sep 2002 | JP |
2004-285937 | Oct 2004 | JP |
2014-47772 | Mar 2014 | JP |
2014-70518 | Apr 2014 | JP |
2013018359 | Jul 2013 | WO |
Entry |
---|
International Search Report of corresponding PCT Application No. PCT/JP2016/081683 dated Jan. 24, 2017. |
International Preliminary Report of corresponding PCT Application No. PCT/JP2015/081683 dated May 11, 2018. |
European Search Report of corresponding EP Application No. 16 85 9823.3 dated Oct. 11, 2018. |
Number | Date | Country | |
---|---|---|---|
20180328367 A1 | Nov 2018 | US |