The present application claims priorities under 35 U.S.C. § 119 to Japanese Application No. 2019-076029, filed on Apr. 12, 2019, entitled “COMPRESSOR HOUSING FOR TURBOCHARGER”, and Japanese Application No. 2019-109323, filed on Jun. 12, 2019, entitled “COMPRESSOR HOUSING FOR TURBOCHARGER AND METHOD FOR MANUFACTURING THE SAME”. The contents of these applications are incorporated herein by reference in their entirety.
The present disclosure relates to a compressor housing for a turbocharger and a method for manufacturing the same.
A turbocharger to be mounted on an internal combustion engine of an automobile, etc. includes a compressor impeller and a turbine impeller, which are housed in a housing. The compressor impeller is disposed in an air flow path that is formed inside a compressor housing. The air flow path is provided with an intake port for sucking in air toward the compressor impeller, a diffuser passage through which compressed air discharged from the compressor impeller passes, and a discharge scroll chamber into which the compressed air passing through the diffuser passage flows. The discharge scroll chamber discharges the compressed air into the internal combustion engine side.
Some internal combustion engines for an automobile, etc. are provided with a positive crankcase ventilation system (hereinafter referred to as PCV) for purifying the inside of a crankcase and/or the inside of a head cover by reflowing blowby gas that has generated in the crankcase in an intake passage. In such a configuration, oil (oil mist) contained in the blowby gas may flow out from the PCV into the intake passage that is located upstream of the compressor in the turbocharger under some circumstances.
At that time, if air pressure at an outlet port of the compressor is high, air temperature there is made high, so that the oil flowing out from the PCV is concentrated and thickened by evaporation to have high viscosity. In some cases, the oil is accumulated as deposit on, for example, the diffuser surface of a compressor housing for a turbocharger and/or the surface of a bearing housing which opposes the diffuser surface. And, there is a risk that the deposit thus accumulated may narrow the diffuser passage to thereby cause reduction in performance of the turbocharger and reduction in output of the internal combustion engine.
In the past, an air temperature at the outlet port of the compressor was controlled to some extent to prevent such deposit accumulation in the diffuser passage as described above. As a result, a turbocharger was not able to satisfactorily exhibit its performance, and the output of an internal combustion engine was not satisfactorily raised.
Patent Document 1 discloses a configuration to prevent deposit accumulation in a diffuser passage, in which a refrigerant flow path is provided inside a compressor housing for a turbocharger to allow a refrigerant to pass therethrough, thereby restraining an increase in the temperature of compressed air passing through an air flow path inside the housing. In the configuration disclosed in Patent Document 1, the compressor housing for a turbocharger is dividably formed of a scroll piece and a shroud piece, and a refrigerant flow path is defined by assembling both pieces.
Patent Document
Patent Document 1
In the configuration disclosed in Patent Document 1, leakage of a refrigerant from the refrigerant flow path is curtailed by a seal part formed by press-fitting the shroud piece into the scroll piece. In order to enhance sealability at the seal part to a satisfactory extent, it may be considered to apply a sealing material to the seal parts in the shroud piece and the scroll piece at the time of press-fitting. However, when applying the sealing material, some kind of pretreatment such as preparation of the sealing material, degreasing, etc. is required, which will cause cost increase and deterioration of workability. Alternately, it may be considered to form the seal part with a press-fitting surface on the shroud piece into the scroll piece without using the sealing material to reduce cost and number of working processes, however, this case involves a risk that a micro gap will be formed in the seal part, which may cause leakage of a refrigerant, and leakage defects will occur. The leakage defects can be detected in leakage inspection performed after assembly, so that distribution of defective products to the market can be prevented. However, reduction of the production yield will eventually result in cost increase.
On the other hand, also in the case where a compressor housing for a turbocharger having no refrigerant flow path is dividably formed of a scroll piece and a shroud piece, and both pieces are assembled together by press-fitting, improvement in sealability at a press-fitting portion is required in some cases. In this case, if a sealing material is used as mentioned above, cost increase and reduction in workability will be caused.
The present disclosure has been made in view of this background, and is directed to a compressor housing for a turbocharger in which improvement in sealability can be achieved compatibly with cost reduction.
One aspect of the present disclosure provides a compressor housing for a turbocharger configured to house a compressor impeller, the compressor housing including:
an intake port formation part that defines an intake port configured to suck in air toward the compressor impeller;
a shroud part that surrounds the compressor impeller in a circumferential direction and has a shroud surface facing the compressor impeller;
a diffuser part that is formed on an outer circumferential side of the compressor impeller in the circumferential direction and forms a diffuser passage configured to allow compressed air discharged from the compressor impeller to pass therethrough; and
a scroll chamber formation part that forms a scroll chamber configured to guide the compressed air passing through the diffuser passage to outside;
wherein the compressor housing is dividably composed of a plurality of pieces including a scroll piece having at least the intake port formation part and a portion of the scroll chamber formation part, and a shroud piece having at least a portion of the scroll chamber formation part, a portion of the diffuser part, and the shroud part,
wherein the scroll piece and the shroud piece are assembled to each other by press-fitting a press-fitting portion of the shroud piece into a press-fitted portion of the scroll piece, and
wherein a seal part that seals the scroll piece and the shroud piece is formed by pressure-contacting a pressure-contacting portion that is provided on either one of the scroll piece and the shroud piece with a pressure-contacted portion that is provided on the other one of the scroll piece and the shroud piece so as to cause plastic flow in the pressure-contacting portion.
According to the above-mentioned one aspect of the compressor housing for a turbocharger, the seal part between the scroll piece and the shroud piece is formed by pressure-contacting the pressure-contacting portion that is provided on either one of the scroll piece and the shroud piece with the pressure-contacted portion that is provided on the other one of the scroll piece and the shroud piece so as to cause plastic flow in the pressure-contacting portion. In this way, the pressure-contacting portion plastically flows at the seal part, and a micro gap is filled by the plastic flow, so that improvement in sealability can be achieved differently from the case of forming the seal part by just press-fitting the scroll piece and the shroud piece. In addition, because there is no need to apply a sealing material separately to the seal part, cost reduction can be achieved.
As mentioned above, according to the present aspect, a compressor housing for a turbocharger in which an improvement in sealability is achieved compatibly with cost reduction can be provided.
“Circumferential direction” in the present specification means the rotation direction of a compressor impeller, “shaft direction” means the direction of the rotation shaft of the compressor impeller, “radial direction” means the radius direction of an imaginary circle centered on the rotation shaft of the compressor impeller, and “outwardly in the radial direction” is defined to be in the direction straightly extending from the center of the imaginary circle to the circumference of the circle.
The compressor housing for a turbocharger further includes a refrigerant flow path that is formed along the diffuser part in the circumferential direction, and allows a refrigerant for cooling the diffuser part to pass therethrough;
wherein the refrigerant flow path is formed as an annular space that is constituted by a first refrigerant flow-path formation part of the scroll piece and a second refrigerant flow-path formation part of the shroud piece, the first refrigerant flow-path formation part and the second refrigerant flow-path formation part being formed respectively at each opposing part of the scroll piece and the shroud piece which oppose each other,
wherein the seal part includes an inner circumferential seal part configured to seal the refrigerant flow path on the inner circumferential side thereof, and an outer circumferential seal part configured to seal the refrigerant flow path on the outer circumferential side thereof,
wherein the inner circumferential seal part is formed by pressure-contacting an inner circumferential pressure-contacting portion that is provided on either one of the scroll piece and the shroud piece with an inner circumferential pressure-contacted portion that is provided on the other one of the scroll piece and the shroud piece so as to cause plastic flow in the inner circumferential pressure-contacting portion, and
wherein the outer circumferential seal part is formed by pressure-contacting an outer circumferential pressure-contacting portion that is provided on either one of the scroll piece and the shroud piece with an outer circumferential pressure-contacted portion that is provided on the other one of the scroll piece and the shroud piece so as to cause plastic flow in the outer circumferential pressure-contacting portion. According to such a configuration, in the compressor housing for a turbocharger having the refrigerant flow path provided therein, improvement in sealability can be achieved compatibly with cost reduction.
The seal part is preferably located on further rear side in a press-fitting portion inserting direction with respect to the press-fitting portion. In this case, when the shroud piece is assembled to the scroll piece, the pressure-contacting portion is pressure-contacted with the pressure-contacted portion after the press-fitting portion is press-fitted into the press-fitted portion, so that dispersal of a plastic flow portion of the seal part can be curtailed. Therefore, the sealability can be surely improved.
Another aspect of the present disclosure provides a method for manufacturing a compressor housing for a turbocharger according to claim 1, the method including:
molding the scroll piece and the shroud piece by die-casting;
forming the pressure-contacting portion on either one of the scroll piece and the shroud piece and the pressure-contacted portion on the other one of the scroll piece and the shroud piece by machining; and
assembling the shroud piece to the scroll piece by press-fitting the press-fitting portion into the press-fitted portion, and by pressure-contacting the pressure-contacting portion with the pressure-contacted portion so as to cause plastic flow in the pressure-contacting portion to thereby form the seal part.
According to this configuration, the above-mentioned compressor housing for a turbocharger can be manufactured. Because the pressure-contacting portion and the pressure-contacted portion are formed by machining, the surfaces thereof can be made rough to some extent in comparison with a cast surface made by die-casting, which makes it possible to easily cause plastic flow in the pressure-contacting portion in the assembling, so that the sealability can be further enhanced.
In the machining, the pressure-contacting portion is preferably formed by machining in a mountain shape that protrudes in the radial direction in a cross section including the rotation axis of the compressor impeller, having a front-end side inclined plane that is located on the front-end side in the press-fitting portion inserting direction and a rear-end side inclined plane that is located on the rear-end side in the inserting direction such that an acute-angle between the rear-end side inclined plane and the rotation axis is set larger than an acute-angle between the front-end side inclined plane and the rotation axis in the cross section. In this case, the pressure-contacting portion is shaped by machining such that the rear-end side inclined plane stands more steeply with respect to the rotational axis than the front-end side inclined plane does, so that the width of the pressure-contacting portion can be narrowed with the inclination angle of the front-end side inclined plane and the protruding amount of the pressure-contacting portion being kept unchanged. Thus, in the assembling step, plastically flow in the pressure-contacting portion is easily caused without deterioration of assemblability. Consequently, at each seal part formed in the assembling step, a micro gap can be filled more surely, so that the sealability can be further improved. Otherwise, by narrowing the width of the pressure-contacting portion with the plastic flow amount of the pressure-contacting portion being kept unchanged, dimension tolerances in the pressure-contacting portion and the pressure-contacted portion can be eased in the machining. As a result, productivity can be improved and cost reduction can be achieved.
Hereinafter, embodiments of the above-mentioned compressor housing for a turbocharger will be described with reference to
As shown in
The intake port formation part 10 defines an intake port 11 configured to suck in air toward the compressor impeller 13.
The shroud part 20 surrounds the compressor impeller 13 in the circumferential direction and has a shroud surface 22 facing the compressor impeller 13.
The diffuser part 30 is formed on the outer circumferential side of the compressor impeller 13 in the circumferential direction and forms a diffuser passage 15 configured to allow compressed air discharged from the compressor impeller 13 to pass therethrough.
The scroll chamber formation part 120 forms a scroll chamber 12 configured to guide the compressed air passing through the diffuser passage 15 to outside.
And the compressor housing 1 is dividably composed of a plurality of pieces including the scroll piece 2 and the shroud piece 3.
The scroll piece 2 has at least the intake port formation part 10 and a portion of the scroll chamber formation part 120.
The shroud piece 3 has at least a portion of the scroll chamber formation part 120, a portion of the diffuser part 30, and the shroud part 20.
The scroll piece 2 and the shroud piece 3 are assembled to each other by press-fitting a press-fitting portion 53b of the shroud piece 3 into a press-fitted portion 53a of the scroll piece 2. In addition, seal parts 541 and 542 that seal the scroll piece 2 and the shroud piece 3 are formed by pressure-contacting pressure-contacting portions 541b and 542b that are provided on the shroud piece 3 with pressure-contacted portions 541a and 542a that are provided on the scroll piece 2 so as to cause plastic flow in the pressure-contacting portions 541b and 542b.
Hereinafter, the compressor housing 1 for a turbocharger according to the present embodiment will be described in detail.
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The seal plate 40 has a third scroll chamber formation part 123, a seal plate insertion portion 41, and a second diffuser part 36 as shown in
Next, a manufacturing method of the compressor housing 1 for a turbocharger according to the present embodiment will be described.
First of all, as shown in
Next, the shroud piece 3 is assembled to the scroll piece 2 in the assembling step as shown by an arrow P in
Also in the outer circumferential seal part 542, in association with the action that the press-fitting portion 53b of the shroud piece 3 is press-fitted into the press-fitted portion 53a of the scroll piece 2, the outer circumferential pressure-contacting portion 542b of the shroud piece 3 is brought in contact with the second chamfered portion 582 of the scroll piece 2 as shown in
In the compressor housing 1 for a turbocharger, a refrigerant introduction tube and a refrigerant discharge tube, which are not shown in any figure, are connected respectively to the refrigerant feed part 513 and the refrigerant discharging part 514 each communicated with the refrigerant flow path 5 as shown in
It is noted that although in the inner circumferential seal part 541 according to the present embodiment, the scroll piece 2 is provided with the inner circumferential pressure-contacted portion 541a, and the shroud piece 3 is provided with the inner circumferential pressure-contacting portion 541b, the inner circumferential pressure-contacting portion 541b may be provided on the scroll piece 2, and the inner circumferential pressure-contacted portion 541a may be provided on the shroud piece 3. Similarly, in the outer circumferential seal part 542, the scroll piece 2 is provided with the outer circumferential pressure-contacted portion 542a, and the shroud piece 3 is provided with the outer circumferential pressure-contacting portion 542b. Alternatively, the outer circumferential pressure-contacting portion 542b may be provided on the scroll piece 2, and the outer circumferential pressure-contacted portion 542a may be provided on the shroud piece 3. In this regard, it is preferable to provide the pressure-contacted portions 541a and 542a on either piece that has a higher rigidity than the other does.
It is noted that although in the present embodiment, the press-fitting portion 53b is provided at further Y1 side than the location of the inner circumferential pressure-contacting portion 541b of the shroud piece 3 in order to curtail dispersal of a plastic flow portion, instead of or concurrently with such a configuration, the press-fitting portion may be formed on further Y1 side with respect to the outer circumferential pressure-contacting portion 542b of the shroud piece 3, and the press-fitted portion may be formed on further Y1 side with respect to the inner circumferential pressure-contacted portion 541a of the scroll piece 2.
Next, operational effects of the compressor housing 1 for a turbocharger according to the present embodiment will be described in detail.
According to the compressor housing 1 for a turbocharger of the present embodiment, the seal parts 541 and 542 between the scroll piece 2 and the shroud piece 3 are formed by pressure-contacting the pressure-contacting portions 541b and 542b that are provided on either one of the scroll piece 2 and the shroud piece 3 with the pressure-contacted portions 541a and 542a that are provided on the other one of the scroll piece 2 and the shroud piece 3 so as to cause plastic flow in the pressure-contacting portions 541b and 542b. Thus, micro gaps are filled by the plastic flow substantially of the pressure-contacting portions 541b and 542b in the seal parts 541 and 542, so that improvement in sealability can be achieved in comparison with the case where the seal parts are formed by just press-fitting of both. In addition, because there is no need to apply any sealing material separately at the seal parts 541 and 542, cost reduction can be achieved.
The present embodiment includes the refrigerant flow path 5 that is formed along the diffuser part 30 in the circumferential direction, and allows a refrigerant for cooling the diffuser part to pass therethrough. The refrigerant flow path 5 is formed as an annular space 50 that is constituted by the first refrigerant flow-path formation part 51 of the scroll piece 2 and the second refrigerant flow-path formation part 52 of the shroud piece 3, the first refrigerant flow-path formation part 51 and the second refrigerant flow-path formation part 52 being formed respectively at each opposing part of the scroll piece 2 and the shroud piece 3 which oppose each other. This embodiment includes, as the seal parts 541 and 542, the inner circumferential seal part 541 configured to seal the refrigerant flow path 5 on the inner circumferential side thereof, and the outer circumferential seal part 542 configured to seal the refrigerant flow path 5 on the outer circumferential side thereof, and the inner circumferential seal part 541 is formed by pressure-contacting the inner circumferential pressure-contacting portion 541b that is provided on either one of the scroll piece 2 and the shroud piece 3 with the inner circumferential pressure-contacted portion 541a that is provided on the other one of the scroll piece 2 and the shroud piece 3 so as to cause plastic flow substantially in the inner circumferential pressure-contacting portion 541b to thereby form the seal part. The outer circumferential seal part 542 is formed by pressure-contacting the outer circumferential pressure-contacting portion 542b that is provided on either one of the scroll piece 2 and the shroud piece 3 with the outer circumferential pressure-contacted portion 542a that is provided on the other one of the scroll piece 2 and the shroud piece 3 so as to cause plastic flow substantially in the outer circumferential pressure-contacting portion 542b to thereby form the seal part. According to such configurations, in the compressor housing 1 for a turbocharger provided with the refrigerant flow path 5, the sealability at the inner circumferential seal part 541 and the outer circumferential seal part 542 can be achieved compatibly with cost reduction.
In the present embodiment, the inner circumferential pressure-contacting portion 541b is located on further rear side Y2 in the inserting direction of the press-fitting portion 53b with respect to the press-fitting portion 53b. Therefore, when the shroud piece 3 is assembled to the scroll piece 2, the inner circumferential pressure-contacting portion 541b is pressure-contacted with the inner circumferential pressure-contacted portion 541a after the press-fitting portion 53b is press-fitted, so that dispersal of a plastic flow portion at the inner circumferential seal part 541 can be curtailed. Thus, the sealability can be surely improved.
Furthermore, the compressor housing 1 for a turbocharger is dividably formed to include the scroll piece 2 and the shroud piece 3, and the scroll chamber 12 is defined by assembling at least both pieces. Thus, the scroll chamber 12 can be formed to have a circular cross section, and the scroll chamber formation part 120 can be formed into a shape having no undercut, which can be formed by die-cutting. As a result, the compression efficiency for the supplied air can be improved, and the scroll chamber can be easily formed by die casting.
It is noted that although in the present embodiment, the housing 1 for a turbocharger is of a two-piece structure that is composed of the scroll piece 2 and the shroud piece 3, the housing 1 may be of a three-piece structure that is composed of the scroll piece 2, the shroud piece 3, and an outer circumference annular piece 4 as in Modification 1 shown in
A method for manufacturing the compressor housing 1 for a turbocharger according to Modification 1 will be described hereinafter. First of all, as shown in
The housing 1 for a turbocharger according to Modification 1 also exhibits operational effects equivalent to those in Embodiment 1. A tightening margin of the press-fit part 42 into which the outer circumference annular piece 4 is press-fitted is preferably set smaller than that of the inner circumferential seal part 53b. In this case, the integral piece 3b can be easily press-fitted into the scroll piece 2. In addition, misalignment between the press-fitting portion 53b of the shroud piece 3 and the press-fitting portion 42 of the outer circumference annular piece 4 can be absorbed.
In the housing 1 for a turbocharger according to Modification 1, a part of the integrated piece 3b for constituting the outer circumference annular piece 4 is not brought into contact with the scroll piece 2 in the shaft direction S2 so as to form a gap B, as shown in
In Embodiment 1, the inner circumferential pressure-contacting portion 541b in the non-assembled state protrudes in the radial direction in a cross section including the rotation axis 13a of the compressor impeller 13 to form a mountain shape, as shown in
According to Embodiment 2, instead of the above-mentioned configurations, the inner circumferential pressure-contacting portion 541b in the non-assembled state is formed in a mountain shape that protrudes in the radial direction X in a cross section including the rotation axis 13a of the compressor impeller 13, and has a front-end side inclined plane 545 that is located on the front-end side in the press-fitting portion inserting direction (on the intake side Y1 in the present embodiment) and a rear-end side inclined plane 546 that is located on the rear-end side in the inserting direction (on the opposite side Y2 to the intake side Y1 in the present embodiment), as shown in
The acute-angle θ1 formed between the front-end side inclined plane 545 and the rotation axis 13a in
As shown in
The acute-angle θ3 formed between the front-end side inclined plane 547 and the rotation axis 13a in
Next, a method for manufacturing the compressor housing 1 for a turbocharger according to Embodiment 2 will be described.
First of all, the scroll piece 2 and the shroud piece precursor 3a are separately molded by die casting in the same manner as in Embodiment 1 shown in
The compressor housing 1 for a turbocharger of Embodiment 2 exhibits the same operational effects as in Embodiment 1. Further, in the method for manufacturing the compressor housing 1 for a turbocharger according to the present embodiment, the inner circumferential pressure-contacting portion 541b and the outer circumferential pressure-contacting portion 542b are each formed by machining in a mountain shape that protrudes in the radial direction in a cross section including the rotation axis 13a, having the front-end side inclined planes 545 and 547 respectively that are located on the front-end side in the inserting direction of the press-fitting portion and the rear-end side inclined planes 546 and 548 respectively that are located on the rear-end side in the inserting direction such that in the cross section, the acute-angles θ2 and θ4 of the rear-end side inclined plane 546 and 548 are respectively set larger than the acute-angles θ1 and θ3 of the front-end side inclined planes 545 and 547. In this way, at the pressure-contacting portions 541b and 542b, the rear-end side inclined planes 546 and 548 are machined to stand more steeply with respect to the rotational axis 13a respectively than the front-end side inclined planes 545 and 547. Consequently, the formation ranges (i.e. the widths) H3 and H4 respectively of the pressure-contacted portions 541b and 542b can be narrowed while the inclination angles θ1 and θ3 respectively of the front-end side inclined planes 545 and 547, and the protrusion amounts T1 and T2 respectively of the pressure-contacted portions 541b and 542b are set to be the same as in Embodiment 1. Therefore, plastic flow in the pressure-contacting portions 541b and 542b can be easily caused without deterioration of assemblability. Consequently, at each seal part 541 and 542, a micro gap can be filled more surely, so that the sealability can be further improved. Otherwise, when plastic flow amounts at the pressure-contacting portions 541b and 542b are set to the same as in Embodiment 1, dimension tolerances in the pressure-contacting portions 541b and 542b, and the pressure-contacted portions 541a and 542a in machining can be eased by narrowing the widths H3 and H4 of the pressure-contacting portions. As a result, productivity can be improved and cost reduction can be achieved.
In the present embodiment, the shroud piece 3 is provided with the inner circumferential pressure-contacting portion 541b, and the scroll piece 2 is provided with the inner circumferential pressure-contacted portion 541a, however, instead of such a configuration, the inner circumferential pressure-contacted portion 541a may be provided on the shroud piece 3, and the inner circumferential pressure-contacting portion 541b may be provided on the scroll piece 2. Further, in the present embodiment, the shroud piece 3 is provided with the outer circumferential pressure-contacting portion 542b, and the scroll piece 2 is provided with the outer circumferential pressure-contacted portion 542a, however, instead of such a configuration, the outer circumferential pressure-contacted portion 542a may be provided on the shroud piece 3, and the outer circumferential pressure-contacting portion 542b may be provided on the scroll piece 2. In both cases, it is preferable to provide the inner circumferential pressure-contacted portion 541a, and the outer circumferential pressure-contacted portion 542a on either piece that has a higher rigidity than the other does.
It is noted that in the present embodiment, the inner circumferential pressure-contacting portion 541b and the outer circumferential pressure-contacting portion 542b are provided on the shroud piece 3 as shown in
It is noted that in the present embodiment, the front-end side inclined planes 545 and 547, and the rear-end side inclined planes 546 and 548 are formed to have a shape that is shown by a straight line when viewed in the cross section including the rotation axis 13a, however, it is not necessary for the line to be an exact straight line in the cross section, and the line may be slightly curved.
The present disclosure is not limited to the above-mentioned embodiments and modifications, and can be applied to various embodiments within the range that does not depart from the gist of the present disclosure.
Number | Date | Country | Kind |
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JP2019-076029 | Apr 2019 | JP | national |
JP2019-109323 | Jun 2019 | JP | national |
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Entry |
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Sep. 2, 2020 Search Report issued in European Patent Application No. 20161556.4. |
Apr. 6, 2021 Office Action issued in Japanese Patent Application No. 2019-109323. |
Oct. 12, 2021 Office Action issued in Japanese Application No. 2019-109323. |
Number | Date | Country | |
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20200325902 A1 | Oct 2020 | US |