JP2005240901A - Separate push-open hinge device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent leakage of lubricant of a push-open hinge device in which opening operation is easy, a casing is surely opened, and the casing is openable close to 180°, and to reduce a production cost. <P>SOLUTION: The separate push open hinge device of a foldable type portable electronic apparatus 40 is constituted of a set of the push open hinge part 20 housing a fixed cam, a movable cam, and an inner cam in a case and a torsion spring hinge part 30 housing a torque seal type torsion spring in a case. An operation end of the torsion spring is dropped in a groove part of a spring receiving part immediately before a display part casing 42, so as to prevent the torque is exerted on a hinge. In a fully closed state, the casing is locked only by the cams. When a button is pressed, a key is separated from the inner cam to release the lock. At a position where the display part casing 42 is slightly opened, the operation end of the torsion spring is returned from the groove part of the spring receiving part to a groove part of a holder to exert the torque on the holder and thereby to open the display part casing 42. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a separate push-open hinge device, and more particularly, to a separate push-open hinge device for a folding portable electronic device capable of opening a folded housing with a single operation by a button operation.

  In a foldable mobile phone, a display unit casing and an operation unit casing are connected to each other by a hinge mechanism so as to be freely opened and closed. During a call or the like, it can be opened with one touch by pressing the open button of the hinge mechanism, and both cases are folded by hand after use. When the display housing is folded against the torque in the opening direction of the torsion spring, the cam is engaged and the display housing and the operation housing are locked in a folded state. When the open button is pressed, the cam is disengaged, and the display housing is rotated and opened by the torque in the opening direction of the torsion spring. When the display housing is opened to a predetermined angle, the cam is engaged, and the display housing is locked in the opened state.

  In this push-open hinge device, the torque of the torsion spring cannot be overcome unless the engaging force of the cam in the closed state is increased. In order to reliably close the cam, it is necessary to sufficiently increase the engagement force of the cam. As a result, a strong force is required to disengage the cam, and the force to push the button is increased, so that the ease of button operation is sacrificed. If the button operation force may be weak, it cannot be closed securely. In order to solve this problem, the present inventor disclosed in Patent Document 1 that push-opening is performed such that the button operation force for opening the folding cellular phone is reduced and the opening operation is facilitated even if the opening operation is facilitated. A hinge device was proposed.

  In this hinge device, the fixed end of the torsion spring is fixed to the operation unit casing, and the working end is locked to the groove of the holder fixed to the display unit casing. The operating end of the torsion spring falls into the groove of the spring receiving portion at a position immediately before closing the display unit housing, and torque is not applied to the holder. In this state, the projection of the movable cam is engaged with the cam groove of the fixed cam, and the display unit housing is closed. When opening, the working end of the torsion spring returns from the groove portion of the spring receiving portion to the groove portion of the holder immediately before the movable cam is separated, and torque is applied to the holder, and the display unit housing is opened. Since no torque is applied to the movable cam in the closed state, the engagement force between the fixed cam and the movable cam may be weak, and the force to push the button for releasing becomes small.

  Furthermore, as an example of a conventional push-open hinge device that facilitates an open operation, there is an “electronic device hinge” disclosed in Patent Document 2. This is an electronic device hinge that can be automatically opened by pressing a push button to a usable angle and can be opened to a fully open position with one hand in a free stop. The first housing and the second housing are connected to each other so as to be openable and closable. The first casing and the second casing are automatically opened to a predetermined opening angle by a push-open type first hinge with a push button. A friction type second hinge that strongly generates a friction torque from a predetermined automatic opening angle is attached coaxially with the push open type first hinge. The locking means is provided on any one of the hinges.

In these push-open hinge devices, since the casing could not be opened to nearly 180 °, the present inventor in Japanese Patent Application Laid-Open No. H10-228707 has a button-shaped force by making the protrusion of the cam into a dogleg shape. We proposed a push-open hinge device that can open the housing to nearly 180 ° even if it is weak and easy to operate. In this push-open hinge device, a triple movable composite cam including an outer cam, an inner cam, and a release key is fixed to the display unit casing. A fixed cam that contacts the composite movable cam is fixed to the operation unit casing. The outer cam and the inner cam are engaged via a release key. When the casing is closed, the torque of the torsion spring is sealed, and the protrusion of the fixed cam gets over the protrusion of the inner cam and is locked in the fully closed state. When the button is pressed in the fully closed state of the housing, the plunger presses the release key to release the engagement between the outer cam and the inner cam. The projection tip of the fixed cam slides down the slope of the outer cam and reaches the concave portion of the outer cam, and the housing opens to nearly 180 °.
Japanese Patent Application No. 2003-187036 JP 2003-161312 A Japanese Patent Application No. 2003-426791

  However, the conventional push-open hinge device has a problem that it is difficult to prevent the leakage of the lubricant because the shaft is used as the rotation center shaft.

  In addition, in the conventional push-open hinge device as disclosed in Patent Documents 1 and 3, since all hinge function members are built in one hinge device, the total length of the hinge device is necessarily long. Become. Since it is necessary to provide a dummy hinge on the opposite side of the hinge mounting portion of the housing, the gap portion without the hinge in the hinge mounting portion of the housing becomes very short. Therefore, it has been difficult to ensure a sufficient width for passing a flexible cable that electrically connects the first housing and the second housing. In such a conventional hinge device, a plurality of narrow-width flexible cables must be stacked and there is a problem that the manufacturing cost increases.

  The present invention solves the above-mentioned conventional problems, prevents leakage of lubricant in the hinge device, and sufficiently secures a width for passing the flexible cable through the hinge mounting portion of the housing, thereby reducing the manufacturing cost. Objective.

  In order to solve the above problems, in the present invention, a separate push-open hinge device includes a push-open hinge portion in which a composite cam including a fixed cam, a movable cam, an inner cam, and a key shaft is housed in a first case, and a torsion The torque sealing type torsion spring hinge portion in which the spring, the spring receiving shaft, and the holder are housed in the second case is provided.

  According to the present invention, the configuration as described above makes it possible to easily and reliably close the opening operation, and to prevent the leakage of the lubricant in the push-open hinge device that can open the housing to nearly 180 °. Moreover, the total length of each hinge part can be reduced by dividing the push-open hinge part and the torsion spring hinge part into left and right parts, so that the total length of each hinge part can be reduced. For flexible cables connecting the first housing and the second housing Can be sufficiently secured at the center of the hinge mounting portion of the portable device. As a result, it is possible to arrange the flexible cables without overlapping them, and to prevent an increase in cost for the flexible cables.

  Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS.

  In an embodiment of the present invention, a push-open hinge portion in which a composite cam composed of a fixed cam, a movable cam, an inner cam, and a key shaft is accommodated in a first case is attached to one hinge attachment portion of a folding portable electronic device. For a folding portable electronic device, a torsion spring hinge portion in which a torque-sealed torsion spring, a spring receiving shaft and a holder are housed in a second case is attached to the other hinge mounting portion of the folding portable electronic device. This is a separate push-open hinge device.

  FIG. 1 is a perspective view of a separate push-open hinge device according to an embodiment of the present invention. In FIG. 1, a push-open hinge portion 20 is a hinge portion in which a composite cam composed of a fixed cam, a movable cam, an inner cam, and a key shaft is housed in a case. The torsion spring hinge portion 30 is a hinge portion in which a torque sealed torsion spring, a spring receiving shaft, and a holder are accommodated in a case. The foldable portable electronic device 40 is a portable electronic device such as a mobile phone. The operation unit casing 41 is a casing having a keyboard or the like. The display unit housing 42 is a housing with a display device.

  A configuration of the push-open hinge portion will be described. Fig.2 (a) is a front assembly perspective view of a push open hinge part. FIG. 2B is an exploded front perspective view of the push-open hinge portion. FIG. 2C is a front exploded perspective view of the composite cam of the push-open hinge portion. Fig.3 (a) is a back surface assembly perspective view of a push open hinge part. FIG. 3B is an exploded rear perspective view of the push-open hinge portion. FIG. 3C is an exploded perspective view of the back surface of the composite cam of the push-open hinge portion. 2 and 3, a button 1 is a push button for opening the casing. The flange 2 is a means for fixing the fixed cam to the first casing (operation unit casing). The case 3 is a means for fixing the push-open hinge part to the second housing (display unit housing). The case rotates in synchronization with the second housing.

  The fixed cam 4 is a cam fixed to the first housing via a flange. The protrusion of the fixed cam 4 has a dogleg shape. When the button 1 is pressed, the protrusion of the movable cam 7 comes into contact with the cam slope of the fixed cam 4 and rotates the second housing. Also has a fully open position retention function. The key shaft 5 is a shaft that moves in the axial direction, although the rotation angle is synchronized with the first housing. When the button 1 is pressed, it moves in the axial direction and freely rotates the inner cam 6. When the inner cam 6 is engaged with the key shaft 5, it engages with the fixed cam 4 and does not rotate. When the engagement with the key of the key shaft 5 is released by depressing the button 1, it becomes free and is pushed by the movable cam 7 to freely rotate. In the case of manual operation, the protrusion of the movable cam 7 is always in contact with the slope of the inner cam 6 and has a function of holding / free-stop or intermediate stop / open / close.

  The movable cam 7 is a cam that rotates in synchronization with the case 3 and also moves in the axial direction. The protrusion of the movable cam 7 has a dogleg shape. The first compression spring 8 and the second compression spring 9 are cam compression springs that urge the movable cam 7 to contact the fixed cam 4 or the inner cam 6. There may be one cam compression spring. The third compression spring 10 is a key compression spring that urges the key shaft 5 to synchronize the fixed cam 4 and the inner cam 6 and pushes back the button 1. The stopper 11 is a stopper that is fixed to the case 3 by a snap fit and serves as a lid. At the bottom of the stopper 11, there is a hook claw for attaching and fixing to the second housing by snap fitting.

  FIG. 4 is a cross-sectional view perpendicular to the axis of the push-open hinge portion. FIG. 4A is a diagram showing a state where the key of the key shaft 5 and the groove of the inner cam 6 are engaged. FIG. 4B is a diagram illustrating a state where the key of the key shaft 5 is detached from the groove of the inner cam 6.

  5 to 16 are explanatory views of the operation of the composite cam of the push-open hinge portion. The circumferential direction is developed in a straight line over 360 °. 5 to 8 are development views of a composite cam provided with a fully opened inner cam. FIG. 5A is a development view of the fully closed position of the composite cam including the fully opened inner cam. FIG. 5B is a development view when the button 1 is pressed in the fully closed position. FIG. 6A is a development view of a position in the middle of pressing and opening the button 1. FIG. 6B is a development view of the fully opened position. FIG. 7A is a development view of the button return state fully opened position. The inner cam 6 is rotated 180 °. FIG. 7B is a development view of the operation position in the middle of the manual closing direction. The inner cam 6 is rotated 180 °. FIG. 8 is also a development view of the fully closed position, and shows a state in which the inner cam 6 is rotated by 180 °, but is externally the same as FIG.

  9 to 12 are development views of the composite cam provided with the free stop type inner cam. FIG. 9A is a development view of the fully closed position of the composite cam provided with the free stop type inner cam. FIG. 9B is a development view when the button 1 is pressed in the fully closed position. FIG. 10 (a) is a development view of a position in the middle of pressing the button 1 in the same way. FIG. 10B is a development view of the fully open position. FIG. 11A is a development view of the button return state fully opened position. The inner cam 6 is rotated 180 °. FIG. 11 (b) is a development view showing a state in which it is also manually opened and stopped at the intermediate stop position. The inner cam 6 is rotated 180 °. FIG. 12A is a development view of the operation position in the middle of the manual closing direction. The inner cam 6 is rotated 180 °. FIG. 12 (b) is also a development view of the fully closed position, and shows a state in which the inner cam 6 is rotated by 180 °, but is externally the same as FIG. 9 (a).

  13 to 16 are development views of the composite cam provided with the intermediate stop type inner cam. FIG. 13A is a development view of the fully closed position of the composite cam provided with the intermediate stop type inner cam. FIG. 13B is a development view when the button 1 is pushed in the fully closed position. FIG. 14 (a) is a development view of a position in the middle of opening by pressing the button 1 in the same manner. FIG. 14B is a development view of the fully opened position. FIG. 15A is a development view of the button return state fully opened position. The inner cam 6 is rotated 180 °. FIG. 15 (b) is a development view showing a state in which it is also manually opened and stopped at the intermediate stop position. The inner cam 6 is rotated 180 °. FIG. 16A is a development view of the operation position in the middle of the manual closing direction. The inner cam 6 is rotated 180 °. FIG. 16 (b) is also a development view of the fully closed position, and shows a state in which the inner cam 6 is rotated by 180 °, but is externally the same as FIG. 13 (a).

  The configuration of the torsion spring hinge portion will be described with reference to FIGS. FIG. 17A is a front assembly perspective view of a torsion spring hinge portion. FIG. 17B is an exploded front perspective view of the torsion spring hinge portion. FIG. 18A is a rear assembly perspective view of the torsion spring hinge portion. FIG. 18B is a rear assembly perspective view of the torsion spring hinge portion. FIG. 19 is a diagram for explaining the movement of the movable end portion of the torsion spring. The torsion spring hinge portion includes a cap 12 fixed to the first casing, a spring receiving shaft 16 fixed to the cap 12 by a pin 13, a case 14 fixed to the second casing, and a second casing. A holder 15 to be fixed, a torsion spring 17 having a fixed end portion and a movable end portion, and a stopper 18 which is fixed to the case 14 by a snap fit with a hook claw at the bottom portion and serves as a lid. The spring receiving shaft 16 has a torque sealing groove and a spring fixing portion that fixes a fixed end portion of the torsion spring 17. The holder 15 has a groove portion that holds the movable end portion of the torsion spring 17.

  17 and 18, the cap 12 is a cap for fixing the first housing. While fixing the spring receiving shaft 16 and the first housing, it becomes an appearance design portion. The pin 13 is a pin that fixes the cap 12 and the spring receiving shaft 16. The case 14 is a case for fixing the second housing, and rotates in synchronization with the second housing. The holder 15 is a holder that holds the movable end of the torsion spring 17 and rotates in synchronization with the case 14. A torsion spring force is generated by the rotation of the second casing. Has a groove for torque sealing. The spring receiving shaft 16 is a spring receiving shaft that is fixed to the cap 12. The fixed end of the torsion spring 17 is fixed. There is a groove that acts as a torque sealing mechanism by engaging the movable end of the torsion spring 17 at about 20 ° immediately before full closure. The torsion spring 17 is a torsion spring that generates a torsional force. One end is fixed to the spring receiving shaft 16. The other end is engaged with the groove of the holder 15. The stopper 18 is a stopper that is fixed to the case 14 by a snap fit and serves as a lid. A hook claw that is attached to and fixed to the second housing by snap fitting is provided at the bottom.

  20 to 25 are sectional views in the axial direction of the separate push-open hinge device according to the embodiment of the present invention. FIG. 20 is an axial cross-sectional view showing a state when the hinge is attached. FIG. 21 is a sectional view in the axial direction showing the fully opened state. FIG. 22 is an axial sectional view showing a state at the time of free stop. FIG. 23 is an axial cross-sectional view showing a state at the cam apex and a fully closed state. FIG. 24 is an axial cross-sectional view showing a state in the middle of opening by a button push. FIG. 25 is an axial sectional view showing a state in which the button push is fully opened.

  The operation of the separate push-open hinge device in the embodiment of the present invention configured as described above will be described. First, an outline of a separate push-open hinge device will be described with reference to FIG. Push-open hinge 20 that houses a composite cam consisting of a fixed cam, movable cam, inner cam, and key shaft in a case, and a torsion spring hinge that houses a torque-sealed torsion spring, spring receiving shaft, and holder in the case Two sets 30 are attached to the hinge mounting portion of the foldable portable electronic device 40 as a set to form a separate push-open hinge device. The operating end of the torsion spring is dropped into the groove of the spring receiving portion at a position immediately before closing the display unit housing 42, so that no torque is applied to the hinge. In the fully closed state, it is locked only with the composite cam. When the button is pressed, the key is released from the inner cam and unlocked. At a position where the display housing 42 is slightly opened, the working end of the torsion spring is returned from the groove of the spring receiving portion to the groove of the holder, and torque is applied to the holder to open the display housing 42.

  The function of the push-open hinge portion will be described with reference to FIGS. One rotating member (a member that moves in synchronization with the operation unit housing) of the push-open hinge unit is fixed to the first housing (operation unit housing) via the flange 2. The other rotating member (a member that moves in synchronization with the display unit housing) of the push-open hinge unit is fixed to the second housing (display unit housing) via the case 3. The fixed cam 4 is fixed to the flange 2.

  The movable cam 7 rotates in synchronization with the case 3 and also moves in the axial direction. The movable cam 7 is always pressed against the inner cam 6 by the elastic force of the first compression spring 8 and the second compression spring 9. When the engagement of the inner cam 6 and the key of the key shaft 5 is released by pressing the button 1, the inner cam 6 becomes free, and the movable cam 7 pushes the inner cam 6 to freely rotate, and is pressed against the fixed cam 4 to be fully opened. The inner cam 6 is always pressed against the fixed cam 4 when engaged with the key shaft 5. When the inner cam 6 is engaged with the key shaft 5, it engages with the fixed cam 4 and does not rotate. When the engagement with the key of the key shaft 5 is released by pressing the button 1, it becomes free, and is pushed by the movable cam 7 to freely rotate. In the case of manual operation, it is always engaged with the fixed cam 4 and is in contact with the protrusion of the movable cam 7.

  In the fully open position (position where the opening angle of the display unit housing and the operation unit housing is close to 180 °), the protrusion of the movable cam 7 enters the recess of the base of the protrusion of the fixed cam 4. And the protrusion of the fixed cam 4 engage with each other most deeply. The protrusion of the movable cam 7 is shaped like a letter and can be rotated over 180 °, so the housing can be moved to nearly 180 ° even if there is a margin for maintaining the state in the fully open state and the fully closed state. Can be opened. In the fully open state, the protrusion of the movable cam 7 is in a state of pressing the slope of the end of the cam slope of the fixed cam 4. Since the display unit case is open to the limit when it hits the operation unit case, the resistance force from the operation unit case and the force from the cam slope are balanced, and the display unit case remains stable and fully open. .

  When a force is applied by hand in the direction in which the display unit housing and the operation unit housing are closed, the force by which the projection of the movable cam 7 pushes the cam slope of the fixed cam 4 increases, and the first compression spring 8 and the second compression spring Overcoming the elastic force of the spring 9, the protrusion of the movable cam 7 climbs the slope of the inner cam 6 engaged with the fixed cam 4. The display housing is closed while compressing the first compression spring 8 and the second compression spring 9.

  When the projecting portion of the movable cam 7 exceeds the projecting portion of the inner cam 6, the elastic force of the first compression spring 8 and the second compression spring 9 receives the force in the closing direction from the cam slope, and the display housing is fully closed. Closed to state. Also at this time, the protrusion of the movable cam 7 is stopped while pressing the cam slope of the inner cam 6. Since the display unit case is closed to the limit when it hits the operation unit case, the resistance force of the operation unit case and the resistance force of the cam slope are balanced, and the fully closed state is stably maintained without any play. Yes. The closed state can be stably maintained by the pulling force in the closing direction when the first compression spring 8, the second compression spring 9, and the fixed cam 4 are fully closed.

  In the fully closed state of the housing, the fixed cam 4 and the inner cam 6 are engaged, and the protrusion of the movable cam 7 stops at a position beyond the top of the inner cam 6. The first compression spring 8 and the second compression spring 9 urge the movable cam 7 to contact the inner cam 6 and apply a closing force to the housing. The button 1 and the key shaft 5 are urged by the third compression spring 10 and are pushed to the outside of the casing in the axial direction. When the button 1 is pressed, the key shaft 5 is pressed and moves inward of the housing along the axial direction, and the engagement between the inner cam 6 and the fixed cam 4 is released. The cam inclined surface of the fixed cam 4 comes into contact with the protrusion of the movable cam 7 and rotates the second housing.

  When the button 1 is pressed when the display unit housing and the operation unit housing are fully closed, the key shaft 5 is pressed, the key is detached from the inner cam 6, and the engagement between the inner cam 6 and the fixed cam 4 is released. The Since the elastic force of the first compression spring 8 and the second compression spring 9 is not applied to the key, the force for pressing the button 1 may be weak and the operability is good. Since the inner cam 6 rotates freely, the protrusion of the movable cam 7 comes into contact with the cam slope of the fixed cam 4. The movable cam 7 is pushed by the first compression spring 8 and the second compression spring 9 and rotates. The display unit casing is opened by a rotational moment in the opening direction.

  When the display housing is opened to approximately 165 °, the display housing is fully opened. With the protrusion of the movable cam 7 applied to the end of the cam slope of the fixed cam 4, the opening force is received by the elastic force of the first compression spring 8 and the second compression spring 9. The inner cam 6 is rotated by 180 °, and the key groove coincides with the fixed cam 4. The key of the key shaft 5 is fitted in the key groove, and the inner cam 6 and the fixed cam 4 are engaged.

  The function of the key shaft 5 will be described with reference to FIG. In the synchronized state, the position of the key groove of the fixed cam 4 and the position of the key groove of the inner cam 6 coincides, the key fits into the key groove of the inner cam 6, and the inner cam 6 engages with the fixed cam 4 and does not rotate. It has become. The key is always fitted in the key groove of the fixed cam 4, and the key and the fixed cam do not rotate. When the button 1 is pressed in the fully closed state of the housing, the key shaft 5 is pressed, slides inward in the axial direction, and the key is removed from the key groove of the inner cam 6. The inner cam 6 is in a freely rotating state, is pushed by the protrusion of the movable cam 7 and moves out of engagement with the fixed cam 4.

  In the fully closed state, the key shaft 5 is engaged with the inner cam 6 and the fixed cam 4 so that they are integrated. At this time, the protruding portion of the movable cam 7 exceeds the protruding portion of the inner cam 6. Since the movable cam 7 is pushed by the first compression spring 8 and the second compression spring 9, a force acts in the direction of closing the casing. Since the casing does not close any more, it is stable in the closed state. When the button 1 is pressed in the fully opened state of the housing, the inner cam 6 is disengaged and does not lock even in the fully closed state. Since it is locked when it is fully opened again and then closed, there is no particular inconvenience in use.

  The operation of the composite cam will be described with reference to FIGS. The state of the cam in the fully closed position will be described with reference to FIG. Since the key engages the inner cam 6 and the fixed cam 4, both are integrated. The protruding portion of the movable cam 7 exceeds the protruding portion of the inner cam 6. Since the inner cam 6 is pushed by the first compression spring 8 and the second compression spring 9, a force acts in the direction of closing the casing. Since the casing does not close any more, it is stable in the closed state.

  The inner cam 6 is stopped by the key portion of the key shaft 5. The fixed cam 4 is prevented from rotating by the flange 2 fixed to the first housing. The movable cam 7 is rotationally stopped by a case fixed to the second housing and can move only in the hinge axis direction. By the operation of closing the housing, the protrusion of the movable cam 7 is in contact with the cam slope of the inner cam 6 and slides. In the fully closed position, there is a clearance between the movable cam 7 and the fixed cam 4, and a force is applied in the direction of further closing.

  The state of the cam when the button 1 is pushed in the fully closed position will be described with reference to FIG. The key shaft is pushed by the button 1, and the key is separated from the inner cam 6. The inner cam 6 rotates freely and is pushed by the protrusion of the movable cam 7 to rotate. The protruding portion of the movable cam 7 comes into contact with the cam inclined surface of the fixed cam 4. By pressing the button 1, the key shaft 5 is pushed down in the housing inner direction along the hinge axis direction. Then, the key portion of the key shaft 5 that has stopped the rotation of the inner cam 6 is detached from the key groove of the inner cam 6. The inner cam 6 engaged with the fixed cam 4 is released from rotation suppression. The bottom of the movable cam 7 is urged by a compression spring. Therefore, the protrusion of the movable cam 7 is pushed to the cam slope of the fixed cam 4. The inner cam 6 is rotated around the hinge axis by the tip of the movable cam 7.

  The state of the cam when it is half-opened from the fully closed position will be described with reference to FIG. The protrusion of the movable cam 7 moves in the direction of opening the casing while sliding on the cam slope of the fixed cam 4. Since the fixed cam 4 is pressed by the first compression spring 8 and the second compression spring 9, a force is applied in the direction of opening the housing. The inner cam 6 is pushed by the protrusion of the movable cam 7 and rotates. When the fully closed state is released by pressing the button 1, the tip of the protrusion of the movable cam 7 slides down while contacting the steeply inclined cam slope of the fixed cam 4. The second housing can be moved in the opening direction by adjusting the angle of the steeply inclined cam slope and the load of the compression spring so as to generate an opening moment more than the closing moment by the second housing. .

  In addition, when the torsion seal on the torsion hinge side is released in the state where it is within the range of the steeply inclined cam slope, the torsional force of the torsion spring on the torsion hinge side causes the torsion spring to fully open. Can be opened. By dividing the function of the opening operation into two hinges, the cam height on the push open hinge side can be kept low, and the total length on the push open hinge side can be set short.

  The state of the composite cam when the fully opened position is reached will be described with reference to FIG. The protrusion of the movable cam 7 stops at the end of the cam slope of the fixed cam 4. Since the housing is fully open at about 165 °, the cam force and the resistance force of the housing are stable and fully open. The inner cam 6 is rotated 180 ° so that the keyway coincides with the fixed cam 4. When the button 1 is returned, as shown in FIG. 7A, the key enters the keyway and engages both.

  Since the fully opened angle between the first housing and the second housing is 180 ° or less, the inner cam 6 cannot rotate up to 180 ° in the fully opened position. Therefore, the key portion tip of the key shaft 5 and the key groove entrance portion of the inner cam 6 are chamfered. Since the bottom portion of the key shaft 5 is urged toward the button 1 by the third compression spring, when the hand is released from the button 1, the chamfered portion at the key groove entrance of the inner cam 6 becomes the tip of the key portion of the key shaft 5. The inner cam 6 is further rotated by the chamfered portion. The key portion of the key shaft 5 is fitted into the key groove of the inner cam 6. The inner cam 6 is fixed to the fixed cam 4 by turning 180 ° from the initial position.

  The state of the cam when manually closing from the fully open state will be described with reference to FIG. When the housing is closed by hand from the fully open position, the protrusion of the movable cam 7 climbs the cam slope of the inner cam 6 with the inner cam 6 and the fixed cam 4 engaged. When the protruding portion of the movable cam 7 exceeds the protruding portion of the inner cam 6, a force is applied in the direction of closing the casing, so that the movable cam 7 is stably closed and the state shown in FIG. 8 is obtained. The inner cam 6 rotates to follow the movable cam 7 when opened by pressing a button, and is engaged with the fixed cam 4 and stopped when the inner cam 6 is closed. Therefore, it rotates in the same direction by 180 ° for every opening and closing.

  The key shaft 5 and the inner cam 6 are fixed by the key portion by releasing the button 1 after the button 1 is fully opened by pressing the button 1 and then released. By manually closing the second housing, the cam tip of the movable cam 7 slides in contact with the cam slope of the inner cam 6. At this time, the inner cam 6 is in a state reversed 180 ° from the initial position. When the closing operation is continued, the fully closed state is finally obtained. Again, the tip of the protrusion of the movable cam 7 gets over the top of the protrusion of the inner cam 6 and is positioned on the opposite cam slope. Due to the physically closed state of the first housing and the second housing, the first housing and the second housing are stopped in the middle of the slope of the cam, and the closed state is stably maintained.

  9 to 12 are views showing the operation of the composite cam provided with the free stop type inner cam. The state of the free-stop cam shown in FIGS. 9 to 11 (a) is the same as that shown in FIGS. 5 to 7 (a). A state in which the free stop type is manually opened and stopped at the intermediate position will be described with reference to FIG. When the housing is manually opened from the fully closed position, the protrusion of the movable cam 7 climbs the cam slope of the inner cam 6 with the inner cam 6 and the fixed cam 4 engaged. Since the cam slope of the inner cam 6 has a loose slope in the middle, the protrusion of the movable cam 7 receives a weak force in the closing direction on the slope, and the housing stops in a free stop state at an intermediate position. To do. The housing can be freely stopped at an arbitrary position within the range of the slope. Furthermore, when the housing is manually opened, it stops stably at the fully opened position. The state of the cam when manually closing the free stop type shown in FIG. 12 (a) is the same as that shown in FIG. 7 (b). The state of the cam when the free stop type shown in FIG. 12B is again in the fully closed position is the same as that shown in FIG.

  The fixed cam 4, the inner cam 6, and the key shaft 5 are prevented from rotating by the key portion of the key shaft 5. The fixed cam 4 is stopped by the flange 2 and fixed to the first housing. The movable cam 7, which is prevented from rotating by the case 3 fixed to the second casing and can move only in the hinge axis direction, slides in contact with the cam slope of the inner cam 6 by the operation of closing the second casing. To do. In the fully closed position, the movable cam 7 and the fixed cam 4 are stopped with a clearance, and a force acts in the closing direction.

  When the key shaft 5 is pushed down in the hinge axis direction by pressing the button 1, the key portion of the key shaft 5 that has stopped the rotation of the inner cam 6 is detached from the key groove of the inner cam 6. The rotation suppression of the inner cam 6 fixed to the fixed cam 4 is released. The movable cam 7 is urged by a compression spring and pushed to the cam slope of the fixed cam 4. The inner cam 6 is rotated around the hinge shaft by the tip of the protrusion of the movable cam 7.

  When the fully closed state is released by pressing the button 1, the tip of the protrusion of the movable cam 7 slides down if it contacts the steeply inclined cam slope of the fixed cam 4. Adjusting the angle of the steeply inclined cam slope and the load of the compression spring, and setting the second housing to move in the release direction by setting it to generate a moment in the opening direction that is greater than the moment in the closing direction by the second housing Can be made. In addition, when the torsion seal on the torsion hinge side is released in the state where it is within the range of the steeply inclined cam slope, the torsional force of the torsion spring on the torsion hinge side causes the torsion spring to fully open. Release action. By dividing the function of the release operation into two hinges, the cam height on the push open hinge side can be kept low, and the total length on the push open hinge side can be set short.

  Since the fully opened angle between the first housing and the second housing is 180 ° or less, the inner cam 6 cannot rotate up to 180 ° in the fully opened position. Therefore, the key portion tip of the key shaft 5 and the key groove entrance portion of the inner cam 6 are chamfered. Since the key shaft 5 is biased to the button 1 side by the compression spring, when the hand is released from the button 1, the chamfered portion at the key groove entrance of the inner cam 6 becomes the chamfered portion at the tip of the key portion of the key shaft 5. The inner cam 6 rotates further when invited. The key portion of the key shaft 5 is fitted into the key groove of the inner cam 6. The inner cam 6 is fixed to the fixed cam 4 by turning 180 ° from the initial position.

  The key shaft 5 and the inner cam 6 are fixed by the key portion by releasing the button 1 after the button 1 is fully opened by pressing the button 1 and then released. By manually closing the second housing, the tip of the protrusion of the movable cam 7 slides while contacting the cam slope of the inner cam 6. At this time, the inner cam 6 is in a state reversed 180 ° from the initial position.

  The movable cam 7 slides while coming into contact with the cam slope of the inner cam 6. When the opening angle of the first housing and the second housing is in the range of about 90 ° to about 140 °, a moment in the closing direction slightly larger than the moment in the opening direction by the second housing is generated. Set the tilt angle. Within this range, a free stop can be made. When the manual operation is further performed in the closing direction beyond the free stop range, the tip of the protrusion of the movable cam 7 climbs the cam slope of the inner cam 6. At this time, the second housing is moved in the closing direction against the force in the opening direction by the biasing force of the compression spring. If the closing operation is further continued, the fully closed state is finally obtained, and the tip of the protruding portion of the movable cam 7 gets over the top of the protruding portion of the inner cam 6 again and is positioned on the cam slope on the opposite side. Due to the physically closed state of the first housing and the second housing, the first housing and the second housing are stopped in the middle of the slope of the cam, and the closed state is stably maintained.

  FIGS. 13 to 16 are views showing the operation of the composite cam provided with the intermediate stop type inner cam. A recess is provided on the cam slope of the inner cam 6 where the opening angle of the first housing and the second housing is about 125 °. The tip of the protruding portion of the movable cam 7 is fitted into this recess to obtain an intermediate stop position. The state of the cam shown in FIGS. 13 to 15 (a) is the same as that shown in FIGS. 5 to 7 (a). A state in which the intermediate stop mold is manually opened and stopped at the intermediate position will be described with reference to FIG. When the housing is manually opened from the fully closed position, the protrusion of the movable cam 7 climbs the cam slope of the inner cam 6 with the inner cam 6 and the fixed cam 4 engaged. Since a recess is provided in the cam slope of the inner cam 6, the protrusion of the movable cam 7 fits into the recess, and the housing is stably stopped at the intermediate position. Furthermore, when the housing is manually opened, it stops stably at the fully opened position. The state of the cam when manually closing the intermediate stop mold shown in FIG. 16 (a) is the same as that shown in FIG. 7 (b). The state of the cam when the intermediate stop type shown in FIG. 12B is again in the fully closed position is the same as that shown in FIG.

  The inner cam 6 is locked to the fixed cam 4 by the key portion of the key shaft 5. The fixed cam 4 is stopped by the flange 2 and fixed to the first housing. The movable cam 7, which is fixed to the case 3 fixed to the second housing and is movable only in the hinge axis direction, slides in contact with the cam slope of the inner cam 6 by the operation of closing the second housing. To do. In the fully closed position, the movable cam 7 and the fixed cam 4 are stopped with a clearance, and a force acts in the closing direction.

  When the key shaft 5 is pushed down in the hinge axis direction by pressing the button 1, the key portion of the key shaft 5 that has stopped the rotation of the inner cam 6 is detached from the key groove of the inner cam 6. The rotation suppression of the inner cam 6 fixed to the fixed cam 4 is released. The movable cam 7 is urged by a compression spring and pushed to the cam slope of the fixed cam 4. The inner cam 6 is rotated around the hinge shaft by the tip of the protrusion of the movable cam 7.

  When the fully closed state is released by pressing the button 1, the tip of the protruding portion of the movable cam 7 slides down while contacting the steeply inclined cam slope of the fixed cam 4. By adjusting the angle of the steeply inclined cam slope and the force of the compression spring to set the moment in the opening direction to be greater than the moment in the closing direction by the second housing, the second housing is moved in the release direction. Let In addition, when the torsion seal on the torsion hinge side is released in the state where it is within the range of the steeply inclined cam slope, the torsional force of the torsion spring on the torsion hinge side causes the torsion spring to fully open. Release action. By dividing the function of the release operation into two hinges, the cam height on the push open hinge side can be kept low, and the total length on the push open hinge side can be set short.

  Since the fully opened angle between the first housing and the second housing is 180 ° or less, the inner cam 6 cannot rotate up to 180 ° in the fully opened position. Therefore, the key portion tip of the key shaft 5 and the key groove entrance portion of the inner cam 6 are chamfered. Since the key shaft 5 is biased to the button 1 side by the compression spring, when the hand is released from the button 1, the chamfered portion at the key groove entrance of the inner cam 6 becomes the chamfered portion at the tip of the key portion of the key shaft 5. The inner cam 6 rotates further when invited. The key portion of the key shaft 5 is fitted into the key groove of the inner cam 6. The inner cam 6 is fixed to the fixed cam 4 by turning 180 ° from the initial position.

  The key shaft 5 and the inner cam 6 are fixed by the key portion by releasing the button 1 after the button 1 is fully opened by pressing the button 1 and then released. By manually closing the second housing, the tip of the protrusion of the movable cam 7 slides while contacting the cam slope of the inner cam 6. At this time, the inner cam 6 is in a state reversed 180 ° from the initial position. The movable cam 7 slides while coming into contact with the cam slope of the inner cam 6.

  In the case of release by pressing the button 1 from the fully closed position, the tip of the protrusion of the movable cam 7 slides while abutting against the cam slope of the fixed cam 4, so that the operation is opened without fully stopping. In the case of a manual opening / closing operation, the tip of the protrusion of the movable cam 7 slides while coming into contact with the cam slope of the inner cam 6, so it always stops temporarily.

  When the manual operation is further performed in the closing direction beyond the intermediate stop position, the tip of the protrusion of the movable cam 7 climbs the cam slope of the inner cam 6. At this time, the second housing is moved in the closing direction against the force in the opening direction by the biasing force of the compression spring. When the closing operation is continued, the fully closed state is finally obtained. The tip of the protruding portion of the movable cam 7 again gets over the top of the protruding portion of the inner cam 6 and is positioned on the cam slope on the opposite side. Due to the physically closed state of the first housing and the second housing, the first housing and the second housing are stopped in the middle of the slope of the cam, and the closed state is stably maintained.

  The operation of the torsion spring hinge portion will be described with reference to FIGS. In a state from the fully opened state of the first housing and the second housing to just before the fully closed state, the movable end portion of the torsion spring engages with the groove portion of the holder. In the fully closed state from the state immediately before the first housing and the second housing are fully closed, the movable end portion of the torsion spring engages with the sealing groove portion of the spring receiving shaft. When the opening angle of the display unit housing and the operation unit housing is closed to about 20 ° from the fully opened state, the movable end of the torsion spring 17 comes out of the groove of the holder 15 and falls into the groove of the spring receiving shaft 16. The holder 15 does not receive the torque of the torsion spring 17. Accordingly, the rotation moment in the opening direction due to the torsion spring 17 is eliminated from the display unit casing.

  When the opening angle of the display unit housing and the operation unit housing is opened from the fully closed state to approximately 20 °, the movable end of the torsion spring 17 comes out of the groove of the spring receiving shaft 16 and enters the groove of the holder 15. Since it falls, the holder 15 receives the torque of the torsion spring 17 again. Therefore, the display unit casing is opened by a rotational moment in the opening direction by the torsion spring 17.

  The torque sealing operation of the torsion spring 17 will be described with reference to FIG. When the opening angle between the display unit casing and the operation unit casing is larger than 20 °, the movable end of the torsion spring 17 is placed in the groove of the holder 15. When the holder 15 rotates and is closed until the opening angle of the display unit casing and the operation unit casing reaches 20 °, the movable end portion comes in between the groove portion and the groove portion. When the opening angle between the display unit housing and the operation unit housing is smaller than 20 °, the movable end portion falls into the groove portion of the spring receiving shaft 16. In this state, since the torque of the torsion spring 17 is received by the spring receiving shaft 16, no torque is applied to the holder 15. When the display housing and the operation housing are opened from the fully closed state, the torque of the torsion spring 17 is applied to the holder 15 when the opening angle of the display housing and the operation housing is larger than 20 °. Thus, the display unit casing and the operation unit casing are automatically opened.

  The operation of the separate push-open hinge device will be described with reference to FIGS. However, in FIGS. 21 to 25, the illustration of the torsion spring is omitted. As shown in FIG. 20, the case is opened to about 173 ° exceeding the fully open state, and the push-open hinge portion 20 and the torsion spring hinge portion 30 are used as hinge mounting portions of the folding portable electronic device. insert. As shown in FIG. 21, when the housing is fully opened, it opens to about 165 °. In this state, the composite cam is engaged most deeply. As shown in FIG. 22, in the case of a hinge device provided with a free stop type inner cam, a free stop state is established when the housing is manually opened at about 120 °. The protrusion of the movable cam 7 receives a weak force in the closing direction on the loose slope of the inner cam 6, and the housing enters a free stop state at an intermediate position and stops.

  As shown in FIG. 23 (a), when the casing is closed to about 18.5 °, the torque of the torsion spring is sealed, and the moment in the opening direction is only due to the cam. There is no torque at the top of the cam. As shown in FIG. 23B, in the fully closed state of the casing, the cam torque is in the closing direction, and the closed state is stably maintained. As shown in FIG. 23C, when the button 1 is pressed in the fully closed state of the casing, the engagement of the inner cam 6 is released and the lock is released. As shown in FIG. 24, when the lock is released, the torque in the opening direction works, and the housing opens to about 20 °. In that state, the sealing of the torsion spring is released, and the torque in the opening direction by the torsion spring acts. Thereafter, the housing is opened with a strong force. As shown in FIG. 25, the housing is automatically fully opened to about 165 °.

  As described above, in the embodiment of the present invention, the separate push-open hinge device is folded by the push-open hinge portion in which the composite cam composed of the fixed cam, the movable cam, the inner cam, and the key shaft is accommodated in the first case. The torsion spring hinge portion, which is attached to one hinge mounting portion of the portable electronic device and accommodates the torque-sealed torsion spring, the spring receiving shaft, and the holder in the second case, is connected to the other hinge of the folding portable electronic device. Since it is configured to be attached to the attachment portion, the opening operation is easy and can be reliably closed, and leakage of the lubricant can be prevented even if the housing can be opened to nearly 180 °. In addition, it is possible to secure a sufficient width for passing the flexible cable through the hinge mounting portion of the housing, and to reduce the manufacturing cost for the flexible cable.

  The separate push-open hinge device of the present invention is most suitable as a push-open hinge device for a mobile phone. Moreover, it is also suitable as a push-open hinge device for portable electronic devices.

The perspective view of the separate push open hinge device in the example of the present invention, The front assembly perspective view and front exploded perspective view of the push open hinge part in the embodiment of the present invention, The rear assembly perspective view and the rear exploded perspective view of the push open hinge portion in the embodiment of the present invention, Sectional drawing perpendicular | vertical to the axis | shaft of the push open hinge part in the Example of this invention, FIG. 3 is a development view of a fully closed position of a composite cam including a fully opened inner cam of a push open hinge portion in an embodiment of the present invention; FIG. 3 is a development view when a button of a composite cam having a fully-open type inner cam of a push-open hinge portion in the embodiment of the present invention is pressed and opened; The expanded view in the middle of the manual closing of the composite cam provided with the fully open type inner cam of the push open hinge part in the embodiment of the present invention, FIG. 3 is a development view of a fully closed position of a composite cam including a fully opened inner cam of a push open hinge portion in an embodiment of the present invention; The developed view of the fully closed position of the composite cam provided with the free stop type inner cam of the push open hinge part in the embodiment of the present invention, The developed view when the button of the composite cam provided with the free stop type inner cam of the push open hinge part in the embodiment of the present invention is pressed, FIG. 3 is a development view in the middle of manual closing of a composite cam having a free-stop type inner cam of a push-open hinge portion in an embodiment of the present invention; The developed view of the fully closed position of the composite cam provided with the free stop type inner cam of the push open hinge part in the embodiment of the present invention, The development view of the fully closed position of the composite cam provided with the intermediate stop type inner cam of the push open hinge part in the embodiment of the present invention, FIG. 4 is a development view when a button of a composite cam having an intermediate stop type inner cam of a push open hinge portion in an embodiment of the present invention is pressed; FIG. 3 is a development view in the middle of manual closing of a composite cam having an intermediate stop type inner cam of a push-open hinge portion in an embodiment of the present invention; The development view of the fully closed position of the composite cam provided with the intermediate stop type inner cam of the push open hinge part in the embodiment of the present invention, Front assembly perspective view and front exploded perspective view of a torsion spring hinge part in an embodiment of the present invention, The rear assembly perspective view and the rear exploded perspective view of the torsion spring hinge part in the embodiment of the present invention, The figure explaining the movement of the movable end part of the torsion spring of the torsion spring hinge part in the embodiment of the present invention, The axial direction sectional view showing the state at the time of hinge attachment of the separate push open hinge device in the embodiment of the present invention, The axial direction sectional view showing the state at the time of full opening of the separate push open hinge device in the embodiment of the present invention, An axial direction sectional view showing a state at the time of free stop of a separate push open hinge device in an embodiment of the present invention, The axial direction sectional view showing the state at the time of the cam top and the fully closed state of the separate push open hinge device in the embodiment of the present invention, An axial direction sectional view showing a state in the middle of opening by a button push of a separate push open hinge device in an embodiment of the present invention, It is an axial direction sectional view showing the state at the time of full release by button push of the separate push open hinge device in the example of the present invention.

Explanation of symbols

1 Button 2 Flange 3 Case 4 Fixed cam 5 Key shaft 6 Inner cam 7 Movable cam 8 First compression spring 9 Second compression spring
10 Third compression spring
11 Stopper
12 cap
13 pin
14 cases
15 Holder
16 Spring bearing shaft
17 Torsion spring
18 Stopper
20 Push-open hinge
30 Torsion spring hinge
40 foldable portable electronic devices
41 Control unit housing
42 Display housing

Claims (7)

A torque-sealed type of a push-open hinge portion in which a composite cam composed of a fixed cam, a movable cam, an inner cam and a key shaft is housed in a first case, and a torsion spring, a spring receiving shaft and a holder in a second case. A separate push-open hinge device for a foldable portable electronic device, comprising a torsion spring hinge portion. The push-open hinge portion includes a flange fixed to the first housing, a fixed cam fixed to the flange, a first case fixed to the second housing, and movement in the rotational direction by the first case. A movable cam that is controlled in an axial direction, a cam compression spring that urges the movable cam in an axial direction along the axial direction, an inner cam sandwiched between the movable cam and the fixed cam, A key shaft having a key for engaging the fixed cam and the inner cam, a key compression spring for urging the key shaft in the axial direction along the axial direction, and the key shaft along the axial direction A button for pushing inwardly of the housing, and a stopper fixed to the first case and holding the compression spring for the cam and the compression spring for the key. Separate push open hinge device for folding-type portable electronic device according. The torsion spring hinge portion includes a cap fixed to the first casing, a spring receiving shaft fixed to the cap by a pin, a second case fixed to the second casing, and the second casing. A holder to be fixed; a torsion spring having a fixed end and a movable end; and a stopper that is fixed to the second case by a snap fit with a hook claw at the bottom, and serves as a lid. A sealing groove portion and a spring fixing portion for fixing a fixed end portion of the torsion spring; and the holder includes a groove portion for holding a movable end portion of the torsion spring; In a state from the fully opened state of the second housing to immediately before the fully closed state, the movable end portion of the torsion spring engages with the groove portion of the holder, and immediately before the first housing and the second housing are fully closed. State to fully closed state Oite is movable end of the torsion spring separate push open hinge device for folding-type portable electronic device of claim 1, wherein the engaging the groove for sealing the spring receiving shaft. The inclined cam surface of the inner cam is formed so that when the first casing and the second casing are manually opened, the inner casing is fully opened without stopping in the middle. Separate push open hinge device. The separate push-open hinge according to claim 2, wherein an inclined cam surface of the inner cam is formed so as to stop in the middle when the first casing and the second casing are manually opened. apparatus. The inclined cam surface of the inner cam is formed so that the first housing and the second housing are manually stopped at a predetermined intermediate range when the first housing and the second housing are manually opened. Separate push open hinge device. 3. The separate push-open hinge device according to claim 2, wherein the cam compression spring comprises two compression springs.

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