This application is based on and claims the benefit of priority from Japanese Patent application No. 2016-068404 filed on Mar. 30, 2016, which is incorporated by reference in its entirety.
The present disclosure relates to a fixing device which fixes a toner image on a sheet and an image forming apparatus including the same.
An electrophotographic type image forming apparatus includes a fixing device which fixes a toner image transferred on a sheet, such as a paper, on the sheet.
An example of the fixing device includes a pressuring roller which comes into pressure contact with an endless fixing belt which is heated. A pressing pad comes in contact with an inner circumferential face of the fixing belt to press the fixing belt to the pressuring roller. The pressing pad is made of material having a high elastic coefficient. Pressing force of the pressing pad to the pressuring roller is higher at a downstream side than at an upstream side in a movement direction of the fixing belt. By rotating the fixing belt with large curvature at an exit of a pressure contact area, the sheet can be separated from the fixing belt adequately.
Another example of the fixing device includes a pair of upper and lower approach guides which guides the sheet to a fixing nip. Each approach guide is fixed to a frame of the fixing device.
In accordance with an aspect of the present disclosure, a fixing device includes a fixing member, a pressuring member, a deforming part, an approach guide and a guide adjusting part. The fixing member is rotatable and heated by a heat source. The pressuring member is rotatable and forms a fixing nip between the fixing member and the pressuring member. The deforming part deforms the fixing nip. The approach guide guides a sheet to the fixing nip. The guide adjusting part moves the approach guide to a position corresponding to the fixing nip after deformation, as the deforming part deforms the fixing nip.
In accordance with an aspect of the present disclosure, an image forming apparatus includes an image forming part and the fixing device. The image forming part transfers a toner image on a sheet. The fixing device fixes the toner image on the sheet.
The above and other objects, features, and advantages of the present disclosure will become more apparent from the following description when taken in conjunction with the accompanying drawings in which a preferred embodiment of the present disclosure is shown by way of illustrative example.
Hereinafter, with reference to the attached drawings, a preferable embodiment of the present disclosure will be described. The following description is based on directions shown in each figure.
With reference to
The printer 1 includes an apparatus main body 2, a sheet feeding cassette 3 and an ejection tray 4. The sheet feeding cassette 3 is provided in a lower portion of the apparatus main body 2 and stores the sheets S (a bundle of sheets S). The ejection tray 4 is formed on an upper face of the apparatus main body 2.
The printer 1 further includes a sheet feeding part 10, an image forming part 11, a fixing device 12, an ejecting part 13 and a control device 14. The sheet feeding part 10 is disposed on an upstream side end portion of a conveying path 15 extending from the sheet feeding cassette 3 to the ejection tray 4. The sheet feeding part 10 feeds the sheet S stored in the sheet feeding cassette 3 toward the conveying path 15 one by one. The image forming part 11 is disposed on a middle portion of the conveying path 15. The fixing device 12 is disposed closer to the downstream side of the conveying path 15 than the image forming part 11. The ejecting part 13 is disposed on a downstream side end portion of the conveying path 15. The control device 14 totally controls the printer 1.
The image forming part 11 has a drum unit 21 which forms a toner image using a toner (a developer) supplied from a toner container 20. The drum unit 21 develops a latent image formed by an exposure of an optical scanning device 22 into the toner image. The image forming part 11 (the drum unit 21) transfers the toner image on the sheet S conveyed along the conveying path 15. The fixing device 12 fixes the toner image on the sheet S. The sheet S having the toner image is ejected by the ejecting part 13 on the ejection tray 4.
Next, with reference to
As shown in
The fixing belt 30 as a fixing member has flexibility, and is formed into an endless shape. The fixing belt 30 is formed into a cylindrical shape elongated in the left and right direction (a direction of a rotation axis). The fixing belt 30 is supported by the fixing frame (not shown) so as to be capable of rotating (circulating). The fixing belt 30 is formed by laminating a substrate layer, an elastic layer and a releasing layer in the order from an inner side (they are not shown). The substrate layer is made of polyimide resin mixed with nickel or metal powder, for example. The elastic layer is made of silicon rubber, for example. The releasing layer is made of fluororesin, for example.
As shown in
At the right side of the fixing belt 30, a rotation detecting mechanism 38 is provided. The rotation detecting mechanism 38 has a transmitting gear 38a, a rotating pulse plate 38b and a rotation detecting sensor 38c. The transmitting gear 38a is meshed with the connecting gear 37b of the right cap 37 to transmit rotation of the fixing belt 30 to the rotating pulse plate 38b. The rotating pulse plate 38b has a plurality of light-shielding pieces (not shown) aligned in a circumferential direction at equal intervals. The rotation detecting sensor 38c is a photo-interrupter having a light emitting part and a light receiving part which oppose to each other on both sides of the rotating pulse plate 38b. The rotation detecting sensor 38c transmits light receiving information changing depending on rotation of the rotating pulse plate 38b to the control device 14. One or more rotation detecting sensor 38c may be provided so as to detect rotation of at least one of the pair of left and right caps 37.
As shown in
As shown in
As shown in
The deforming part 34 is provided in order to press the fixing belt 30 to the pressuring roller 31. The deforming part 34 is configured to deform a shape of the fixing nip N. The deforming part 34 has a supporting stay 40, a switching adjusting part 41, two pressing pads 42 and 43, a switching detecting mechanism 44 and a belt guide 45.
The supporting stay 40 as a supporting member extends in an inner space of the fixing belt 30 in the left and right direction. Both left and right end portions of the supporting stay 40 are loosely fitted in the through holes 37c of the pair of left and right caps 37. The both left and right end portions of the supporting stay 40 protrude outside from the inner space of the fixing belt 30, and are supported by the fixing frame. A middle portion of the supporting stay 40 in the left and right direction has a sectional view of a substantially U-shape whose lower side is opened (refer to
As shown in
As shown in
The two pressing pads 42 and 43 as pressing members are each made of heat-resistant resin, such as liquid crystal polymer, and formed into a substantially rectangular parallelepiped shape elongated in the left and right direction. As shown in
The two pressing pads 42 and 43 are rotatable around the switching rotation shaft 46. The switching motor 47 is configured to be capable of keeping a position (a posture) of each of the pressing pads 42 and 43. A selected one of the two pressing pads 42 and 43 makes the downward pressure contact face 42a (or 43a) come into pressure contact with the inner circumferential face 30a of the fixing belt 30. Thereby, the fixing nip N is formed between the fixing belt 30 and the pressuring roller 31.
As shown in
The first pressing pad 42 (the pressure contact face 42a) is formed such that a difference in the width between the both left and right end portions and the center portion in the left and right direction is larger than that of the second pressing pad 43 (the pressure contact face 43a) (G1>G2). A width of the center portion of the pressure contact face 42a in the left and right direction is narrower than a width of the center portion of the pressure contact face 43a in the left and right direction. That is, the pressure contact face 42a narrows at the center portion in the left and right direction more largely than the pressure contact face 43a. Accordingly, a ratio of the nip width of the both left and right end portions to the nip width of the center portion in the left and right direction is larger at the fixing nip N1 than at the fixing nip N2.
A sliding sheet made of fluororesin may be fixed on the pressure contact faces 42a and 43a of the pressing pads 42 and 43. In addition, the inner circumferential face 30a of the fixing belt 30 may be coated with coating material made of polyimide, polyamide-imide or polytetrafluoroethylene (PTFE).
As shown in
As shown in
The approach guide 35 is turnable around the guide shaft 35a. The approach guide 35 is turnable between a first position P1 (refer to
The guide adjusting part 36 is provided in order to transmit rotation force from the switching adjusting part 41 to the approach guide 35 and to turn the approach guide 35 corresponding to deformation of the fixing nip N. The guide adjusting part 36 has a guide gear train 50 and a pair of left and right adjusting cams 51.
The guide gear train 50 as a drive transmitting part has a guide intermediate gear 50a and a guide drive gear 50b. The guide intermediate gear 50a is a so-called spur gear, and rotatably supported by the fixing frame. The guide intermediate gear 50a is meshed with the pinion gear 47a of the switching motor 47. The guide drive gear 50b is a so-called spur gear, and fixed to an adjusting shaft 50c extending in the left and right direction. The guide drive gear 50b is meshed with the guide intermediate gear 50a. Accordingly, the guide intermediate gear 50a and the guide drive gear 50b are driven by the switching motor 47 to be rotated. Both left and right end portions of the adjusting shaft 50c are rotatably supported by the fixing frame.
A gear ratio of the switching gear train 48 (the gears 48a and 48b) to the guide gear train 50 (the gears 50a and 50b) is set such that a rotation angle of the switching rotation shaft 46 is equal to a rotation angle of each adjusting cam 51.
The pair of left and right adjusting cams 51 is fixed to the both left and right end portions of the adjusting shaft 50c. Each adjusting cam 51 rotates around the adjusting shaft 50c together with the guide drive gear 50b. The above described guide gear train 50 transmits the rotation force of the switching adjusting part 41 (the switching motor 47) to each adjusting cam 51. Around an outer circumferential face of each adjusting cam 51, a first cam face 51a and a second cam face 51b are formed. The first cam face 51a and the second cam face 51b are respectively formed around one half and the other half of the outer circumferential face of each adjusting cam 51. The first cam face 51a and the second cam face 51b are formed into curved faces having curvatures different from each other. The first cam face 51a has a curvature smaller (a radius of curvature larger) than that of the second cam face 51b.
Each adjusting cam 51 is provided in contact with the approach guide 35. In a state where the first cam face 51a of each adjusting cam 51 comes into contact with each guide plate 35b, the approach guide 35 is turned to the first position P1 (refer to
The printer 1 includes an operation panel 60 (refer to
The above described control device 14 has an arithmetic processing part (not shown) executing an arithmetic processing according to a program stored in a storage part (not shown). As shown in
Next, an operation of the deforming part 34 of the fixing device 12 will be described.
Information showing the size and the type of the sheet S, which are input by the user through the operation panel 60 or the external terminal, is transmitted to the control device 14. The control device 14 controls the switching adjusting part 41 (the switching motor 47) on the basis of the type of the sheet S passing through the fixing nip N (switching control). The switching adjusting part 41 rotates the two pressing pads 42 and 43 around the switching rotation shaft 46 to switch the pressing pads 42 and 43 so as to make either one of them come into pressure contact with the inner circumferential face 30a of the fixing belt 30. That is, the switching adjusting part 41 deforms the fixing nip N.
For instance, when the sheet S which is easy to be crinkled, such as an envelope and a thin paper, is subjected to the fixing processing, the control device 14 controls the switching adjusting part 41 to make the first pressing pad 42 come into pressure contact with the inner circumferential face 30a of the fixing belt 30. In detail, the control device 14 receives an output signal (a detection result) output from the switching detecting sensor 44b, and recognizes that either of the two pressing pads 42 or 43 comes into contact with the inner circumferential face 30a of the fixing belt 30. The control device 14 controls the switching adjusting part 41 on the basis of the detection result of the switching detecting mechanism 44 (the switching detecting sensor 44b).
As shown in
On the other hand, as shown in
In this case, the switching motor 47 is controlled by the control device 14 to rotate the switching rotation shaft 46 by a predetermined angle (for example, 180 degrees). The switching motor 4 rotates the switching rotation shaft 46 until the first pressing pad 42 comes into contact with the inner circumferential face 30a of the fixing belt 30. Thereby, the fixing nip N is switched from the second fixing nip N2 to the first fixing nip N1 (refer to
As described above, as the deforming part 34 deforms the fixing nip N from the second fixing nip N2 to the first fixing nip N1, the guide adjusting part 36 makes the approach guide 35 turn to the first position P1 where the approach guide 35 corresponds to the first fixing nip N1 after the deformation. The storage part of the control device 14 previously stores (sets) information showing a rotation angle of the switching rotation shaft 46 used for switching the two pressing pads 42 and 43. The control device 14 recognizes the rotation angle of the switching rotation shaft 46 on the basis of the detection result of the switching detecting sensor 44b. The control device 14 calculates a rotation angle of the switching motor 47 using the information stored in the storage part and the detection result of the switching detecting censor 44b. The switching motor 47 (the switching rotation shaft 46) may be rotated in the clockwise direction or the counterclockwise direction in
In another case, when the sheet S which is hard to be crinkled, such as a plain paper and a thick paper, is subjected to the fixing processing, the control device 14 switches and controls the switching adjusting part 41 such that the second pressing pad 43 comes into pressure contact with the inner circumferential face 30a of the fixing belt 30. Thereby, the second fixing nip N2 is formed, and the approach guide 35 is turned to the second position P2 (refer to
After that, the control device 14 executes the image forming processing as described above. The fixing drive motor 32a is controlled by the control device 14 to rotate the pressuring roller 31. The fixing belt 30 is driven by the pressuring roller 31 to be rotated. The rotation detecting sensor 38c detects the rotation of the rotating pulse plate 38b. The control device 14 receives the detection result of the rotation detecting sensor 38c, and then drives the IH heater 33. The IH heater 33 heats the fixing belt 30. The fixing device 12 presses and heats the sheet S passing through the fixing nip N to fix the toner image on the sheet S (the fixing processing). If the rotation detecting sensor 38c does not detect the rotation of the rotating pulse plate 38b (the fixing belt 30), the control device 14 does not drive the IH heater 33 and displays an error message on the operation panel 60 or the like.
As described above, depending on the type of the sheet S, either one of the first pressing pad 42 or the second pressing pad 43 is selected. That is, depending on the type of the sheet S, the nip width can be changed. Thereby, even in the case where the sheet S which is easy to crinkled, such as an envelope and a thin paper, is subjected to the fixing processing, the sheet S can be prevented from being crinkled.
According to the fixing device 12 of the first embodiment as described above, the guide adjusting part 36 turns (moves) the approach guide 35 corresponding to the fixing nip N (N1 or N2) deformed by the deforming part 34. In addition, the movement of the approach guide 35 by the guide adjusting part 36 is linked with the deformation of the fixing nip N by the deforming part 34. Thereby, the approach guide 35 can be turned to a position suitable for the shape of the fixing nip N so that the sheet S can be guided to the fixing nip N smoothly.
In addition, according to the fixing device 12 of the first embodiment, the switching adjusting part 41 makes one selected from the two pressing pads 42 and 43 come into pressure contact with the inner circumferential face 30a of the fixing belt 30. The nip width is changeable by switching the pressing pads 42 and 43. Because the fixing nips N1 and N2 each have the nip width which is wider at the both end portions than the center portion in the left and right direction, force for conveying the sheet S (conveying force) is larger at the both end portions than at the center portion in the left and right direction. Thereby, the sheet S is conveyed while extending in the left and right direction and, therefore, can be prevented from being crinkled. Accordingly, it becomes possible to form the fixing nip N where the sheet S can be conveyed appropriately, the toner image can be fixed on the sheet S appropriately and the sheet S is hard to be crinkled.
Furthermore, force for rotating each of the pressing pads 42 and 43 (rotation force) is transmitted to the approach guide 35 via the guide adjusting part 36 to turn the approach guide 35. That is, the switching adjusting part 41 is used in common as a drive source which rotates each of the pressing pads 42 and 43 and turns the approach guide 35. Thereby, the deformation of the fixing nip N and the movement of the approach guide 35 can be linked with each other by a simple configuration.
Furthermore, according to the fixing device 12 of the first embodiment, the approach guide 35 slides relative to each of the cam faces 51a and 51b of each adjusting cam 51 to be turned to a position (P1 or P2) corresponding to the fixing nip N (N1 or N2) after the deformation. In this way, use of a cam mechanism in the guide adjusting part 36 can appropriately link the deformation of the fixing nip N with the movement of the approach guide 35.
The fixing device 12 of the first embodiment is provided with the two pressing pads 42 and 43. However, the present disclosure is not limited to the number of the pressing pad. For instance, two or more pressing pads may be provided. In this case, in order to correspond to change in the number of the pressing pad (the number of the deformed shape of the fixing nip N), each adjusting cam 51 of the guide adjusting part 36 may have two or more cam faces so as to turn the approach guide 35 to two or more positions. Furthermore, in the first embodiment, the two pressing pads 42 and 43 are fixed to one switching rotation shaft 46 and rotatably supported around the switching rotation shaft 46. However, the present disclosure is not limited to the embodiment. For instance, a plurality of pressing pads may be lineally moved upward and downward.
Next, with reference to
As shown in
The pressing member 72 is made of heat-resistant resin, such as liquid crystal polymer, for example, and extends in the inner space of the fixing belt 30 in the left and right direction. The pressing member 72 has a pressing pad 75 and a base material 76 fixed on an upper face of the pressing pad 75. The pressing pad 75 is formed into a substantially rectangular parallelepiped shape elongated in the left and right direction. The base material 76 is formed into a substantially plate shape elongated in the left and right direction. An upper face of the base material 76 is fixed on a lower face of the supporting stay 71. The pressing pad 75 has a pressure contact face 77 which comes into pressure contact with the inner circumferential face 30a of the fixing belt 30. The pressure contact face 77 forms a lower face of the pressing pad 75.
As shown in
As shown in
The rotation shaft 80 is supported between a pair of left and right bearing parts 80a so as to be rotatable around an axis in the rotation space SP. A right end portion of the rotation shaft 80 penetrates through the bearing part 80a, and protrudes rightward from the supporting stay 71. The three eccentric cams 81 are disposed corresponding to the three pressure changing faces 78 of the pressing member 72, and fixed to the rotation shaft 80. Each eccentric cam 81 penetrates through the supporting stay 71, and is rotatable in a state where each eccentric cam 81 is in pressure contact with the upper face (a sliding face 79) of the base material 76.
As shown in
As shown in
As shown in
As shown in
The guide intermediate gear 50a of the guide adjusting part 36 is meshed with the pinion gear 84a of the adjusting motor 84. Accordingly, the guide intermediate gear 50a and the guide drive gear 50b are driven by the adjusting motor 84 to be rotated. A gear ratio of the adjusting gear train 85 (the gears 85a and 85b) to the guide gear train 50 (the gears 50a and 50b) is set such that a rotation angle of the rotation shaft 80 is equal to a rotation angle of each adjusting cam 51.
As shown in
Next, an operation of the deforming part 70 will be described. The adjusting motor 84 is controlled by the control device 14 to rotate the three eccentric cams 81 which are in contact with the sliding face 79 of the pressing member 72, around the rotation shaft 80. In this way, the pressing adjusting part 73 changes the pressing force applied on a part (the three pressure changing faces 78) of the pressure contact face 77 in the direction of the rotation axis to deform the fixing nip N. Each eccentric cam 81 is set such that either one of the point portions 831 to 834 comes into contact with the sliding face 79.
For instance, as shown in
The pressing member 72 is elastically deformed in the width direction depending on force with which the pressing member 72 is pressed on the inner circumferential face 30a of the fixing belt 30. As shown in
On the other hand, as shown
Next, a pressure changing control by the deforming part 70 will be described. Each eccentric cam 81 is set in the standard state.
The control device 14 controls the pressing adjusting part 73 on the basis of the type of the sheet S passing through the fixing nip N (the pressure changing control). The storage part of the control device 14 previously stores information showing a rotation angle used for recognizing a contact position where each cam face 83 (the point portions 831 to 834) comes into contact with the sliding face 79. The control device 14 recognizes the rotation angle of each eccentric cam 81 (a state of each eccentric cam 81) on the basis of a detection result of the angle detecting sensor 74b, and controls the adjusting motor 84. The control device 14 calculates a rotation angle of the adjusting motor 84 using the information stored in the storage part and the detection result of the angle detecting sensor 74b. The pressing adjusting part 73 changes the contact position where the cam face 83 of each eccentric cam 81 comes into contact with the sliding face 79 of the pressing member 72.
For instance, when the sheet S which is hard to be crinkled is subjected to the fixing processing, the control device 14 controls each eccentric cam 81 to rotate (switch) it to the standard state. That is, the control device 14 performs control for forming the standard nip N10 (refer to
Next, for instance, when the sheet S which is easy to be crinkled is subjected to the fixing processing, the control device 14 controls each eccentric cam 81 to rotate it to the center pressure decreased state and to form the center pressure decreased nip N20 (refer to
At the same time of the rotation of the rotation shaft 80, the adjusting motor 84 rotates the guide gear train 50 and each adjusting cam 51. For instance, when the rotation shaft 80 is rotated by 270 degrees in the clockwise direction in
After that, the control device 14 executes the image forming processing by the image forming part 11 and the others. In the above description about the pressure changing control, as an example, the standard nip N10 is formed when the sheet S, such as a plain paper and a thick paper, is subjected to the fixing processing. However, the present disclosure is not limited to the above example. For instance, the control device 14 may perform the pressure changing controls different between a thick paper and a plain paper (which is thinner than the thick paper and thicker than a thin paper). That is, the control device 14 may perform the pressure changing control to form the standard nip N10 (refer to
According to the fixing device 16 of the second embodiment as described above, the pressing adjusting part 73 adjusts (increases or decreases) the pressing force applied on the inner circumferential face 30a of the fixing belt 30 by a part (each pressure changing face 78) of the pressure contact face 77 in the left and right direction. Increasing and decreasing of the pressing force changes (increases or decreases) the nip width of the fixing nip N. Accordingly, it becomes possible to form the fixing nip N where the sheet S can be conveyed appropriately, the toner image can be fixed on the sheet S appropriately and the sheet S is hard to be crinkled. In addition, the center pressure decreased nip N20 has the nip width which is wider at the both end portions than at the center portion in the left and right direction. Thus, the force for conveying the sheet S (the conveying force) is larger at the both end portions than at the center portion in the left and right direction. Thereby, the sheet S is conveyed while extending in the left and right direction and, therefore, can be prevented from being crinkled.
The guide adjusting part 36 transmits the rotation force from the pressing adjusting part 73 to the approach guide 35 and turns the approach guide 35 by linking with the deformation of the fixing nip N. The force for rotating each eccentric cam 81 (the rotation force) is transmitted to the approach guide 35 via the guide adjusting part 36 and turns the approach guide 35. That is, the pressing adjusting part 73 is used in common as a drive source which rotates each eccentric cam 81 and turns the approach guide 35. Thereby, the deformation of the fixing nip N and the turning of the approach guide 35 can be linked by a simple configuration.
The fixing device 16 of the second embodiment is provided with the three eccentric cams 81. However, the present disclosure is not limited to the number of the eccentric cam 81. One or more eccentric cams 81 may be provided. For instance, a single eccentric cam 81 may come into contact with the center portion of the pressing member 72 in the left and right direction. Alternatively, four or more eccentric cams 81 may come into contact with the pressing member 72. In addition, the three eccentric cams 81 each has the same shape in the embodiment. However, the present disclosure is not limited to the embodiment. For instance, each end cam 81a may be formed such that the pressing force applied on the pressure changing face 78 is larger.
Next, the fixing devices 12 and 16 of modified examples of the first and second embodiments will be described. In the flowing description, the same configuration as the fixing devices 12 and 16 of the first and second embodiments is shown with the same reference number as the first and second embodiments, and its description is omitted.
Under a high temperature and high humidity environment, because of increase in a moisture content of the sheet S, sheet conveying failure may easily occur or the sheet S may be easy to be crinkled. Thus, the fixing devices 12 and 16 of the modified examples are configured to change the fixing nip N depending on the environment condition.
The control device 14 controls the switching adjusting part 41 (or the pressing adjusting part 73) on the basis of a detection result of the temperature/humidity sensor 61 (refer to
The control device 14 may perform the switching control on the basis of a temperature detected by the temperature/humidity sensor 61, instead of the humidity detected by the temperature/humidity sensor 61. That is, the control device 14 is set to control the switching adjusting part 41 (or the pressing adjusting part 73) on the basis of at least one of the environment temperature and the environment humidity.
In the fixing device 12 of the first embodiment, the switching gear train 48 and the guide gear train 50 are rotated by the switching motor 47. As with this, in the fixing device 16 of the second embodiment, the adjusting gear train 85 and the guide gear train 50 are rotated by the adjusting motor 84. Instead of these configurations, for instance, a dedicated drive motor which rotates each adjusting cam 51 via the guide gear train 50 may be provided separately. In this case, the control device 14 may drive the switching motor 47 (or the adjusting motor 84) synchronously with the drive motor.
In the first and second embodiments, the control device 14 controls the printer 1 totally. However, the present disclosure is not limited to the control device 14. For instance, a dedicated control part which controls the fixing devices 12 and 16 may be separately provided. In addition, in the first and second embodiments, the IH heater 33 is used as the heat source. However, the present disclosure is not limited to the embodiments. For instance, a heat source such as a halogen heater may be disposed in the inner space of the fixing belt 30.
The first and second embodiments were described in a case where configurations of the disclosure are applied to the monochromatic printer 1 as an example. However, the configurations of the disclosure may be applied to a color printer, a copying machine, a facsimile, a multifunctional peripheral or the like, other than the monochromatic printer 1.
While the present disclosure has been described with reference to the particular illustrative embodiments, it is not to be restricted by the embodiments. It is to be appreciated that those skilled in the art can change or modify the embodiments without departing from the scope and spirit of the present disclosure.
Number | Date | Country | Kind |
---|---|---|---|
2016-068404 | Mar 2016 | JP | national |