The present invention relates to a sliding mechanism and a portable device, and more particularly, to a sliding mechanism having a tilting structure, and a portable device.
In recent years, a slide-type mobile phone, which is one of portable devices, can be used in both an open state and a closed state, in the case of using a telephone call function, a mail function, a menu function, an Internet function, a game function, a camera function, a music function, a television function, and the like.
Patent literatures 2 to 5 disclose other structures for providing a tilt angle.
Patent literature 1: Japanese Unexamined Patent Application Publication No. 2006-186577
Patent literature 2: Japanese Unexamined Patent Application Publication No. 2007-74411
Patent literature 3: Japanese Unexamined Patent Application Publication No. 2007-132508
Patent literature 4: Japanese Unexamined Patent Application Publication No. 2009-71511
Patent literature 5: Japanese Unexamined Patent Application Publication No. 2009-88667
However, in the case of using a mobile phone in a crowded train, for example, a user's arm is bent to a greater degree as shown in
As shown in
The present invention has been made in view of the above-mentioned problem, and an object of the present invention is to provide a sliding mechanism and a portable device which are capable of changing a tilt angle with a simple configuration.
A sliding mechanism according to an aspect of the present invention includes: a first frame provided with a slide rail having a sliding direction that changes; a second frame that slides along the slide rail; an elastic member that generates an urging force between the first frame and the second frame according to a slide position of each of the first frame and the second frame; a link that is mounted slidably with respect to the slide rail and rotates to change a tilt angle of the first frame with respect to the second frame; a first stopper that regulates the rotation of the link; and a second stopper that regulates the rotation of the link from a direction different from that of the first stopper.
According to the present invention, it is possible to provide a sliding mechanism and a portable device which are capable of changing a tilt angle with a simple configuration.
Hereinafter, exemplary embodiments of the present invention will be described. Note that the size and ratio of each component shown in the attached drawings are illustrated for convenience of explanation, and are not necessarily the same as the actual size and ratio.
The first casing 10 and the second casing 20 have a substantially rectangular parallelepiped shape and substantially the same size. In the closed state, the first casing 10 and the second casing 20 overlap each other, and the first casing 10 and the second casing 20 do not protrude from each other. In other words, in the closed state, the outer shape of the mobile phone 1 is a substantially rectangular parallelepiped. The display unit 11 is disposed on a front surface side (on a surface opposite to the second casing of the first casing 10), and is visible in both the open state and the closed state. An input unit 21 is disposed on a surface at the first casing side of the second casing 20. Accordingly, in the closed state, the input unit 21 is opposed to the back surface of the first casing 10 and thus is hidden.
The first casing 10 is slidably supported in a direction indicated by an arrow A with respect to the second casing 20. Specifically, the second casing 20 is slidably provided along slide rails (not shown in
Note that the input unit 21 appears in the open state, which allows the user to manipulate the input keys and the like. The sliding direction parallel with the display unit 11 is defined as the lengthwise direction of the mobile phone 1. The direction perpendicular to the display surface of the display unit 11 is defined as the thickness direction of the mobile phone 1. Further, the direction perpendicular to each of the lengthwise direction and the thickness direction is defined as the width direction of the mobile phone 1.
The mobile phone 1 has a tilting mechanism. Accordingly, when the first casing 10, which is in parallel with the second casing 20 in the closed state, shifts to the open state, the first casing is tilted in a direction indicated by an arrow B. As the first casing 10 is caused to further slide, the first casing 10 is gradually tilted with respect to the second casing 20 during the sliding. Thus, the mobile phone 1 has a tilt-sliding mechanism.
Referring next to
Screw holes 22 are formed in the front surface of the second casing 20. Screw bosses 41 are formed on a second frame 40. The second frame 40 and the second casing 20 are screwed using the screw holes 22 and the screw bosses 41. Each of the first frame 30 and the second frame 40 is a hinge frame that constitutes a hinge unit 100. The hinge unit 100 is a sliding mechanism with a tilt (tilt-sliding mechanism). That is, the first frame 30 is tilted with respect to the second frame 40. The second frame 40 slidably supports the first frame 30. A relative position of the first frame 30 relative to the second frame 40 is changed, thereby allowing the mobile phone 1 to perform a sliding action. In other words, when the first frame 30 is caused to slide with respect to the second frame 40, the first casing 10 mounted on the first frame 30 slides with respect to the second casing 20 mounted on the second frame 40. Since the first frame 30 and the second frame 40 slide relatively to each other, when one frame is gripped, the other frame slides.
Next, a detailed configuration of the hinge unit 100 will be described with reference to
The first frame 30 is a plate-like member with both ends rising upward. Accordingly, L-shaped side walls are formed at both ends of the flat plate. The first frame 30 is for example, a sheet metal press work, a metal molded product, a resin molded product, or an integrally molded product of metal and resin. In this case, the first frame 30 is a sheet metal part having a U-shaped cross section with both sides folded into an L-shape. The first frame 30 is provided with the screw holes 31, notches 32, and a long hole 33. The central long hole 33 is a through-hole formed in a flexible substrate. Specifically, FTCs (Flexible Printed Circuits) or the like to be connected with electronic circuits or the like provided in the first casing 10 are inserted into the long hole 33. The flexible substrate is used to transmit electrical signals between the first casing 10 and the second casing 20, for example.
The rails 70 are respectively provided at both ends of the first frame 30. The rails 70 are rod-like members each having a longitudinal direction. The two rails 70 are members having substantially the same shape. A groove 71 extending along the longitudinal direction is formed on one surface of each of the rails 70. Each of the rails 70 is, for example, a metal sheet press-forged product, a metal molded product, a resin molded product, or an integrally molded product of metal and resin. In this case, each of the rails 70 is a metal sheet forged part having a U-shaped cross section. The two rails 70 are arranged in parallel along the sliding direction. The second frame 40 slides and moves along the rails 70. As shown in
The pair of rails 70 is arranged side by side such that the grooves 71 face each other. First pins 51, second pins 42, and third pins 43 are disposed in the grooves 71 that are formed in the rails 70. The first pins 51, the second pins 42, and the third pins 43 slide along the rails 70. This allows the second frame 40 to slide with respect to the first frame 30. Further, a curved portion 72 is provided to each of the grooves 71 of the rails 70 to carry out a tilting action. Specifically, the direction of each groove 71 changes at the curved portion 72, and thus each groove 71 is formed in a doglegged shape. In the case of sliding and moving to the open state, the position of each of the first pins 51 is away from the second casing 20, for example, in the thickness direction of the mobile phone 1. In the thickness direction of the mobile phone 1, the leading end of the first casing 10 slides away from the second casing 20. In this manner, the tilt sliding action is carried out.
Assume herein that each of the grooves 71 has a linear portion 71a which is located on the right side of the curved portion 72, and a tilted portion 71b which is located on the left side of the curved portion 72. In the closed state, the linear portion 71a is in substantially parallel with the front surface of the second casing 20. The tilted portion 71b is tilted with respect to the linear portion 71a. In the closed state, the first pins 51, the second pins 42, and the third pins 43 are located at the linear portion 71a. This allows the first pins 51, the second pins, and the third pins 43 to be arranged at the same height as the front surface of the second casing 20. In the open state, the first pins 51 are located at the linear portion 71a; the second pins 42 are located at the vicinity of the curved portion 72; and the third pins 43 are located at the tilted portion 71b. Thus, the height of each first pin 51 with respect to the front surface of the second casing 20 is different from the height of each of the second pins 42 and the third pins 43. Accordingly, in the open state, the first casing 10 is tilted with respect to the second casing 20. When each of the third pins 43 passes through the linear portion 71a and moves toward the curved portion 72, the height of the first pins 51 increases. In other words, the distance in the thickness direction from the front surface of the second casing 20 to each first pin 51 increases. As a result, the first casing 10 is gradually tilted with respect to the second casing 20 in the middle of the sliding action.
The link 50 is connected to the two rails 70. Specifically, the link 50 is slidably mounted to the rails 70. The link 50 is, for example, a sheet metal press work, a metal molded product, a resin molded product, or an integrally molded product of metal and resin. In this case, the link 50 is a plate-like metal part. The link 50 is a member having a longitudinal direction, and is disposed perpendicularly to the rails 70. Accordingly, one end of the link 50 is mounted on one of the rails 70, and the other end of the link 50 is mounted on the other rail 70. As shown in
Thus, the first pins 51 and the shafts 52 are disposed at both ends of the link 50. The first pins 51 are inserted into the respective grooves 71. The width of each of the grooves 71 and the diameter of each of the first pins 51 are designed so as to provide a slight clearance to each groove 71. This allows the first pins 51 to slide with respect to the respective grooves 71. Each of the first pins 51 is, for example, a sheet metal press work, a metal molded product, a resin molded product, or an integrally molded product of metal and resin. The link 50 and the first pins 51 are connected together by an integral product, welding, placing, or the like. The first pin 51 and the shaft 52 are arranged side by side on each of the ribs 50b. Each shaft 52 is disposed at a position closer to the second frame 40 than the corresponding first pin 51. The height of each shaft 52 is lower than that of each of the first pins 51. The shafts 52 are inserted into respective shaft holes 44 of the second frame 40. The link 50 is decentered with respect to each shaft 52.
The second frame 40 is a frame-like member with both ends rising and being in close contact with the rails 70. The second frame 40 is, for example, a sheet metal press work, a metal molded product, a resin molded product, or an integrally molded product of metal and resin. The second frame 40 is disposed below the first frame 30. The second frame is provide with the screw bosses 41, the second pins 42, the third pins 43, the shaft holes 44, a second spring base 45, and a first stopper 47. The second pins 42 are respectively provided at both ends of the second frame 40. Also the third pins 43 are respectively provided at both ends of the second frame 40. Each of the second pins 42 and the third pins 43 has a cylindrical shape projecting outward. Each of the second pins 42 and the third pins 43 project to the inside of the grooves 71, and slides with respect to the grooves 71. That is, the second pins 42 and the third pins 43 are inserted into the grooves 71 as described above. In each of the grooves 71, each of the second pins 42 is disposed between the corresponding third pin 43 and the corresponding first pin 51. Each of the second pins 42 and the third pins 43 is, for example, a sheet metal press work, a metal molded product, a resin molded product, or an integrally molded product of metal and resin. The second frame 40, the second pins 42, and the third pins 43 are connected together by an integral product, welding, placing, or the like.
The first pins 51, the second pins 42, and the third pins 43 are slidably connected to the grooves 71 of the rails 70. That is, the second frame 40 slides with respect to the rails 70 that are formed on the first frame 30.
The two shaft holes 44 are formed in the second frame 40. The two shaft holes 44 are coaxially arranged in the vicinity of the corners of the second frame 40. As described above, the shafts 52 of the link 50 are inserted into the respective shaft holes 44. The link 50 rotates with respect to the second frame 40 with the central axis of the column of each shaft 52 as a rotation axis. In other words, the second frame 40 rotatably supports the link 50. When the link 50 is allowed to rise, the tilt angle increases, and when the link 50 is allowed to fall, the tilt angle decreases. The second frame 40 is also provided with the first stopper 47 for controlling the tilt angle. The first stoppers 47 are disposed in the vicinity of each of the shaft holes 44. The first stopper 47 contacts the link 50, thereby regulating the rotation of the link 50. This enables limitation of the tilt angle.
Furthermore, the second spring base 45 is provided in the vicinity of a corner of the second frame 40. The second spring base 45 is formed of a part of the second frame 40. The second spring base 45 is mounted with a second spring support 46 that receives the assist spring 60. The second spring support 46 is a metal molded product, a resin molded product, or the like. The second spring base 45 and the second spring support 46 are connected together by fitting. The second spring support 46 is connected with the assist spring 60.
In the second spring base 45, the assist spring 60 is mounted on the second frame 40 through the second spring support 46. The assist spring 60 is a metal product. The assist spring 60 and the second spring support 46 are connected together by fitting. The assist spring 60 is an elastic member that generates an urging force depending on the slide position. Specifically, the assist spring 60 generates an urging force in the direction in which the sliding operation of the user is assisted. An urging force may be generated between the first frame 30 and the second frame 40 by using an elastic member other than a spring.
At the center of the assist spring 60, a spiral portion 61 which is obtained by winding a metal line in a spiral shape is formed. The metal line extends substantially linearly from the spiral portion 61 to one end 62 of the assist spring 60. Further, the metal line extends substantially linearly from the spiral portion 61 to the other end 63 of the assist spring 60. The metal line extending from the spiral portion 61 to the one end 62 and the metal line extending from the spiral portion 61 to the other end 63 are inclined. Here, the metal line extending from the spiral portion 61 to the one end 62 and the metal line extending from the spiral portion 61 to the other end 63 are substantially orthogonal to each other and form an L-shape. The spiral portion 61 is disposed at the corner of the L-shape. The other end 63 of the assist spring 60 is connected with the second spring support 46.
The one end 62 of the assist spring 60 is connected with a first spring support 81. The leading end of the assist spring 60 is inserted into a hole formed in the first spring support 81. This allows the first spring support 81 to hold the assist spring 60. A recess formed in the first spring support 81 allows the first spring support 81 to be mounted on the first spring base 80. The first spring base 80 is disposed below the first frame 30. The first spring base 80 is, for example, a sheet metal press work, a metal molded product, a resin molded product, or an integrally molded product of metal and resin. The first spring base 80 is welded or integrally molded on the first frame 30. The first spring support 81 is, for example, a metal molded product or a resin molded product. The first spring base 80 and the first spring support 81 are connected together by fitting.
In this manner, the one end 62 of the assist spring 60 is mounted on the first frame 30 through the first spring support 81. The other end 63 of the assist spring 60 is mounted on the second frame 40 through the second spring support 46. The leading end of the assist spring 60 is inserted into a hole formed in the second spring support 46. This allows the second spring support 46 to hold the assist spring 60. A recess formed in the second spring support 46 allows the second spring support 46 to be mounted on the second spring base 45.
In this manner, the first frame 30 and the second frame 40 are connected through the assist spring 60. This generates an urging force between the first frame 30 and the second frame 40. This assist spring 60 assists the sliding operation by the user. For example, an intermediate slide position between the closed state and the open state serves as a reference position. The slide is shifted from the reference position, thereby generating an urging force in one of the sliding directions. In the case of sliding from the intermediate position to the open state, an urging force is generated in the direction in which the slide is extended. On the other hand, in the case of sliding from the intermediate position to the closed state, an urging force is generated in the direction in which the slide retracts. In this manner, the assist spring 60 assists the sliding operation by the user.
The first spring base 80 is mounted on the first frame 30. The first spring base 80 is provided with a notch for holding the first spring support 81. The first spring base 80 is provided with a second stopper 82. The second stopper 82 contacts the link 50, thereby regulating the rotation of the link 50. This enables limitation of the tilt angle. The second stopper 82 contacts the link 50 in the vicinity of the open state. That is, since the first spring base 80 is mounted on the first frame 30, the second stopper 82 does not contact the link 50 in a state apart from the open state.
In the open state, for example, as shown in
Referring next to
Referring to
Referring to
The angle of the link 50 and the tilt angle in the action described above will be described. First, as shown in
In the high tilt angle state, the mobile phone 1 is in the state as shown in
In the low tilt angle state, the mobile phone 1 is in the state as shown in
Next, the action obtained by the sliding operation and tilting operation will be described with reference to
Further, the user presses the first casing 10 in the direction of the second casing 20 (direction indicated by the arrow shown in
As shown in
This results in stopping the rotation of the link 50 in the direction in which the link 50 rises. In other words, the second stopper 82 and the first stopper 47 prevent the tilt angle from increasing. The sliding due to the urging force of the assist spring 60 is also stopped. In this manner, the urging force from the assist spring 60 allows the link 50 to be pressed against each of the first stopper 47 and the second stopper 82. In this state, the urging force of the assist spring 60 with respect to the first frame 30 is generated in the direction indicated by the arrow shown in
In this manner, the first stopper 47 and the second stopper 82 regulate the rotation of the link. Thus, the tilt angle can be changed by a simple operation. Therefore, the operability can be improved. The slide position in the high tilt angle state and the slide position in the low tilt angle state are substantially the same. This enables an input operation using the input keys of the input unit 21 in any tilt state.
Note that the first stopper 47 is provided to the second frame 40. The first stopper 47 and the second frame 40 may be separately provided, as a matter of course. In this case, the first stopper 47 is provided to the second frame 40. Meanwhile, the second stopper 82 is provided to the first frame 30. That is, the second stopper 82 is mounted on the first frame 30 through the first spring base 80. That is, the second stopper 82 is fixed to the first frame 30. The second stopper 82 and the first frame 30 may be formed as an integral product, as a matter of course. This improves the operability with a simple configuration. Note that stoppers are preferably provided at both ends of the link 50. In this case, two stoppers, i.e., the first stopper 47 and the second stopper 82, are provided.
Further, the link 50 contacts the second stopper 82 with different angles in each of the high tilt angle state and the low tilt angle state. At this time, the position where the link 50 of the second stopper 82 contacts varies. Specifically, in the high tilt angle state, the link contacts on the front surface of the base portion 50a shown in
According to the configuration described above, the tilt angle can be changed simply. Specifically, the tile angle can be switched only by slightly pressing the surface of the first casing 10 on which the display unit 11 is disposed. Further, the tilt angle can be switched only by the operation in which the casing including the display unit is slightly drawn in the closing direction and is then released.
According to the configuration described above, the mobile phone 1 can be reduced in thickness. The first stopper 47 and the second stopper 82 are arranged in the movable area of the assist spring 60 which is provided so as not to interfere with the casing. Further, the first stopper 47 and the second stopper 82 can be formed of a part of the existing components. Specifically, the first stopper 47 is formed as a part of the second frame 40, and the second stopper 82 is formed as a part of the first spring base 80. Consequently, the mobile phone 1 can be reduced in thickness.
A sliding mechanism of a mobile phone according to this exemplary embodiment will be described with reference to
In this exemplary embodiment, the operation for changing the tilt angle and the action in association with the operation are different from those of the first exemplary embodiment. As shown in
In this exemplary embodiment, the operation for changing the tilt angle from the open state shown in
In the case of shifting from the high tilt angle state to the low tilt angle state, the user slightly draws in the first casing 10 and then slightly presses it into the second casing. This allows the mobile phone 1 to shift from the high tilt angle state shown in
Next, the operation in the case of shifting from the low tilt angle state to the high tilt angle state will be described with reference to
The action of the link 50 in the case of changing the tilt angle will be described with reference to
Specifically, as shown in
When the first casing is caused to slide in the retracting direction in the high tilt angle state, the link 50 is released from the third stopper 83 and the first stopper 47. This brings the link 50 into a rotatable and movable state. Sliding in the retracting direction changes the positions of the first pins 51, the second pins 42, and the third pins 43 with respect to the rails 70. Accordingly, the tilt angle changes and the link 50 rotates counterclockwise. In this case, after the link 50 rises vertically and a link angle θ4 becomes 90 degrees, the link angle θ4 becomes an acute angle. When the user stops applying a force, the link 50 adds a force in the extending direction to the second stopper 82 by the urging force of the assist spring 60. As a result, the state shown in
In this exemplary embodiment, the rotation of the link 50 is regulated by the third stopper 83 when the first casing 10 is pressed in the direction of the second casing 20 in the thickness direction. That is, the third stopper 83 regulates the rotation of the link 50 when the first frame 30 receives the force that presses the first frame 30 into the second frame 40 in the thickness direction. Accordingly, even if the first casing 10 is pressed accidentally, the tilt angle does not change. This leads to improvement in the operability. Further, formation of the second stopper 82 and the third stopper 83 as the same component enables reduction in the number of components.
According to the configuration described above, the tilt angle can be switched simply. That is, the operation in which the display surface of the first casing 10 on which the display unit 11 is disposed is slightly drawn in the retracting direction and is then pressed enables switching of the tilt angle. Further, the operation in which the first casing 10 including the display unit 11 is slightly drawn in the retracting direction and is then released enables shifting from the low tilt angle state to the high tilt angle state. The operation of drawing in the retracting direction is only necessary for shifting from the open state to the closed state. This leads to improvement in the operability.
Furthermore, according to the configuration described above, the mobile phone 1 can be reduced in thickness. The the first stopper 47, the second stopper 82, and the second stopper 83 are arranged in the movable area of the assist spring 60 which is provided so as not to interfere with the casing. Further, the first stopper 47, the second stopper 82, and the second stopper 83 can be formed of a part of the existing components. Specifically, the first stopper 47 is formed as a part of the second frame 40, and the second stopper 82 and the third stopper 83 are formed as a part of the first spring base 80. This contributes to a reduction in thickness of the mobile phone 1.
As shown in the first and second exemplary embodiments, the tile angle can be easily changed by the action of the link 50. That is, the tilt angle is changed by one-time operation, which improves the operability. Note that the first and second exemplary embodiments can be combined as needed. The sliding structure described above is not limited to the mobile phone 1, but can be used for other portable electronic devices, as a matter of course. The sliding structure can also be implemented in portable electronic devices such as a portable game device, a portable computer, a portable music player, a desktop computer, and various remote controllers for television/video/air conditioner or the like. In the slide-type mobile phone in which a certain tilt angle is formed between the first casing 10 including the display unit 11 and the second casing 20 including the input keys, the tilt angle can be easily switched.
Though the present invention has been described above with reference to exemplary embodiments, the present invention is not limited to the above exemplary embodiments. The configuration and details of the present invention can be modified in various manners which can be understood by those skilled in the art within the scope of the invention.
This application is based upon and claims the benefit of priority from Japanese patent application No. 2010-116124, filed on May 20, 2010, the disclosure of which is incorporated herein in its entirety by reference.
A technique according to the present invention can be applied to portable devices, for example.
Number | Date | Country | Kind |
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2010-116124 | May 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2011/002075 | 4/7/2011 | WO | 00 | 10/10/2012 |