JP2009063039A - Tilt hinge device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a tilt hinge device capable of easily performing smooth tilting without leaving a large clearance between members. <P>SOLUTION: This tilt hinge device includes: a first torque hinge part 36 attached to the first member 31; a second torque hinge part 38 attached to the second member 34; a coupling part 40 for coupling the first torque hinge part 36 to the second torque hinge part 38; and a link arm 82 having one end part 82a rotatably attached to the non-turning part of the first torque hinge part 36 or the first member 31 and the other end rotatably attached to the non-turning part of the second torque hinge part 38 or the second member 34 in order to restrict the turning movement of the coupling part 40 in the second torque hinge part 38 by a positional relation with the first member 31. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a tilt hinge device that connects a first member and a second member so as to be relatively rotatable.

Personal terminal devices in the information field such as notebook personal computers and PDA (Personal Digital Assistants), which are portable information terminals, have an apparatus main body (hereinafter sometimes simply referred to as the main body) in which a keyboard, a numeric keypad, etc. are arranged, and a liquid crystal display. In many cases, a display device or the like (hereinafter sometimes simply referred to as a display unit) is connected by a tilt hinge device.
The tilt hinge device has a structure that can be stably stopped at a predetermined angle when the display unit is opened with respect to the main body.

Hereinafter, a conventional tilt hinge apparatus will be described with reference to FIG.
The tilt hinge device 10 is used in a notebook personal computer 9, and a main body 11 having a keyboard 8 and a display unit 12 provided separately from the main body 11 are constituted by two connecting members 14 and 14. It is attached.
One end 14 a of each connection member 14 is rotatably attached to the side surface of the main body 11 by a rotation shaft 16, and the other end 14 b of each connection member 14 is rotated by a rotation shaft 17 on the side surface of the display unit 12. It is attached movably (see, for example, Patent Document 1).

In addition, not only notebook personal computers but also mobile phones have a tilt hinge device (see, for example, Patent Document 2).
In the mobile phone described in Patent Document 2, a main body provided with an operation unit and a display unit are formed separately, and the main body and the display unit are connected by two connecting rods.

JP 2004-199219 A JP 2005-228069 A

  In the structure disclosed in Patent Document 1 and Patent Document 2 as described above, the main body and the display unit are coupled by a connection member, and the connection member is a main body and a display unit, respectively, and the rotation shaft and the display unit on the main body side. It is fixed so as to be rotatable by two rotation shafts of the side rotation shaft.

In the case of such a structure, the user tilts the display unit with respect to the main body by hand, and rotates the display unit to an angle that is most easy to see.
At this time, as shown in FIG. 10, if only the rotation shaft 16 on the main body 11 side rotates, a large gap is formed between the end portion 12 a on the main body 11 side of the display unit 12 and the surface of the main body 11. h occurs, and the wiring on the back side is visible and unsightly.
As shown in FIG. 11, when only the rotation shaft 17 on the display unit 12 side rotates, the end portion 12 a on the main body 11 side of the display unit 12 comes into contact with the surface of the main body 11, and smooth. In some cases, the camera cannot tilt.

Thus, when the display unit 12 is to be tilted, in the conventional tilt hinge device 10, both the rotation shaft 16 on the main body 11 side and the rotation shaft 17 on the display unit 12 side are turned at the same rotation angle. It was necessary to tilt while adjusting well.
However, such adjustments must rely on the skill and familiarity of the user during tilting.
For this reason, when tilting the display unit 12, there is a demand for a tilt hinge device that can be easily tilted by anyone.

  Accordingly, the present invention has been made to solve the above-described problems, and an object of the present invention is to provide a tilt hinge device that can easily perform a smooth tilt operation without greatly opening a gap between members.

According to the tilt hinge device of the present invention, in the tilt hinge device that connects the first member and the second member so as to be relatively rotatable, the first torque hinge portion attached to the first member, A second torque hinge portion attached to the second member, one end of which is rotatable with a predetermined torque with respect to the first torque hinge portion, and the other end with a predetermined torque with respect to the second torque hinge portion. The connecting portion connecting the first torque hinge portion and the second torque hinge portion, and the turning operation of the connecting portion in the second torque hinge portion, One end is rotatably attached to the non-rotating part of the first torque hinge part or the first member, and the other end is the second torque hinge so as to be regulated by the positional relationship of Non-rotating part or second member It is characterized by having a link arm pivotally mounted.
By adopting this configuration, when the user tries to rotate the first member and the second member relative to each other, if the user tries to rotate with the second member, In the first torque hinge portion, the connecting portion is rotated. As the connecting portion is rotated, the rotation of the connecting portion in the second torque hinge portion is restricted by the link arm. Therefore, it is not necessary for the operator to operate while adjusting the rotation with respect to both the first torque hinge portion and the second torque hinge portion. The first member and the second member can be relatively rotated by simply applying a force in the direction. Therefore, even if the operator does not have the skill or experience to rotate while adjusting the rotation angle of the two rotation shafts at the same time, no matter who operates it, there is a large gap between the first member and the second member. Relative rotation can be easily performed so that a gap is not generated or the first member and the second member do not come into contact with each other at the time of rotation.

Further, when seen from the axial direction of the rotation shaft of the first torque hinge part and the second torque hinge part, there are a line segment connecting both ends of the link arm and a line segment connecting both ends of the connecting part. It is good also as arrange | positioning so that it may become a non-parallel state.
According to this configuration, the link arm provided non-parallel to the connection portion restricts the rotation operation of the connection portion in the second torque hinge portion. The second member can be rotated relative to the second member.

  Further, the one end of the link arm is configured such that the rotation axis of the second torque hinge portion and the first torque when the connecting portion is in a rotation state at a position orthogonal to the surface of the first member. Provided on a straight line connecting the rotation axis of the hinge portion, and the other end of the link arm is in a rotation state where the surfaces of the first member and the second member are parallel to each other In addition, a line segment connecting the other end of the link arm and the rotation shaft of the second torque hinge is a position parallel to the surfaces of the first member and the second member, and 1 may be provided at a position closer to the torque hinge portion.

A guide portion having guide grooves formed along both side surfaces of the second member is provided to be attached to both side surfaces of the second member, and the guide groove is provided on the second torque hinge portion. A slide member inserted in the guide groove so as to be slidable in the guide groove may be provided.
According to this configuration, the second member can slide and rotate with respect to the first member.

Further, the slide member may include two support members arranged in parallel along the extending direction of the guide groove.
According to this configuration, the second member can stably slide and move without causing rattling when the slide member moves in the guide groove.

  According to the tilt hinge device of the present invention, anyone can easily perform a tilting operation in which the gap between the members is not greatly opened and the members are smooth.

Embodiments of a tilt hinge device according to the present invention will be described below with reference to the drawings.
1-4 has shown the perspective view of PDA32 using the tilt hinge apparatus 30 of this embodiment. The PDA 32 includes a main body 31 provided with a keyboard (not shown) and a display unit 34 provided with a display (not shown).
A keyboard is provided on the upper surface of the main body 31, and a display unit 34 is arranged so as to be hidden so as to hide the keyboard. A display is provided on the upper surface of the display unit 34.

As shown in FIGS. 1 to 4, the tilt hinge device of the present embodiment is a slide in which the display unit 34 slides relative to the main body 31 in addition to the tilting operation in which the display unit 34 rotates with respect to the main body 31. The operation can be executed.
The slide operation is an operation in which the display unit 34 moves in parallel with the surface of the main body 31. By this sliding operation, the display unit 34 is moved from the surface of the main body 31 to expose the keyboard provided on the surface of the main body 31, and the display unit 34 is moved to the surface of the main body 31 from the state where the keyboard is exposed. You can cover the keyboard.
Such a sliding operation is a manual operation in which the operator holds the display unit 34 and slides it by hand.

  The tilt hinge device 30 is provided at the rear end portion of the main body 31, and is provided so that the front end portion of the display unit 34 can be rotated (tilted) with respect to the rear end portion of the main body 31. That is, the display unit 34 is provided so that it can be tilted when it moves most backward with respect to the surface of the main body 31. This is because the front end portion of the display unit 34 comes into contact with the surface of the main body 31 unless it is the position most moved rearward with respect to the surface of the main body 31.

FIG. 2 shows a state where the display unit 34 is slid rearward with respect to the main body 31 as shown in FIG.
3, after the display unit 34 is slid rearward from the main body 31 as shown in FIG. 2, a tilt operation is performed to rotate the display unit 34 at a predetermined angle with respect to the surface of the main body 31. It shows where you are. By this tilting operation, the user can see the display provided on the display unit 34 at a predetermined angle. As described above, the display unit 34 is slid most rearward with respect to the rear of the main body 31, and the tilt operation is performed unless the second torque hinge unit 38 described later reaches the front end of the display unit 34. I can't.
FIG. 4 shows the display unit 34 stopped at a predetermined angle with respect to the main body 31.

Next, the configuration of the tilt hinge device 30 will be described. FIG. 5 is an exploded view of the tilt hinge device 30.
The tilt hinge device 30 includes a first torque hinge part 36 attached to the main body 31 side, a second torque hinge part 38 attached to the display part 34 side, a first torque hinge part 36, and a second torque hinge part. 38, and a connecting arm 40 (a connecting portion in the claims) that is rotatable with respect to each of the first torque hinge portion 36 and the second torque hinge portion 38 at both ends. . As described above, since the torque hinge portions are provided on both the main body 31 side and the display portion 34 side, the torque necessary for tilting the display portion 34 can be dispersed, and the torque in each torque hinge portion is reduced. be able to. For this reason, compared with the case where there is one torque hinge part, the magnitude | size of the axial direction of each torque hinge part is made small, and it contributes to size reduction of each torque hinge part.
Further, a guide portion 42 that is a member attached to the side surface of the display portion 34 and has a guide groove 41 for sliding movement is provided via a slide member 70 (described later) of the second torque hinge portion 38. Yes.

The first torque hinge portion 36 includes a shaft 46 that serves as a rotation center, and washers that are sequentially arranged around the shaft 46 along the axial direction of the shaft 46. The shaft 46 of the first torque hinge portion 36 has a head 48 having a large diameter on the main body 31 side.
The arrangement of the washers and the like arranged around the shaft 46 is the order of the first washer 50, the connecting arm 40, the second washer 52, and the spring washer 54 in order from the side closer to the main body 31. The spring washer 54 is formed to have elasticity in the axial direction of the shaft 46.

Further, the first torque hinge portion 36 is provided with a fixing plate 44 for attaching the first torque hinge portion 36 to the side surface of the main body 31. The fixing plate 44 has the same cross-sectional shape as the shaft 46 in order to hold the one end portion 46a (the end portion on the side away from the side surface of the main body 31) of the first torque hinge portion 36 in a non-rotatable manner. An insertion hole 44a having a shape such that the shaft 46 can be inserted is formed.
One end portion 46 a of the shaft 46 inserted into the insertion hole 44 a is caulked between the head portion 48 of the shaft 46 and fixed to the fixing plate 44.

When the shaft 46 is caulked between the fixing plate 44 and the head 48, the spring washer 54 is compressed in the thickness direction of the washer. As a result, the first washer 50 and the second washer 52 pinch the connecting arm 40 with a predetermined force. Therefore, the connecting arm 40 rotates around the shaft 46 when a predetermined torque is applied, and is fixed at a position where the torque is released.
The insertion hole 40 a formed at one end of the connecting arm 40 is circular and has a larger diameter than the outer diameter of the shaft 46 to be inserted.

The insertion hole 54 a formed at the center of the spring washer 54 is formed in a circular shape having a larger diameter than the outer diameter of the shaft 46. For this reason, the spring washer 54 is rotatable with respect to the shaft 46.
The insertion hole 50 a formed at the center of the first washer 50 and the insertion hole 52 a formed at the center of the second washer 52 have the same shape as the cross-sectional shape of the shaft 46. For this reason, the first washer 50 and the second washer 52 cannot rotate with respect to the shaft 46.

The first washer 50 and the second washer 52 are preferably made of metal such as stainless steel and phosphor bronze, which are excellent in strength and wear resistance.
Such a first washer 50 and a second washer 52 are not limited to one each, and a plurality of them may be arranged.

Screw holes 55 and 55 are formed at both ends of the fixing plate 44 so as to be fixed to the main body 31 by screws 56 or the like.
In addition, a concave portion 57 is formed on the side surface of the main body 31 to which the fixing plate 44 is fixed.

The second torque hinge portion 38 includes a shaft 58 that serves as a rotation center, and washers that are sequentially arranged around the shaft 58 along the axial direction of the shaft 58. The shaft 58 of the second torque hinge portion 38 is formed with a head 60 having a large diameter on the display portion 34 side.
The washer and the like disposed around the shaft 58 are arranged in the order of the third washer 62, the connecting arm 40, the fourth washer 64, the spring washer 66, and the pressing washer 68 in order from the side closer to the display unit 34. is there. The spring washer 66 is formed to have elasticity in the axial direction of the shaft 58.

The holding washer 68 has a cross-sectional shape of the shaft 58 in order to hold the one end portion 58a of the shaft 58 of the second torque hinge portion 38 (the end portion on the side away from the side surface of the display portion 34) in a non-rotatable manner. An insertion hole 68a that has the same shape and into which the shaft 68 can be inserted is formed.
One end portion 58 a of the shaft 58 inserted into the insertion hole 68 a is caulked between the head portion 60 of the shaft 58 and fixed to the press washer 68.

When the shaft 58 is caulked between the pressing washer 68 and the head 60, the spring washer 66 is compressed in the thickness direction of the washer. As a result, the third washer 62 and the fourth washer 64 pinch the connecting arm 40 with a predetermined force. Therefore, the connecting arm 40 rotates around the shaft 58 when a predetermined torque is applied, and is fixed at a position where the torque is released.
The insertion hole 40b formed in the other end of the connecting arm 40 is circular and has a larger diameter than the outer diameter of the shaft 58 to be inserted.

The insertion hole 66 a formed at the center of the spring washer 66 is formed in a circular shape having a larger diameter than the outer diameter of the shaft 58. For this reason, the spring washer 66 is rotatable with respect to the shaft 58.
The insertion hole 62 a formed at the center of the third washer 62 and the insertion hole 64 a formed at the center of the fourth washer 64 have the same shape as the cross-sectional shape of the shaft 58. For this reason, the third washer 62 and the fourth washer 64 cannot rotate with respect to the shaft 58.

In addition, the 3rd washer 62 and the 4th washer 64 are good in the metal excellent in intensity | strength and abrasion resistance, such as stainless steel and phosphor bronze, respectively.
Such a third washer 62 and a fourth washer 64 may be arranged not only one, but a plurality of each.

  A slide member 70 that is slidable with respect to the guide portion 42 is provided at the end portion of the second torque hinge portion 38 on the display portion 34 side. The second torque hinge portion 38 is fixed to the side surface of the display portion 34 by the slide member 70.

  The slide member 70 includes two support members 72 and 72 and two fixing plates 74 and 75 that fix the support members 72 and 72 so as to be sandwiched between the guide portions 42. Of the two fixing plates 74 and 75, the fixing plate 75 attached to the head 60 of the shaft 58 has two insertion holes 76 and 76 for inserting and fixing the ends of the two support members 72. Is formed. The fixing plate 75 is fixed to the head 60 of the shaft 58 with screws 77.

The two support members 72, 72 are composed of a large diameter portion 72 a and a small diameter portion 72 b, and the small diameter portion 72 b is formed in a diameter that can be inserted into the guide groove 41, and the large diameter portion 72 a is formed in the guide groove 41. Is formed in a diameter that cannot be inserted.
The tip of the small diameter portion 72b of each support member 72 passes through the guide groove 41 and is attached to a fixing plate 74 disposed on the display portion 34 side of the guide surface of the guide portion 42. Two insertion holes 78, 78 are formed in the fixing plate 74, and a thread groove is formed at the tip of each small diameter portion 72b. After each small diameter portion 72b is inserted into each insertion hole 78, a nut 80 (see FIG. 6) is screwed to the tip of each small diameter portion 72b, and the support member 72 and the fixing plate 74 are fixed.

FIG. 6 shows a cross-sectional view of the guide portion 42 as viewed from the end in the sliding direction. However, in FIG. 6, the outer side of the large diameter portion 72a of the support member 72 is omitted.
The guide part 42 is formed in a U-shape opening toward the display part 34 when viewed from the sliding direction. The end of the display unit 34 is inserted into the U-shaped opening side of the guide unit 42.
Screw holes 43 are formed in the front and back surfaces of the guide part 42 and are fixed to the display part 34 by screwing or the like.

  A space is formed between the U-shaped inner bottom surface 42 a of the guide portion 42 and the side surface 34 a of the display portion 34. In this space, the fixing plate 74 and the nut 80 described above are arranged, and the end portion of the support member 72 inserted from the guide groove 41 is fixed. The support member 72 is fixed to the fixed plate 74, so that the fixed plate 74 contacts the inner bottom surface 42 a of the guide portion 42 and functions as a retaining member for the support member 72.

Next, the link arm will be described.
FIG. 7 shows a side surface of the tilt hinge device before tilting the display unit 34, and FIG. 8 shows a side surface of the tilt hinge device after tilting the display unit 34.
The link arm 82 has one end 82 a rotatably attached to a predetermined position of the fixed plate 44, and the other end 82 b rotatably attached to a predetermined position of the holding washer 68. That is, one end 82a of the link arm 82 is provided so as to be rotatable with respect to the main body 31 and not movable, and the other end 82b of the link arm 82 is rotatable with respect to the display unit 34. In addition, it is attached to the main body 31 so as to be movable.

Hereinafter, specific attachment of the link arm 82 will be described.
An attachment hole 44b for attaching one end portion 82a of the link arm 82 is formed below the insertion hole 44a of the fixing plate 44. The other end portion (the end portion on the main body 31 side) of the link arm shaft 84 is inserted and fixed in the attachment hole 44b.
An insertion hole 86 is formed in one end 82 a of the link arm 82. One end portion of the link arm shaft 84 is inserted into the insertion hole 86, and the link arm 82 is provided to be rotatable around the link arm shaft 84.
An E ring 85 that is a retaining member is attached to one end portion of the link arm shaft 84 that has passed through the insertion hole 86 of the link arm 82 so that the link arm 82 does not fall off the link arm shaft 84.

An attachment hole 68b for attaching the other end portion 82b of the link arm 82 is formed at a position on the first torque hinge portion 36 side of the holding washer 68. The other end portion (the end portion on the display unit 34 side) of the link arm shaft 89 is inserted into and fixed to the mounting hole 68b.
An insertion hole 88 is formed in the other end portion 82 b of the link arm 82. One end of a link arm shaft 89 is inserted into the insertion hole 88, and the link arm 82 is provided to be rotatable around the link arm shaft 89.
An E-ring 87 is attached to one end of the link arm shaft 89 that passes through the insertion hole 88 of the link arm 82 so that the link arm 82 does not fall off the link arm shaft 89.

Next, a specific attachment position of the link arm 82 and an operation will be described.
As shown in FIG. 7, in the state before the display unit 34 is slid to the end and before being tilted, the connecting arm 40 is at an angle of about 45 degrees with respect to the surface of the main body 31. It is connected to.

The attachment position of the one end portion 82a of the link arm 82 is the rotation axis of the second torque hinge portion 38 when the connecting arm 40 extends in a direction perpendicular to the surface of the main body 31 (the x position in FIG. 8). It is arranged on a straight line p connecting B and the rotation axis A of the first torque hinge portion 36.
The attachment position of the other end portion 82b of the link arm 82 is such that the surfaces of the main body 31 and the display portion 34 are parallel to each other (FIG. A line segment q connecting the other end 82b of the link arm 82 and the rotation axis B of the second torque hinge 38 at the position slid rearward is relative to the surfaces of the main body 31 and the display 34. It is a parallel position and is disposed on the side closer to the first torque hinge portion 36.

When the operator lifts the display unit 34 to tilt the display unit 34 as shown in FIG. 8 from the state of FIG. 7, the display unit 34 is centered on the rotation axis A of the first torque hinge unit 36. Rotate clockwise. At this time, the second torque hinge unit 38 receives a force that rotates clockwise by the force of lifting the display unit 34 of the operator, but as long as the link arm 82 is disposed between the fixed plate 44 and As long as the one end 82a of the link arm 82 does not move in the clockwise rotation direction, the link arm 82 does not rotate.
That is, if the connecting arm 40 moves in the clockwise direction with respect to the rotation axis A of the first torque hinge portion 36, the link arm 82 also rotates clockwise around the one end portion 82a. Since the link arm 82 is provided non-parallel to the connection arm 40, the rotation of the connection arm 40 with respect to the rotation axis B of the second torque hinge portion 38 is restricted.

Thus, by providing the link arm 82 non-parallel to the connection arm 40, the rotation of the connection arm 40 relative to the second torque hinge part 38 is restricted, and the first torque hinge part 38 has a first rotation. Based on the position with respect to the torque hinge portion 36, the link arm 82 restricts the rotation of the connecting arm 40 in the second torque hinge portion 38.
Therefore, an operator who wants to tilt the display unit 34 simply applies a force to lift the display unit 34 so that the display unit 34 is tilted, and the one end of the connection arm 40 and the other end of the connection arm 40 Can be simultaneously rotated. Further, the rate of simultaneous rotation of the one end and the other end of the connecting arm 40 can be changed depending on the attachment positions of the one end 82 a and the other end 82 b of the link arm 82.

Note that the tilt hinge device described above has a slide mechanism and employs a configuration in which the second torque hinge portion 38 is provided on the guide portion 42 on the side surface of the display portion 34 via the slide member 70. is doing.
However, the tilt hinge device of the present invention is not limited to the above-described configuration, and may not include a slide mechanism. In this case, the shaft of the second torque hinge portion 38 is fixed to the display portion 34.

The tilt hinge device of the above-described embodiment is attached with the same configuration at two locations on both sides of the device. That is, since the tilt hinge device described above has a sliding function, the same configuration is provided at two locations on both sides of the display unit to facilitate sliding.
However, the tilt hinge device may be provided only at one location for the device to be attached.

  Furthermore, the tilt hinge device of the present invention is not limited to a PDA as a device that can be adopted, and may be used for a mobile phone or other devices.

  While the present invention has been described in detail with reference to a preferred embodiment, the present invention is not limited to this embodiment, and it goes without saying that many modifications can be made without departing from the spirit of the invention. .

It is a perspective view of PDA which employ | adopted the tilt hinge apparatus of this invention. FIG. 2 is a perspective view showing a state where a display unit is slid rearward in the PDA of FIG. 1. It is a perspective view which shows the place which tilted the display part from the state of FIG. It is a perspective view which shows the place where the tilt of the display part was completed. It is an assembly exploded view explaining the structure of a tilt hinge apparatus. It is sectional drawing which shows the place which attached the guide part to the side surface of a display part. It is a side view which shows the state of a tilt hinge apparatus when the surface of a display part and a main body is mutually parallel. It is a side view which shows the state of the tilt hinge apparatus when a display part is tilted with respect to the main body. It is explanatory drawing explaining the conventional tilt hinge apparatus. It is explanatory drawing which shows the place where only the rotating shaft by the side of a display part rotated in the conventional tilt hinge apparatus. It is explanatory drawing which shows the place which only the rotating shaft by the side of the main body rotated in the conventional tilt hinge apparatus.

Explanation of symbols

30 Tilt Hinge Device 31 Body 32 PDA
34 Display portion 36 First torque hinge portion 38 Second torque hinge portion 40 Connecting arm 41 Guide groove 42 Guide portion 44 Fixing plate 46 Shaft 48 Head portion 50 First washer 52 Second washer 54 Spring washer 55 Screw hole 56 screw 57 recess 58 shaft 60 head 62 second washer 64 fourth washer 66 spring washer 68 shaft 68 holding washer 70 slide member 72 support member 74,75 fixing plate 76,78 insertion hole 82 link arm 84 for link arm Shaft 85 E-ring 86 Insertion hole 87 E-ring 88 Insertion hole 89 Link arm shaft

Claims (5)

In the tilt hinge device that connects the first member and the second member so as to be relatively rotatable,
A first torque hinge portion attached to the first member;
A second torque hinge portion attached to the second member;
The first torque hinge so that one end can be rotated with a predetermined torque with respect to the first torque hinge and the other end can be rotated with a predetermined torque with respect to the second torque hinge. A connecting portion for connecting the portion and the second torque hinge portion;
One end of the connecting portion of the second torque hinge portion is restricted by the non-rotating portion of the first torque hinge portion or the first member so that the rotation operation of the connecting portion is restricted by the positional relationship with the first member. On the other hand, it is provided with a link arm that is pivotably attached and the other end portion of which is pivotally attached to the non-rotating portion of the second torque hinge part or the second member. A tilt hinge device.   A line segment connecting both end portions of the link arm and a line segment connecting both end portions of the connecting portion are non-parallel when viewed from the axial direction of the rotation shaft of the first torque hinge portion and the second torque hinge portion. 2. The tilt hinge device according to claim 1, wherein the tilt hinge device is arranged so as to be in a state. One end of the link arm is
A straight line connecting the rotation shaft of the second torque hinge portion and the rotation shaft of the first torque hinge portion when the connecting portion is in a rotation state at a position orthogonal to the surface of the first member. Provided on the
The other end of the link arm is
When the first member and the second member are in a rotational state where the surfaces of the first member and the second member are parallel to each other, the other end of the link arm and the rotational shaft of the second torque hinge portion are connected. The line segment is provided at a position that is parallel to the surfaces of the first member and the second member and that is close to the first torque hinge portion. Or the tilt hinge apparatus of Claim 2. A guide portion formed with guide grooves along both side surfaces of the second member is provided to be attached to both side surfaces of the second member;
The slide torque formed by the second torque hinge portion being slidably inserted in the guide groove in the guide groove. The tilt hinge device according to item.   The tilt hinge mechanism according to claim 4, wherein the slide member has two support members arranged in parallel along the extending direction of the guide groove.