The present invention relates to a technique for improving a worm gear mechanism.
A worm gear mechanism is installed, for example, in a power steering device of a vehicle (see, for example, FIG. 14 in Patent Literature 1).
The worm gear mechanism as disclosed in Patent Literature 1 is provided with a worm coupled to an electric motor through a worm shaft, and a worm wheel configured to mesh with the worm. It is a transmission mechanism configured to boost and transmit auxiliary torque generated by the electric motor from the worm to the worm wheel.
In general, when the worm is rotated and force is applied in a direction of pushing the worm wheel, the worm receives reaction force from the worm wheel at a contact point of the worm and the worm wheel. It is preferred that strength of the worm gear mechanism be enhanced as it may contribute to extending a life of the worm gear mechanism.
Patent Literature 1: JP 2010-270908 A
It is therefore an object of the present invention to provide a technique for enhancing strength of a worm gear mechanism.
According to the present invention, in a worm gear mechanism including a worm and a worm wheel meshed with the worm, at least an addendum surface of a tooth of the worm is formed into an arc shape, and a center of a radius of an arc of the addendum surface is positioned nearer to a center line of the worm than a pitch line of the worm, the worm wheel is gear cut by a hob used in gear cutting of the worm wheel, at least an addendum surface of a tooth of the hob being formed into an arc shape, and a center of a radius of an arc of the addendum surface being positioned nearer to a center line of the hob than a pitch line of the hob, and a length of recess path of the worm gear mechanism, in which the worm is meshed with the worm wheel, is set to be larger than a length of recess path of the worm gear mechanism having an involute profile worm and an involute profile worm wheel.
Preferably, at least a tooth of the worm wheel includes a resin molded article.
With the present invention, it is possible to decrease face pressure around a base circle. Furthermore, since undercutting of a tooth profile on a tooth bottom side of the base circle can be eliminated, it is possible to make the tooth bottom side of the base circle a meshing face. Accordingly, it is possible to increase a contact ratio without increasing a diameter of a tooth tip of the worm wheel, whereby strength of a worm gear mechanism can be enhanced.
Furthermore, since a resin worm wheel has a small elastic modulus, a tooth may be easily bent in the present invention. In a case where a plurality of teeth thereof simultaneously meshes with teeth of the worm, a shared load on the meshed teeth becomes larger as a meshing depth becomes lower. However, it is possible to secure a large contact area in a part where the meshing depth is low, whereby the face pressure can be reduced.
An embodiment for carrying out the present invention is described below with reference to the attached drawings.
An example in which a worm gear mechanism according to an embodiment is installed in an electric power steering device and the electric power steering device is used in a vehicle is described.
As illustrated in
In the steering system 20, the steering wheel 21 is coupled to a pinion shaft 24 through a steering shaft 22 and universal shaft couplings 23 and 23, a rack shaft 26 is coupled to the pinion shaft 24 through a rack and pinion mechanism 25, and the right and left steered wheels 29 and 29 are coupled to both ends of the rack shaft 26 through right and left tie rods 27 and 27 and knuckles 28 and 28.
The rack and pinion mechanism 25 includes a pinion 31 formed in the pinion shaft 24 and a rack 32 formed in the rack shaft 26.
With the steering system 20, it is possible to steer the right and left steered wheels 29 and 29 through the rack and pinion mechanism 25 and the right and left tie rods 27 and 27 by a driver steering the steering wheel 21.
The auxiliary torque mechanism 40 is a mechanism in which a steering torque sensor 41 detects steering torque of the steering system 20 applied to the steering wheel 21. A controller 42 generates a control signal based on a torque detection signal of the steering torque sensor 41. An electric motor 43 generates the auxiliary torque in accordance with the steering torque based on the control signal. The auxiliary torque is transmitted to the pinion shaft 24 through a worm gear mechanism 44. Furthermore, the auxiliary torque is transmitted from the pinion shaft 24 to the rack and pinion mechanism 25 in the steering system 20.
The steering torque sensor 41 detects the torque applied to the pinion shaft 24 and outputs it as the torque detection signal. It may be constituted, for example, by a magnetostriction torque sensor or a torsion bar suspension type torque sensor.
According to the electric power steering device 10, it is possible to steer the steered wheels 29 and 29 through the rack shaft 26 by composite torque in which the auxiliary torque of the electric motor 43 is added to the steering torque by the driver.
As illustrated in
As illustrated in
The housing 51 rotatably supports an upper portion 24a, a longitudinal central portion 24m, and a lower end portion 24d of the vertically extending pinion shaft 24 with three bearings (a first bearing 55, a second bearing 56, and a third bearing 57 from the top to the bottom in order). The electric motor 43 is further attached to it, and it is provided with a rack guide 60. Rolling bearings are used as three bearings 55 to 57.
The rack guide 60 is a rack pressurization unit including a guide portion 61, which touches the rack shaft 26 from an opposite side of the rack 32, and an adjustment bolt 63, which pushes the guide portion 61 through a compression spring 62.
As illustrated in
The worm gear mechanism 44 is an auxiliary torque transmission mechanism, or a booster mechanism, transmitting the auxiliary torque generated by the electric motor 43 to the pinion shaft 24. To be more specific, the worm gear mechanism 44 includes a worm 70 and a worm wheel 80, which meshes with the worm 70. Hereinafter, the worm wheel 80 is abbreviated as the “wheel 80”. Relative to a center line WL of the worm 70, a center line CL of the wheel 80 is arranged at substantially a right angle. The center line CL of the wheel 80 is also the center line CL of the pinion shaft 24.
The worm 70 is a metal product integrally formed with the worm shaft 46, and it is, for example, a steel product such as a carbon steel material for mechanical structure (JTS-G-4051). The whole wheel 80 or at least a tooth 81 thereof is a resin product such as of nylon resin. Since the worm 70, which is the metal product, is meshed with the wheel 80, which is the resin product, it is possible to make meshing comparably smooth while further reducing noise.
A screw thread 71 (or, a tooth 71) of the worm 70 is set to be a single thread. On an outer periphery of the wheel 80, a plurality of teeth 81 having an equal pitch on the entire periphery thereof is formed. The wheel 80 is attached such that relative movement in the shaft direction relative to the pinion shaft 24 is limited, while relative rotation thereof is also limited. For example, the wheel 80 is coupled by a serration or a spline in the rotational direction relative to the pinion shaft 24, while it is attached by a snap circle in the shaft direction. By meshing the wheel 80 on a load side with the worm 70 on a drive side, it is possible to transmit torque from the worm 70 to the load through the wheel 80.
Various performances are required for this worm gear mechanism 44. For example, improvement of a contact ratio and enhancement of strength are listed among them. Details are described using the next drawing and after.
Firstly, a conventional worm gear mechanism 200 illustrated in
However, when the worm wheel 220 undergoes gear cutting by a hob, undercutting occurs to a tooth root 221b. On a side nearer to a center of the wheel 220 than the base circle 301, a tooth thickness is W1 at a part where the tooth 221 has the minimum thickness. In this way, since the tooth root 221b has a narrow part, the tooth thickness W1 is smaller than W2. As a result, bending strength of the tooth 221 is decreased. Furthermore, the tooth profile of the wheel 220 is a projected shape having a small curvature radius at a part around the base circle 301. Since it is the projected shape having the small curvature radius, a contact area, which contacts with the worm, decreases. As a result, a meshing contact face pressure increases. That is, when the tooth depth FIT of the wheel 220 having the involute profile is increased, the bending strength and the face pressure strength tend to be decreased.
As illustrated in
As illustrated in
In order to prevent this undercut phenomenon (undercutting) from occurring, as illustrated in
Back to
Next, the conventional wheel 220 illustrated in
The above descriptions can be summarized as below. The tooth 91 of the hob 90 according to the embodiment is formed such that at least the addendum surface 91C has an arc shape with a large radius of curvature. The center 93 of the radius of the arc of the addendum surface 91C is positioned nearer to the center line (axis line) WL of the hob 90 than is the pitch line 94 of the hob 90.
It is preferred that the worm 70, which meshes with the wheel 80, be formed into a shape similar to that of the hob 90. That is, at least an addendum surface 71c of the tooth 71 of the worm 70 is formed into an arc shape. A center 73 of the radius of the arc of the addendum surface 71c is positioned nearer to the center line (axis line) WL of the worm 70 than a pitch line 74 of the worm 70.
As illustrated in
Here, the trochoid curve, which is a principle of the present invention, is supplemented based on
With reference to
Therefore,
With reference to
X′=rp sin θ
Y′=rp cos θ
X″−X′=rpθ cos θ
Y″−Y′=rpθ sin θ
X−X″=−h sin θ
Y−Y″=h cos θ [Mathematical Formula 2]
Therefore,
X=(rp+h)sin θ−rpθ cos θ
Y=(rp+h)cos θ+rpθ sin θ (12)
Here, reconsidering Formula (11),
Substitution of +∞ for γ results in
and then
X=(γp+h)sin θ cos θ
Similarly,
Y=(rp+h)cos θ sin θ
It is found that it corresponds with Formula (2).
This Formula is used in hob cutting.
Here, a description is given by comparing the conventional worm gear mechanism 200 with the worm gear mechanism 44 according to the embodiment.
The worm 210 and the wheel 220 can be meshed with each other in a range of the length of path of contact on the meshing line 321. The base circle 301 of the wheel 220 having the involute profile is uniquely determined by a module, the number of teeth, and a twist angle. Therefore, a position of the third intersection point P13 is uniquely determined as well. In order to make the length of path of contact longer, it is necessary to increase an outside diameter of the wheel 220. Accordingly, there is a problem in that the worm gear mechanism 200 cannot be downsized.
Furthermore, in a case where the conventional worm gear mechanism 200 is used in an electric power steering device for a vehicle, a resin material is often used for the tooth 221 of the wheel 220. In the wheel 220 using the resin material, elastic modulus of the material is small, whereby the tooth 221 is easily bent. In a case where a plurality of teeth 221 simultaneously meshes with each other, the lower a meshing depth is, the larger a shared load on the meshing tooth 221 is. That is, the load applied on each of the teeth 221 becomes larger.
Furthermore, in the involute profile, the curvature radius becomes smaller as it gets closer to the base circle 301. A meshing face pressure around the base circle 301 is very large compared to the meshing face pressure around the pitch circle 302. Accordingly, there is a problem in that it is difficult to extend the meshing line 321 nearer to a side of a wheel center than the base circle 301.
A tooth profile of the tooth 231 of the conventional hob represented by an imaginary line in
The tooth 221 of the conventional wheel 220 represented by an imaginary line in
In contrast, a tooth 81 of the wheel 80 of the embodiment represented by a solid line in
In contrast, in the embodiment, as illustrated in
In this way, as the amount of rectification of the tooth 91 of the hob 90 becomes larger, the recess on the tooth 81 of the dedendum surface of the wheel 80 decreases, and the dedendum tooth thickness becomes larger as well. Furthermore, a curvature radius of the tooth surface of the tooth 81 around the base circle 111 becomes larger. That is, the tooth surface of the tooth 81 does not form a large projected shape around the base circle 111 as before.
The tooth 81 of the wheel 80 according to the above-described embodiment can also be a tooth 81X of a wheel 80X according to a modification illustrated in
The tooth profile of the tooth 81X according to the modification, for example, is formed to be an intermediate shape of the tooth profile of the conventional tooth 221 and the tooth profile of the tooth 81 according to the embodiment. For example, a dedendum height of the tooth 81 according to the embodiment is the same as a dedendum height of the conventional tooth 221. However, the dedendum height of the tooth 81X according to the modification is smaller than the dedendum height of the tooth 81 according to the embodiment. Furthermore, the dedendum tooth thickness of the tooth 81X according to the modification is larger than the dedendum tooth thickness of the conventional tooth 221, but is smaller than the dedendum tooth thickness of the tooth 81 according to the embodiment. Note, however, that there is no recess in the dedendum surface of the tooth 81X according to the modification.
The tooth 81X according to the modification has a special tooth profile, whereby it cannot be manufactured by a machine for creating an involute profile such as a hobbing machine; however, it can be directly created by injection molding using a metal mold or by milling. That is, in the embodiment, face pressure strength and bending strength of the tooth 81 is enhanced by an indirect method of creating the tooth 81 of the wheel 80 by a hob having a rectified tooth thickness. In contrast, in the modification, the tooth 81X can be created directly to enhance the face pressure strength and the bending strength of the tooth 81X. Accordingly, the tooth profile of the tooth 81X to be obtained can be designed directly and finely. Therefore, it is possible to further improve the tooth 81 according to the embodiment. For example, it is possible to finely change a gear tooth depth, a curvature radius at a tooth bottom, and a tooth thickness.
In creating the tooth 81 of the wheel 80 according to the embodiment illustrated in the above-described
An intersection point of the involute line of action Lia of the tooth 81 of the wheel 80 and the pitch line Lhp of the tooth 91 of the hob 90 is denoted by Px. A straight line from a center CL of the wheel 80 to the intersection point PX is denoted by a standard line Lp. An intersection point of a tooth surface Th1 of the hob 90 of the tooth 91 rectified for the minimum amount of rectification δ only and the base circle 111 of the tooth 81 of the wheel 80 is denoted by Py. A straight line passing through the center CL of the wheel 80 and the intersection point Py is denoted by a rectified standard line Lt. A tilt angle (rectification angle) of the rectified standard line Lt relative to the standard line Lp is denoted by θ. The rectification angle is larger than a pressure angle α of the tooth 81 of the wheel 80 (tooth 91 of the hob 90) as a condition (θ>α).
m: a module of the wheel 80
Z: the number of teeth of the wheel 80
Rb: a radius of the base circle 111 of the wheel 80
Rp: a radius of the pitch circle 112 of the wheel 80
Rp−Rb·cos θ: height from the pitch line Lhp of the tooth 91 of the hob 90 to the intersection point (θ>α).
In this way, in this embodiment, an area in which the tooth profile is rectified by the hob 90, which cuts an involute profile, is a tooth surface in a range where a height from the pitch line Lhp of the hob 90 toward a tooth tip direction, or a height from the pitch line Lhp of the tooth 91 of the hob 90 to the intersection point Py of the hob 90 is Rp−Rb·cos θ or above. Then, the tooth 91 is rectified in a direction of decreasing a tooth thickness thereof by the minimum amount of rectification δ or more at the intersection point Py where a height from the pitch line Lhp is Rp−Rb·cos θ.
The tooth surface of the tooth 91 rectified by the minimum amount of rectification δ is represented by the curve Th1. In this case, the involute line of action Lia of the tooth 81 of the wheel 80 is extended to a line of action L1 on the base circle 111. Furthermore, a tooth surface in a case where the amount of rectification of the tooth 91 is larger than the minimum amount of rectification δ is represented by a curve Th2. In this case, the involute line of action Lia of the tooth 81 of the wheel 80 is extended to a line of action L2, which is inside of the base circle 111. In this way, it is possible to enhance the bending strength of the tooth 81 of the wheel 80.
A theory on which the present invention is based is disclosed below. Note that a constituent element common with that in the above-described embodiment is denoted with the same reference numeral, and a description thereof is omitted.
A major problem in a conventional study has been a study of a tooth profile of an optimal worm for actively causing elastic deformation of a worm wheel. Accordingly, there has been still a room for improvement of a tooth profile of the worm wheel.
In a conventional designing method, in order to highly strengthen the worm wheel, a module and a twist angle are increased to geometrically improve a contact ratio. Using this method, it has been necessary to simply increase a diameter of the worm wheel in size.
In order to overcome this problem, the present inventors have tried to highly strengthen a small-sized worm wheel. In the present invention, the present inventors have further tried to downsize the worm wheel, and newly focused on a profile of dedendum of the worm wheel. As a result, they have reached an idea of improving the contact ratio by effectively meshing the worm even under a base circle of the worm wheel. In order to embody this, first, consideration has been given to a geometrical shape even under the base circle formed in actual processing. Based on the consideration, a theory of effectively meshing even under the base circle is referred to as the MUB (Meshing Under Base circle) theory. The MUB theory is proposed herein.
The tooth profile of the tooth 221 of the conventional worm wheel 220 illustrated in
The tooth profile of the tooth 81 of the worm wheel 80 according to the embodiment illustrated in
Proposal of the MUB theory in which the worm is meshed even under the base circle of the wheel 80
In
In order for the tooth 221 having an involute profile to mesh under the base circle 301, it is necessary to undercut the wheel 220 by the hob (reference numeral 230 in
Analysis of a conventional profile of dedendum not capable of meshing under the base circle
A locus of the hob cutter is illustrated in
In the drawing, a working point (Hob Cutter Working Point) of the hob 230 is denoted by WP. A reference numeral 307 denotes an involute profile portion of the wheel 220. A reference numeral 308 denotes a dedendum portion (Dedendum Formed by Corner Radius) of the wheel 220.
In
When the datum line 312 of the hob 230 contacts a phase point B1 of θ on the pitch circle 302 of the wheel 220, a line segment A1B1 is an unwound arc A0B1, and since both lengths are equal, coordinates (X, Y) of the tooth tip arc center T of the hob 230 can be expressed as Formulas (1) and (2) using θ as a variable.
[Mathematical Formula 4]
X=(Rp+h)sin θ−RPθ cos θ (1)
Y=(Rp+h)cos θ+Rpθ sin θ (2)
Next, the envelope 314 of the tooth tip arc center is obtained. A point E on the envelope 314 is on a normal line 315 of the line 313 (trochoid curve), which passes through a point T. Since a distance TE corresponds to a hob tooth tip radius rh, it can be expressed as Formulas (3) to (5).
Accordingly, the point E (X′, Y′) on the envelope can be expressed as Formulas (6) and (7).
By using the above Formulas (6) and (7), a trochoid curve in a case where the tooth tip arc center point of the hob 230 is shifted is illustrated in
Next, an envelope formed by each of the lines 313 is considered in
A line of action 316 can be extended nearer to a center side than the base circle 301. However, a pressure angle of a contact point. P5 reaches 75 degrees (see P6) and increases up to around 90 degrees. Accordingly, the worm is self-locked and becomes not rotatable (see SL). On the other hand, when a bottom clearance is provided in the worm to avoid this, it does not contact geometrically. In the drawing, PP denotes a pitch point. The pitch point is a point through which a normal line of a tooth surface at a gear meshing contact point always passes. A line 317 is a worm tooth profile (Worm Profile).
In
The envelope 314 under the base circle 301 has an arc shape Novikov tooth profile. Accordingly, a transverse contact ratio becomes less than 1, whereby it is not possible to satisfy an isokinetic, which is a mechanical condition of the gear. In order to transmit constant speed rotation, it is necessary to realize an overlap ratio of 1 or more by a multi-row worm, whereby the wheel is increased in size. In the drawing, MS denotes a simultaneous meshing (Meshing Simultaneously) area.
In
The line of action 316 can be extended nearer to the center side than the base circle 301. The normal line 315 of the envelope 314 at a contact point always passes through the pitch point PP, whereby it satisfies a mechanical condition of the gear, and it is possible to mesh effectively.
In
Proposal of the MUB Theory
Based on the above-described consideration, if the addendum tooth profile of a wheel can be formed by the positive shifted trochoid, it is possible to obtain a tooth profile that can effectively mesh even under the base circle. In order to achieve the positive shifted trochoid, a hob tooth tip (addendum) arc radius may be increased, and a center point of the arc may be shifted in a positive direction of the datum line of the hob.
In
As illustrated in
This meshing theory by which it is possible to effectively mesh even under the base circle 111 is named the Meshing Under Base circle (MUB) theory.
Meshing Considering Elastic Deformation of the Wheel
Up to here, the wheel has been regarded as a rigid body in consideration. Based on the study so far, it is expected that the length of path of contact can be further extended considering elastic deformation of the wheel, whereby consideration is made in order to study this effect.
Considering the elastic deformation of the wheel, as in
Using the tooth 81, it is possible to move an actual meshing line of action when a torque is applied in a direction of the pitch circle 112 of the wheel. The rectified worm meshed with the wheel 80 based on the MUB theory is illustrated in
Next, a meshing contact area is considered. In
As illustrated in
Verification of Test of Meshing by the MUB Theory
To verify meshing performance of the worm designed by the proposed MUB theory, after a change in meshing is calculated according to a worm phase, the worm 70 is actually manufactured and tooth bearing during meshing is verified.
As illustrated in
In
In
These verification results are illustrated in
Based on a phase of the worm at which meshing geometrically starts, a worm rotation direction in a case where meshing progresses from a dedendum to a tooth tip direction is set as a positive direction. Note that a rotation angular velocity of the wheel is set to 1.0 rps, and input torque to the worm is set to 3.2 Nm in the verification.
Since the meshing area of the worm tooth surface corresponds to about 1080 degrees of the worm rotation phase, it is verified that the contact ratio becomes 3.0. The contact ratio is increased by 36% compared to 2.2 of the conventional tooth profile. Furthermore, it is confirmed that the meshing area of the wheel is favorably increased to under the base circle.
These substantially correspond with a result of theory consideration, whereby effect of the MUB theory can be verified. Accordingly, it is now possible to predict meshing of a worm gear mechanism designed based on the MUB theory. Therefore, the MUB theory is effective as a designing method of an electric power steering device (EPS) in which installation of a small-sized and high strength worm gear mechanism is required.
In order to downsize the wheel, there has been proposed the MUB theory in which the contact ratio is improved by effectively meshing even under the base circle, and an effect of the theory has been verified through a test. As a result, the following has become found.
It has been found that the profile of dedendum of the wheel can be categorized into three types according to a shifting direction of the tooth tip arc center point of the hob. The tooth profile formed by the negative shifted trochoid is self-locked, whereby it is found that it cannot mesh effectively under the base circle. The tooth profile formed by the zero shifted trochoid has an are tooth profile under the base circle, whereby a multi-row worm is necessary in order to satisfy the isokinetic of a gear, and it is found that the wheel is increased in size. By the MUB theory in which a dedendum tooth profile is formed by the positive shifted trochoid, it is possible to avoid increasing the wheel size and to effectively mesh under the base circle, with which it has not been possible to mesh with the involute profile. It has been proven that, by applying the MUB theory, it is possible to achieve a high contact ratio of 3.0 even with a single-row worm, which is generally considered to have a low contact ratio.
Descriptions have been given based on an example of installing the worm gear mechanism in an electric power steering device; however, it is also possible to install the worm gear mechanism in other apparatus, and it is not to be limited to the electric power steering device.
The worm gear mechanism according to the present invention is particularly suitable for use on an electric power steering device of a vehicle.
44 worm gear mechanism, 70 worm, 71 worm tooth, 71c worm addendum surface. 74 worm pitch line, 80 worm wheel, 90 hob, 91 hob tooth, 91c hob addendum surface, 93 hob addendum surface center, 94 hob pitch line, WL worm center line, 210 involute profile worm, 220 involute profile worm wheel, 200 conventional worm gear mechanism, WL′ hob center line, L length of recess path, Llim conventional length of recess path.
Number | Date | Country | Kind |
---|---|---|---|
2011-267389 | Dec 2011 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2012/081254 | 12/3/2012 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2013/084838 | 6/13/2013 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3595130 | Maker | Jul 1971 | A |
4651588 | Rouverol | Mar 1987 | A |
5271289 | Baxter, Jr. | Dec 1993 | A |
5829305 | Ham | Nov 1998 | A |
5953957 | Ham | Sep 1999 | A |
6077150 | Jankowski | Jun 2000 | A |
6151941 | Woolf | Nov 2000 | A |
6497041 | Fujita | Dec 2002 | B2 |
6779270 | Sonti | Aug 2004 | B2 |
6976556 | Shimizu | Dec 2005 | B2 |
7600602 | Kuroumaru | Oct 2009 | B2 |
7604088 | Nishizaki | Oct 2009 | B2 |
7641850 | Sontti | Jan 2010 | B2 |
7654167 | Watanabe | Feb 2010 | B2 |
7798033 | Oberle | Sep 2010 | B2 |
7979988 | Shiino | Jul 2011 | B2 |
8683887 | Yamazaki | Apr 2014 | B2 |
20090000120 | Shiino | Jan 2009 | A1 |
20090120711 | Shiino | May 2009 | A1 |
20100307274 | Akiyama | Dec 2010 | A1 |
20140090503 | Ohmi | Apr 2014 | A1 |
20150211622 | Ohmi | Jul 2015 | A1 |
Number | Date | Country |
---|---|---|
2004-330937 | Nov 2004 | JP |
2005-003099 | Jan 2005 | JP |
2007-177812 | Jul 2007 | JP |
2007-269065 | Oct 2007 | JP |
2009-248690 | Oct 2009 | JP |
2010-270908 | Dec 2010 | JP |
Number | Date | Country | |
---|---|---|---|
20140331802 A1 | Nov 2014 | US |