JP3032465B2 - Hinge device for portable radio - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide the hinge unit with a small size, less production of play and excellent productivity and mount performance at a low cost. SOLUTION: The unit includes a hinge main body 63 provided to a radio equipment main body (or a main body cover), a hinge shaft 77 provided to the main body cover 52 (or radio equipment main body) and supported by the hinge main body 63, a slid frame 85 slidable axially, and an elastic member 91 energizing the slide frame 85 in the axial direction to abut the slide frame 85 with the hinge shaft 77. A cam is provided to one of both abutting parts of the hinge shaft 77 or the slide frame 85 and a follower part is provided to the other and the cam delivers the energizing force of the elastic member 91 to the hinge shaft 77 so that the main body cover 52 is kept in the opening and/or closing state.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hinge device for a portable wireless device, and more particularly, to a hinge device for a portable wireless device that pivotally supports a body cover of the wireless device body so that the cover can be opened and closed. here,
Portable wireless devices are portable wireless telephones, cordless telephones,
A portable device such as a PHS, a wireless communication device, and a portable information processing terminal device.

[0002]

2. Description of the Related Art In recent years, in order to enhance the portability of a portable wireless device, many types have been used in which a body cover is provided on a wireless device main body and the body cover is pivotally supported on the wireless device main body.
In this type, when not in use, the main body cover is closed to cover a part or the whole of the wireless device main body, thereby protecting the switch and the like. In use, the user opens the main body cover and operates exposed switches and the like. Since the switches and the like are protected by the body cover, the portable wireless device can be easily carried. Hereinafter, this body cover is referred to as a flip.

[0003] As a hinge device provided on a shaft support portion of a flip, various hinge devices having a function of holding the flip in a closed state and an open state have been proposed in order to improve usability. Hereinafter, an example of a hinge device having such a function will be described.

FIG. 12 is a sectional view showing a state in which a conventional hinge device is attached to a portable wireless device. In FIG. 12, a main body case 1 of a radio device main body is a molded product made of a resin material. A mounting base 5 for mounting the flip 3 is formed in the main body case 1, and first hinge shafts 7 protrude from wall surfaces 6 on both sides of the mounting base 5. The first hinge shaft 7 is a cylindrical boss, and has a hinge mounting hole 1 for mounting a hinge device 9 at the center.
1, a rectangular recess is provided.

FIG. 13 is a side view showing the structure of the hinge device 9. The camshaft 13 is formed by integrally connecting the hinge mounting portion 15 and the cam portion 17 in the camshaft direction. The hinge mounting portion 15 is inserted into the hinge mounting hole 11 as shown in FIG. The hinge mounting portion 15 has a quadrangular prism shape, and the outer surface of the quadrangular prism is engaged with the inner surface of the hinge mounting hole 11. Therefore, the hinge mounting portion 15 is not rotated with respect to the main body case 1. FIG.
Reference numeral 4 denotes a cam shape (cross-sectional shape) of the cam portion 17. As shown in the drawing, in the conventional device, the cam shapes of the cam portions 17 of the two hinge devices 9 of FIG. 12 are different from each other. That is, the cam portion 17 of one hinge device 9 is the action cam of FIG. 14A, and the other cam portion 17 is the holding cam of FIG. 14B. At the center of the camshaft 13, as shown in FIG.
9 are provided. The shaft 21 is inserted through the through hole 19, and the hinge mounting portion 15 of the shaft 21 is inserted.
The part protruding to the side is hinged part 1 by caulking.
5 is fixed. The other end of the shaft 21 is integrally formed with a disk-shaped second hinge shaft 23.

A mounting hole 26 is provided in the center of the leaf spring 25, and the leaf spring 25 is loosely fitted to the shaft 21 through the mounting hole 26, and the cam portion 17 and the second hinge shaft are provided. 23. This leaf spring 25 is formed by laminating three spring steels. And leaf spring 25
Is gently bent on both sides of the mounting hole 26,
The distal end portion 27 of the leaf spring 25 is pressed against the cam surface of the cam portion 17 by the elastic force of the spring itself. Further, at the center of the leaf spring 25, a collar-shaped locking claw 29 is integrally provided in a direction perpendicular to the spring direction. A washer 31 is loosely fitted to the shaft 21 so as to be located between the leaf spring 25 and the second hinge shaft 23. Washer 3
Reference numeral 1 is provided to prevent the second hinge shaft 23 from being worn when the leaf spring 25 rotates with respect to the second hinge shaft 23.

The flip 3 has a divided structure including a flip body 33 and a flip cover 35 as shown in FIG. The flip body 33 and the flip cover 35 are molded products of a resin material similarly to the body case 1. The flip body 33 and the flip cover 35 are attached so as to sandwich the first hinge shaft 7 and the hinge device 9 of the body case 1 and are fixed by fixing screws 37. The flip 3 is provided with a first bearing 39 at a position corresponding to the first hinge shaft 7 and a second bearing 41 at a position corresponding to the second hinge shaft 23. Further, the flip 3 is provided with a leaf spring holding portion (not shown), and the leaf spring holding portion is engaged with the locking claw 29 of the leaf spring 25. Therefore, the leaf spring 25 does not rotate with respect to the flip 3.

Next, the operation of the above-mentioned conventional hinge device will be described. When the flip 3 opens and closes, the flip 3 rotates about the first hinge shaft 7 and the second hinge shaft 23. Here, as described above, the camshaft 13 is attached to the main body case 1 and the leaf spring 25 is attached to the flip 3 so as not to rotate. Therefore, when the flip 3 opens and closes, the leaf spring 25 rotates with respect to the camshaft 13.

FIG. 15A shows the opened state of the flip 3, and FIG. 15B shows the positional relationship between the action cam and the leaf spring 25 in this opened state. Here, as shown in the drawing, one of the tip portions 27 of the leaf spring 25 that sandwiches the action cam is denoted by 25a, and the other is denoted by 25b. In the figure, the action cam is in contact with the leaf spring 25 at the lowest position of the cam height (the distance from the center to the outer peripheral surface of the cam). At this time, the holding cam is in contact with the leaf spring 25 at a flat portion on the outer periphery as shown in FIG. Flip 3
By the function of the holding cam, it is held without rattling.

FIG. 1D shows the state of the action cam and the leaf spring 25 when the flip 3 is at the position indicated by the dotted line m in FIG. 1A (that is, when the opening angle of the flip 3 is α). ing. Here, the opening angle is an angle formed by the flip 3 with the main body cover 1. In FIG. 4D, the leaf spring 25 rotates with respect to the action cam from FIG. 5C, the leaf spring 25 is pushed and spread by the action cam, and the elastic force of the leaf spring 25 acts on the action cam. ing. When the flip 3 is released from this state, the leaf spring 25 rotates by the reaction force received from the action cam. This rotation direction is such that the flip 3 opens according to the setting of the cam surface of the action cam. And flip 3
Reaches the open position, it is held open by the function of the holding cam described above.

FIG. 1E shows the state of the action cam and the leaf spring 25 when the flip 3 is at the position indicated by the dotted line n (open angle β) in FIG. In this case, FIG.
The contact position between the cam surface and the leaf spring 25 is on the opposite side of the cam vertex a. When the flip 3 is released from the state shown in FIG. 3E, the flip 3 closes due to the elastic force of the leaf spring 25 and comes into contact with the main body case 1 and stops. This stopped state is the closed state.

When the flip 3 is at the position indicated by the alternate long and short dash line 1 in FIG. 15A, the leaf spring 25 is in contact with the cam vertex a of the action cam. When the flip 3 is located at a position where the opening angle is larger than the one-dot chain line l, the opening operation is performed as described with reference to FIG. When the opening angle is smaller than the one-dot chain line l, the closing operation is performed as described with reference to FIG.

[0013]

The conventional hinge device described above has disadvantages due to the structure of the device as described below.

(1) In the conventional apparatus, the leaf spring 25 is pressed against the cam surface formed on the side surface of the cam portion 17 by the elastic force of the spring itself, and rotates under the pressed state. The leaf spring 25 applies a rotational torque to the cam portion 17 according to the shape of the cam surface, and the reaction of the rotational torque is applied to the cam portion 1.
Receive from 7. This reaction is applied to the flip 3
Conveyed to.

Here, a difference easily occurs between the set value at the time of the design calculation of the leaf spring 25 and the actual actual force value, and the actual actual force value of the leaf spring 25 easily varies depending on the processing state. Therefore,
In the case of the configuration using the leaf spring 25, the performance of the hinge device cannot be confirmed unless an actual product is manufactured.

Further, since the reaction that the leaf spring 25 receives from the cam portion 17 is transmitted to the flip 3, the locking claw 29 of the leaf spring 25 may deform the leaf spring holding portion of the flip 3, which may cause the deformation. There is a problem that rattling may occur.

Further, in the conventional hinge device, as described above, it is necessary to provide the washer 31 between the leaf spring 25 and the second hinge shaft 23 for preventing the second hinge shaft 23 from being worn. In the configuration using the leaf spring 25, there is a problem that the number of components must be added as described above.

Further, it is difficult to reduce the size of the conventional hinge device. In order to reduce the size, it is necessary to reduce the cam diameter and increase the spring pressure. However, in the configuration using the leaf spring 25, the increase in the spring pressure is limited.

(2) The conventional hinge device has a problem that the structure is complicated, the axis is easily shifted, and the backlash is easily generated as described below. That is, in the structure of the conventional device, (a) the hinge mounting hole 1 of the main body case 1
1 and the camshaft 13 and (b) the gap between the camshaft 13 and the shaft 21, the centers of the first hinge shaft 7 and the second hinge shaft 23 are shifted. The dimensions of the bearing portion of the flip 3 are set in consideration of the deviation between the two shafts. Therefore, the clearance between the bearings is large,
This portion is apt to rattle. Similarly, the positional relationship between the leaf spring 25 and the cam portion 17 is likely to shift,
The displacement of this portion also causes the occurrence of rattling.

In the conventional apparatus, the camshaft 13 and the shaft 21 are fixed by caulking. Therefore,
Jigs and tools for caulking are required, and workability deteriorates because caulking is performed during assembly work.
In addition, there is a problem that dimensional variation easily occurs in the swaged portion.

(3) In the conventional apparatus, not only the flip 3 is opened / closed but also the flip 3 is held in an open state to suppress rattling. Here, simply providing the action cam cannot hold the flip 3 in the open state, so two types of cams, an action cam and a holding cam, are provided.

Since the two types of cams are provided in this manner, a sorting operation or the like is required at the time of assembling the portable wireless device, and there is a problem that productivity is low. Further, at least two hinge devices are required, which is disadvantageous in that the number of parts cannot be reduced.

[Object of the present invention] The present invention has been made to solve the problems described above. An object of the present invention is to provide a hinge device which has the following advantages, is small in size and inexpensive, has little rattling, and is excellent in productivity and assembly.

(1) The structure is such that the elastic force of the elastic member acts in the axial direction instead of the structure in which the leaf spring is pressed against the side surface of the cam shaft. Therefore, an elastic member having a small difference between the setting of the design calculation and the actual ability can be used as the elastic member. Further, the elastic member does not deform other members. Further, it is easy to reduce the size of the elastic member. (2) The structure is simple, and the occurrence of rattling is small. And it is easy to assemble and has high productivity. (3) The flip can be operated as desired with one kind of cam shape.

[0025]

SUMMARY OF THE INVENTION (1) The present invention relates to a hinge device for a portable wireless device which pivotally supports a main body cover so that the main body cover can be opened and closed with respect to the radio device main body. A hinge main body, and a hinge shaft rotatably provided on the other of the main body cover or the wireless device main body and rotatably supported with respect to the hinge main body,
A slide piece slidably provided in the hinge body in the axial direction, and an elastic member provided on the hinge body and biasing the slide piece in the axial direction to contact the hinge shaft, A cam portion is provided on one of the contact portions of the hinge shaft or the slide piece, and a driven portion is provided on the other,
The cam portion has a cam surface set to transmit the urging force of the elastic member to the hinge shaft so that the main body cover is held in an open state and / or a closed state. Further, the cam surface has a minimum cam height at a position corresponding to the open state of the main body cover, and a predetermined cover opening intermediate between the open state and the closed state from a position corresponding to the open state. The cam height increases toward the position corresponding to the angle, the cam height reaches the highest cam height at the position corresponding to the predetermined cover opening angle, and the position corresponding to the closed state from the cam vertex. It is set so that the cam height decreases toward. Furthermore, in the present invention, the hinge body
The outer surface has a polygonal pillar side shape, and the hinge axis has a polygonal pillar shape
Mounting boss is provided, and the wireless device main body or the main body cover is provided.
On one of the bars, the polygonal prism side shape of the hinge body
And a hinge main body storage portion for engaging with the radio main body.
Alternatively, the other end of the main body cover may be provided with the hinge shaft.
A hinge shaft mounting hole that engages with the attached boss is provided.
I do.

According to the above configuration, the hinge shaft is supported by the hinge body, and the slide piece urged in the axial direction by the elastic member is in contact with the hinge shaft. The elastic member is, for example, a member such as a spring or a rubber member that can urge the slide piece in the axial direction by an elastic force, and does not need to use a leaf spring as in the related art. A cam mechanism is provided on the hinge shaft and the joint of the slide piece. The cam mechanism is provided so as to transmit the urging force of the axial direction of the elastic member to the hinge axis, it can be used end cam, for example, as a preferred embodiment. According to the setting of the cam mechanism, the main body cover is held in the open state and / or the closed state.

Here, in the present invention, the cam surface further transmits the urging force of the elastic member to the hinge shaft so as to open or close the main body cover in accordance with the opening angle of the main body cover. Setting, as described above, the cam height at the position corresponding to the open state of the main body cover is the lowest, from the position corresponding to the open state, the intermediate between the open state and the closed state The cam height increases toward a position corresponding to the predetermined cover opening angle, reaches a cam apex where the cam height becomes highest at a position corresponding to the predetermined cover opening angle, and the closed state from the cam apex. Is set so that the cam height decreases toward the position corresponding to. Therefore, in the intermediate state between the open state and the closed state, a cover operation is performed in which the cover performs one of the open operation and the close operation at the predetermined cover open angle and does not stop at the intermediate position. And especially in the present invention,
The main body has a guide portion into which the slide piece is inserted,
The shape of the outer surface of the ride piece is a polygonal pillar side shape,
Formed so that the inner surface of the dovetail portion engages with the polygonal prism side surface shape.
The outer surface of the slide piece and the inner surface of the guide portion are engaged.
The rotation of the slide piece is suppressed by the combination. did
Therefore, the rotation of the slide piece is simple and easy to manufacture.
Rolling can be suppressed. (2) In a preferred aspect of the present invention, the hinge book
The outer surface of the body has a polygonal prism side shape, and the hinge axis is polygonal.
A column-shaped mounting boss is provided, and the radio unit or the book
On one side of the body cover, the polygonal prism side surface of the hinge body
A hinge main body storage portion for engaging with the shape is provided;
On the other side of the body or the body cover, in front of the hinge axis
A hinge shaft mounting hole for engaging with the mounting boss is provided.

The opening angle refers to the angle formed by the main body cover and the radio main body as described above. The cam mechanism is configured to transmit the biasing force of the elastic member in the axial direction to the hinge shaft and to convert the biasing force into a rotational torque.
The cam mechanism is set so as to apply a rotational torque to the hinge shaft such that the body cover opens or closes in accordance with the opening angle of the body cover. Such a setting
For example, when the above-described end face cam is used, it is realized by setting the inclination angle of the cam face. The setting of the cam mechanism is set so that no rotational torque is applied to the hinge shaft when the body cover is in the open state and / or the closed state. (3) Further, in the present invention, preferably, the cam surface further increases the cover opening angle from the position where the cam height corresponding to the open state is lowest, toward the direction in which the body cover is further opened. it is inclined such cam height increases with.

(4) In the present invention, the elastic member may be
A coil spring having one end attached to the hinge body and the other end attached to the slide piece may be used. The coil spring has the advantage that the difference between the design calculation value and the actual strength value is small and the quality variation is small as compared with the leaf spring shown in the related art.

(5) Further, in the present invention, a plurality of the coil springs may be provided in parallel. Here, the coil springs may be arranged side by side, or coil springs having different diameters may be arranged coaxially. By using a plurality of coil springs, the overall length of the hinge body is reduced, and the size of the hinge device is reduced.

[0031]

(6) In the present invention, the driven portion may be a driven pin protruding from an end surface of the hinge shaft or the slide piece. Since the driven pin has a small contact surface with the cam surface, the frictional force received from the cam surface is small. Therefore, the resistance when opening and closing the body cover is reduced.

(7) In the present invention, the hinge shaft may be provided with a cable passage for passing a cable connecting the radio device main body and the main body cover. The cable is guided between the wireless device main body and the main body cover by the cable passage.

(8) In the present invention, at least one of the hinge body and the hinge shaft may be provided integrally with the radio device body or the body cover.
As described above, the number of parts is reduced, and the assembling work is facilitated. (9) In the present invention, preferably, the cam surface
Has two cam vertices facing each other across the hinge axis center.
And the line connecting these two cam vertices
The cam surface is set to a line object.

[0035]

Embodiments of the present invention will be described below with reference to the drawings.

Embodiment 1 FIG. 1 is a perspective view of a portable wireless device to which the hinge device of the present embodiment is applied. As shown in the figure, a flip 52 sandwiches a mounting base 51 provided on a main body case 50 of the radio device main body from both sides. The flip 52 includes a hinge device 53 provided on the mounting table 51.
(Not shown in FIG. 1).

FIG. 2 is a partial cross-sectional view of the portable wireless device, showing the structure of the hinge device. Note that the structure of the hinge portion of the present embodiment has a symmetrical shape in the same manner as in the prior art of FIG.
Is provided. FIG. 3 is a cross-sectional view of the hinge device 53 viewed from a direction perpendicular to FIG. The main body case 50 is a molded product of a resin material.
A mounting base 51 is provided at the center. This mounting base 51
An octagonal concave portion is provided as a mounting hole 57 on the wall surface 55 of the, and a mounting wall 59 is provided on the mounting base 51 so as to protrude into the case.

The hinge body 63 of the hinge device 53 comprises a hinge body cylinder 65 made of resin and a bottom plate 67. The hinge main body cylinder 65 is formed in a tubular shape, and has an octagonal prism side surface whose outer surface engages with the mounting hole 57, and a hexagonal prism-like shape whose inner surface engages with a slide piece 85 described later. is there. Four engagement holes 69 are provided on the side surface near one end of the hinge main body cylinder 65, and a hinge shaft abutting wall 71 is provided upright at the other end toward the central axis. On the other hand, the bottom plate 67 is a hexagonal plate corresponding to the inner surface shape of the hinge main body cylinder 65. At the edge of the bottom plate 67, four columnar engaging portions 72 are provided upright. The engaging portions 72 are provided toward the inside of the hinge main body, and a locking claw 73 is provided at the tip of each engaging portion 72 toward the outside. The distance between the opposed engaging portions 72 is set slightly larger than the outer diameter of a hinge spring 91 described later.

The above-described engaging claws 73 of the bottom plate 67 are engaged with the engaging holes 69 of the hinge main body cylinder 65 to form the hinge main body 63. The hinge body 63 is inserted into the mounting hole 57 of the body case 50. At this time, the outer side surface of the hinge main body cylinder 65 is engaged with the mounting hole 57, and the bottom plate 67 abuts against the abutting wall 59. The step portion 59a of the abutment wall 59 supports the hinge body 63 in a direction perpendicular to the axis as shown in the figure. Thus, the hinge main body 63 is non-rotatably attached to the main body case 50.

The hinge shaft 77 is made of a resin material and is supported by the hinge main body cylinder 65. FIG. 4 is a plan view, a front view, and a bottom view of the hinge shaft 77. As shown in the figure, the hinge shaft 77 includes a cylindrical shaft portion 79,
The shaft portion 79 is pivotally supported so as to slide on a bearing surface (a part of the inner surface of a hollow hexagonal column) on the inner surface of the hinge main body cylinder 65. Also, the hinge shaft 77 is positioned in the axial direction by one end surface 80 of the shaft portion 79 abutting on the hinge shaft abutting wall 71. At the center of the end face 80 of the shaft portion 79, a square column-shaped shaft mounting boss 81 is provided in a protruding manner. Further, two driven pins 83 are projected from the other end surface 82 of the shaft portion 79, and each driven pin 83 has a cylindrical shape and the tip of the pin has a hemispherical shape. The shaft portion 79, the shaft mounting boss 81, and the driven pin 83 are integrally formed.

A slide piece 85 made of a resin material is further inserted into the hinge main body 63, and is disposed between the hinge shaft 77 and the bottom surface of the hinge main body. FIG. 5 is a plan view, a front view, and a bottom view of the slide piece 85. As shown in the figure, the slide piece 85 is a hexagonal column-shaped member, and the slide piece 85 is slidable in the axial direction by engaging the side surface of the hexagonal column with the inner side surface of the hinge main body cylinder 65. With it, it does not rotate around the axis. A spring mounting boss 89 protrudes from the center of one end face 87 of the slide piece 85. One end of a hinge spring 91 made of a coil spring is fitted into the spring mounting boss 89, and the other end of the hinge spring 91 is fitted between the engaging portions 72 of the bottom plate 67. The hinge spring 91 is
It is set so as to be in a compressed state in the attached state in FIG. Therefore, the slide piece 85 is urged by the elastic force (compression reaction force) of the hinge spring 91 and is in pressure contact with the hinge shaft 77.

An end face cam 93 is formed on the end face of the slide piece 85 on the side contacting the hinge shaft 77. "End face cam" refers to a cam formed on an end face such as a shaft, the cam height of which changes in the circumferential direction. Here, in the case of the end face cam, the “cam height” refers to the height in the axial direction from the reference position as shown in FIG. 5B. FIG. 6 shows a cam shape of the end cam 93. The abscissa of the figure is the distance from the point p to the point q along the circle of the two-dot chain line z in FIG. 5A, and the ordinate is the cam height at each position on the two-dot chain line z. It is. FIG. 6 shows only the range of 90 degrees,
The cam shape of the end cam 93 is symmetric with respect to the straight line x and the straight line y. As shown in FIG. 6, the end face cam 93 is a straight cam having an inclination angle of 45 degrees.

Here, setting the inclination angle to 45 degrees has the following significance. In the present embodiment, as described later, when the inclined surface of the end cam 93 and the driven pin 83 are in contact with each other, the elastic force of the hinge spring 91 is converted into rotational torque for rotating the hinge shaft 77 at this contact portion. I have. Here, the force acting on the driven pin 83 from the end cam 93 based on the elastic force is P, the distance between the point of application of the force P and the center of the slide piece 85 (the center axis of the hinge shaft 77) is r, and the inclination angle of the cam is θ. Then, the rotation torque T is obtained by the following equation.

[0044]

T = P · r · sin 2θ / 2 Therefore, when the inclination angle θ is set to 45 degrees, the maximum rotation torque T can be obtained for the same elastic force. The configuration of the hinge device 53 of the present embodiment has been described above.

The flip 52 is a molded product of a resin material similarly to the main body case 50. Flip 52
A wall surface 97 is provided so as to face the wall surface 55 of the main body case 50, and a rectangular concave portion is provided in the wall surface 97 as a hinge shaft mounting hole 99. The shaft mounting boss 81 is inserted into the hinge shaft mounting hole 99. Since the inner surface of the hinge shaft mounting hole 99 and the outer surface of the shaft mounting boss 81 are engaged with each other, the hinge shaft 77 does not rotate with respect to the flip 52 (is prevented from rotating). In the state shown in FIG. 2, the flip 52 sandwiches the mounting base 51 of the main body case 50 as described above. Therefore, the flip 52 is positioned in the axial direction by the wall surfaces 55 on both sides of the mounting table 51.

Next, the order of assembling the portable radio shown in FIG. 2 will be described. The hinge shaft 77 is inserted into the hinge main body tube 65, and the slide piece 85 is further inserted. One end of the hinge spring 91 is fitted into the spring mounting boss 89 of the slide piece 85, and the other end of the hinge spring 91 is engaged with the engaging portion 72 of the bottom plate 67.
Fit between. Then, the bottom plate 67 is connected to the hinge main body cylinder 6.
5, the locking claws 73 of the bottom plate 67 are locked in the engaging holes 69 of the hinge body cylinder 65. Thus, the hinge device 53 is completed. The hinge device 53 is inserted from the mounting hole 57 and abuts against the abutment wall 59. Next, the hinge shaft 7
7 is pushed into the inside of the hinge main body 63, and the flip 52 is arranged at the illustrated position. Then, the hinge shaft 77 is pushed out by the reaction force of the hinge spring 91, and the shaft mounting boss 81 of the hinge shaft 77 enters the hinge shaft mounting hole 99 of the flip 52. Thus, the state shown in FIG. 2 is obtained.

Next, the operation of the hinge device according to the present embodiment will be described. As described above, the hinge main body 63 is attached to the main body case 50 and the hinge shaft 77 is attached to the flip 52 so as not to rotate. Therefore, when the flip 52 is rotated, the shaft 79 of the hinge shaft 77 is
Rotate while sliding with 5. At this time, the slide piece 85 slides in the axial direction according to the rotation of the hinge shaft 77.

FIG. 7A shows an open state of the flip 52 similarly to FIG. 15A described above. FIG. 7 (b)
Are the slide piece 85 and the hinge shaft 77 in this open state.
Is the positional relationship. As shown in FIG. 9B, the driven pin 83 at the position p of the end cam 93 where the cam height is the lowest.
Is located. In this state, the amount of contraction deformation of the hinge spring 91 is minimum. When a rotational force acts on the flip 52 from the outside, the rotational force acts on the hinge shaft 77 and the slide piece 85 tends to move in the direction of contracting the hinge spring 91 (arrow X in the drawing). Here, the slide piece 85 receives a reaction force from the hinge spring 91, and this reaction force acts as a resistance to the rotation of the slide shaft 77. The flip 52 is thus held so as not to rattle.

FIG. 9C shows that the flip 52 is the same as FIG.
Slide piece 85 at the position of dotted line m (opening angle α)
And a positional relationship between the hinge shaft 77 and the hinge shaft 77. In FIG. 9C, the angular position of the hinge shaft 77 is different from the above-described open state. Then, the slide piece 85 is in a state of being moved by being pushed by the driven pin 83 according to the setting of the cam surface. The hinge spring 91 is further compressed than in the open state, and exerts a reaction force corresponding to the compression on the slide piece 85. Follower pin 83
And the end cam 93 are in contact on the slope of the cam surface,
A rotational torque based on the reaction force of the hinge spring 91 acts on the driven pin 83. This rotational torque is in the direction of arrow Y in the figure. When the flip 52 is released from this state,
The hinge shaft 77 rotates in the arrow Y direction, and the flip 52 engaged with the hinge shaft 77 opens. Then, when it reaches the position of the open state in FIG. 7A, it is held in the open state as described above.

FIG. 5D shows that the flip 52 is the same as FIG.
Slide piece 85 at the position of dotted line n (open angle β)
And a positional relationship between the hinge shaft 77 and the hinge shaft 77. In this case, the contact position between the cam surface and the driven pin 83 is on the opposite side of the cam vertex q as compared with FIG. When the flip 52 is released from this state, the hinge shaft 77 moves
, And the flip 52 performs the closing operation. Then, the flip 52 stops at a position where it is in contact with the main body case 50 and enters a closed state.

When the flip 52 is at the position indicated by the alternate long and short dash line 1 in FIG. 7A, the driven pin 83 is in contact with the cam vertex q of the end face cam 93. When the flip 52 is located at a position where the opening angle is larger than the dashed line 1, the opening operation is performed as described with reference to FIG. When the opening angle is smaller than the one-dot chain line l, the closing operation is performed as described with reference to FIG.

The hinge device of the present embodiment described above has the following advantages.

(1) A hinge spring 91 made of a coil spring is used as an elastic member for causing the hinge device 53 to perform a desired operation.
Is used. The coil spring is mounted so as to be deformed in the axial direction. The set value at the time of the design calculation of the coil spring agrees well with the actual force value. The quality variation of the coil spring is smaller than that of a leaf spring or the like. Therefore, the function of the hinge device can be more accurately exhibited by using the coil spring.

The hinge spring 91 is housed inside the hinge main body 63 and performs compression and expansion operations. The hinge spring 91 is not configured to slide while being in pressure contact with another member. Therefore, the other members do not deform or wear due to the hinge spring 91.

Further, the spring constant of the coil spring is represented by a wire diameter,
It can be easily adjusted by changing the size, the number of turns, and the like, and the spring constant can be easily increased. Therefore, the entire hinge device can be reduced in size by reducing the size of the coil spring.

(2) The inner surface of the hinge body 63 serves as a bearing, and the shaft 79 of the hinge shaft 77 serves as a rotating shaft. The play of the rotating part occurs between the hinge body 63 and the shaft part 79. As described above, the structure is simple, and there is little attachment relation of components that may cause rattling. Therefore, rattling between the flip 52 and the main body case 50 hardly occurs.

(3) The assembly of the hinge device 53 is performed by sequentially assembling the hinge shaft 77, the slide piece 85, the hinge spring 91, and the bottom plate 67 to the hinge main body cylinder 65. The assembling direction is one direction, the assembling is easy, and caulking as in the prior art is unnecessary. Therefore, automatic assembly using a robot can be easily performed.

(4) Hinge device 53 and flip 52
Is mounted by inserting the hinge device 53 into the mounting hole 57 of the main body case 50, pushing the hinge shaft 77, and applying the flip 52 to the mounting position. In the prior art, the flip was configured in a divided structure, and the hinge device was sandwiched from above and below and screwed and fixed. However, as described above, when the present hinge device 53 is used, it is not necessary to use a split structure for the flip or to perform a screwing operation during assembly.

The flip mounting can be easily performed by forming the shaft mounting boss 81 of the hinge shaft 77 such that the cross section becomes smaller toward the boss apex (for example, a trapezoidal polygonal pyramid as shown in FIG. 2). It can be carried out.

(5) The flip 52 is formed by one kind of cam.
Can be held in the open state, and the flip 52 can perform desired opening and closing operations. As before,
Compared to a case where two types of cams, an action cam and a holding cam, are required, the number of parts is reduced, and it is also possible to use only one hinge device.

(6) The hinge device 53 includes the main body case 50.
Are supported by the wall provided with the mounting hole 57 and the abutting wall 59. When an external force acts on the flip 52, the external force acts on the shaft mounting boss 81 of the hinge shaft 77. Thus, the support position and the position where the external force acts are close to each other. Therefore, the bending moment acting on the hinge device 53 due to the external force applied to the flip 52 is small, which is advantageous in strength.

[Modification of Embodiment 1] The following modifications can be made to Embodiment 1 described above.

(1) The hinge body 63 is attached to the flip 52,
The hinge shaft 77 may be configured to be attached to the main body case 50. In this case, the mounting relationship of the hinge device 53 is directly opposite to that of FIG.

(2) The end face cam 93 may be provided on the end face 82 of the hinge shaft 77, and the driven pin 83 may be provided on the slide piece 85.

(3) The shape of the driven pin 83 is shown in FIG.
It may be deformed as shown in FIG.

(4) The cam shape of the end face cam 93 is shown in FIG.
It may be deformed as shown in FIG. In this case, it is preferable to change the driven pin to one in FIG. 4 corresponding to the cam shape.

(5) The outer side surface shape of the hinge main body cylinder 65 may be a polygonal side surface shape having a different number of angles from the octagonal prism side surface.
In this case, a deformation corresponding to the shape of the inner surface of the mounting hole 57 of the main body case 50 may be performed.

Similar modifications may be made for the outer surface of the slide piece 85 and the inner surface of the hinge body cylinder 65. The same deformation is applied to the shaft mounting boss 8 of the hinge shaft 77.
1 and the shape of the hinge shaft mounting hole 99 of the flip 52 may be performed.

[Second Embodiment] FIG. 9A is a cross-sectional view showing the structure of a hinge device 101 of the present embodiment. In the present embodiment, a description of the same configuration as in the first embodiment will be omitted.

The second embodiment is different from the first embodiment in that two hinge springs 103 are provided.
Then, two spring mounting bosses 106 are attached to the slide piece 105 so that the two hinge springs 103 can be mounted.
Is provided. The same bottom plate 107 is also provided with two similar spring mounting bosses 108. Note that, in the present embodiment, the engaging portions 72 of the bottom plate 107 are provided with a phase shifted by 45 degrees with respect to the first embodiment, and therefore, the engaging portions 72 are not shown in FIG. FIG.
(B) is a bottom view of the slide piece 105 and shows the positional relationship between the two hinge springs 103.

In this embodiment, a plurality of hinge springs 103
, The spring reaction force is increased. Therefore,
With a hinge device of the same size, a larger spring reaction force can be applied to the slide piece. Further, in a setting in which a spring reaction force of the same magnitude acts on the slide piece, the length of each spring can be made shorter than in the case of a single spring. As described above, by using a plurality of hinge springs,
The size of the hinge device can be reduced.

[Third Embodiment] FIG. 10 is a sectional view showing the structure of a hinge device 111 of the present embodiment. In the present embodiment, a description of the same configuration as in the first embodiment will be omitted.

The hinge main body 113 has a shape obtained by integrating the hinge main body cylinder of the first embodiment and the bottom plate. Unlike the first embodiment, no hinge shaft abutment wall is provided. In addition, a circular opening 115 is provided at the center of the bottom surface.

A cylindrical cable pipe 119 is provided upright on the end face of the hinge shaft 117 on the driven pin 83 side. As described above, the hinge shaft 117 is made of resin, and
19 is formed integrally with the hinge shaft 117. The distal end portion 120 of the cable tube 119 penetrates the bottom surface of the hinge main body 113 at the opening 115, and the distal end portion 1
20 is provided with a circumferential groove 121. A C-shaped retaining ring 122 is attached to the circumferential groove 121.
When the C-shaped retaining ring 122 abuts against the bottom surface of the hinge main body 113, the hinge shaft 117 is positioned so as not to protrude from the hinge main body 113. A cable passage 123 is provided at the center of the hinge shaft 117. The cable passage 123 is provided so as to penetrate the hinge shaft 117 from the shaft mounting boss 124 to the distal end portion 120 of the cable tube 119. This cable passage 12
A cable 125 is passed through 3.

The slide piece 131 has the same configuration as that of the first embodiment, but is provided with a circular opening 133 for passing the cable tube 119 at the center. This opening 13
The inner diameter of 3 is set sufficiently larger than the outer diameter of the cable tube 119.

In addition, although not shown in FIG. 10, the main body case 50 and the flip 52 are also provided with an opening through which the cable 125 passes. It is led to.

Next, the order of assembling the hinge device 111 of this embodiment will be described. Cable tube 11 of hinge shaft 117
9 and the center hole of the slide piece 131 and the hinge spring 91.
In the order. In this state, the hinge shaft 117 is inserted into the hinge main body 113, and the distal end portion 12 of the cable tube 119 is inserted.
0 protrudes from the opening 115 on the bottom surface of the hinge body 113. Then, C is inserted into the circumferential groove 121 of the tip portion 120.
By attaching the die retaining ring 122, the hinge device 1
11 is completed. This hinge device 111 is the same as that of the first embodiment.
In the same manner as described above, the main body case 50 and the flip 52 are assembled. Note that the cable 125 is connected to the cable passage 1
Passing through 23 may be performed at any time in the above assembling step.

The hinge device of this embodiment operates in the same manner as in the first embodiment. According to the present embodiment, it is possible to connect the device of the wireless device main body and the device provided on the flip 52 with the cable 125. Therefore, for example, in a configuration in which a microphone is provided on the flip 52, cable wiring can be easily performed.

[Embodiment 4] FIG. 11 is a sectional view showing the structure of a hinge device 141 of the present embodiment. In the present embodiment, a description of the same configuration as in the first embodiment will be omitted.

In the present embodiment, the hinge main body 143 is formed integrally with the main body case 145 of the radio device main body.
That is, the hinge main body 143 is formed of a column-shaped boss protruding from the wall 149 of the mounting base 147 of the main body case 145 toward the inside of the case. The cylindrical boss-shaped hinge main body 143 is formed with a concave portion 150 having a hollow hexagonal column as in the first embodiment. Recess 1
A spring mounting boss 151 protrudes from the center of the bottom surface of the body 50 toward the inside of the main body.

The hinge shaft 152 is connected to the flip 153
And are formed integrally. That is, the wall portion 155 is formed on the flip 153 so as to face the wall portion 149 of the main body case 145, and the hinge shaft 152 is formed of a columnar boss protruding from the wall portion 155. On the end face of the hinge shaft 152, two driven pins 83 similar to those of the first embodiment are provided.

Next, the order of assembling the hinge device 141 of this embodiment will be described. One end of the hinge spring 91 is attached to the hinge spring attachment boss 151 of the recess 150, and the other end is attached to the hinge spring attachment boss 89 of the slide piece 85. Then, the slide piece 85 and the hinge shaft 152 are sequentially inserted into the recess 150. The flip 153 is positioned in the axial direction by positioning means (not shown).

According to the present embodiment, since the hinge main body 143 and the hinge shaft 152 are integrated with the main body case 145 and the flip 153, respectively, the number of parts is reduced.
The hinge main body 143 may be integrated with the main body case 145, and the hinge shaft 152 may have the configuration of the first embodiment.
Further, the configuration may be reversed.

[0084]

【The invention's effect】

(1) In the hinge device of the present invention, since the hinge body, the hinge shaft, the slide piece and the elastic member are provided, and the cam mechanism is provided between the hinge shaft and the slide piece, the structure is simple and the number of parts is small. it can. Therefore, the size and the cost are reduced, the occurrence of rattling is reduced, and the productivity and the assembling property are improved.

Further, according to the present invention, since the elastic member for applying a spring force to the main body cover is provided so as to urge the slide piece in the axial direction, the conventional leaf spring can be eliminated. . Since the elastic member is not configured to rotate while being pressed against another member as in the case of the conventional leaf spring,
Wear and deformation of other members due to the elastic member can be suppressed, and rattling can be avoided. Again
According to Ming, the proper setting of the cam surface allows open and closed
In the intermediate state between the two, the specified cover opening angle
The cover performs either open or close operation,
Covers such as mobile phones and PHS that do not stop at the location
-Operation is obtained. In particular, in the present invention, the outside of the slide piece
The shape of the surface is a polygonal prism side shape, and the inner surface of the guide part is
By forming so as to engage with the polygonal prism side shape
Simple and easy to manufacture to prevent the rotation of the slide piece
Can reduce manufacturing costs.
It works. (2) According to the present invention, the outer side surface of the hinge main body is
With a pillar side shape, a polygonal pillar-shaped mounting boss is installed on the hinge axis.
The hinge body on one side of the transceiver or body cover.
A hinge body storage section that engages the polygonal
And the other side of the transceiver or body cover
A hinge shaft mounting hole for engaging with the mounting boss of
Therefore, the flip can have a split structure or hinge
There is no need to screw in when assembling the device
Become.

According to the present invention to [0086] of al, in accordance with the adjustment settings of the cam surface, depending on the opening angle of the cover, since the body cover operation or closing operation to open, desired in the body cover at one type of cam Can be easily performed.

[0087] Also in the present invention, by using a coil spring as the elastic member, it is possible to reduce the difference between the design calculation value and the actual ability value, also it is possible to suppress the variation in quality, performance of the hinge device Can be improved.

[0088] Also in the present invention, by providing in parallel a plurality of coil springs as the elastic member, it is possible to shorten the length of the spring, further it is possible to miniaturize the hinge device.

[0089]

[0090] Also in the present invention, the follower, by the follower pin projecting from the end face of the hinge axis or slide piece, the frictional resistance of the follower pin and the cam surface is reduced,
Resistance when opening and closing the body cover can be reduced.

[0091] Also in the present invention, by providing the cable passage hinge axis, can be guided the cable between the radio device body and the body cover, the case of providing the electrical apparatus or the like to the main body cover wiring, etc. Becomes easier.

[0092] Also in the present invention, at least one of the hinge body or the hinge axis, by providing integrally with the radio body or body cover, the manufacturing cost reduced number of parts, and because the assembly work is facilitated Is reduced.

[Brief description of the drawings]

FIG. 1 is a perspective view of a portable wireless device including a hinge device according to a first embodiment of the present invention.

FIG. 2 is a partial cross-sectional view of a portable wireless device including the hinge device according to the first embodiment of the present invention.

FIG. 3 is a cross-sectional view of the hinge device according to the first embodiment of the present invention when viewed from a direction perpendicular to FIG. 2;

FIG. 4 is a plan view, a front view, and a bottom view of a hinge shaft.

FIG. 5 is a plan view, a front view, and a bottom view of the slide piece.

FIG. 6 is an explanatory view showing a cam shape of an end face cam provided on an end face of a slide piece.

FIG. 7 is an explanatory diagram showing a positional relationship between a cam and a driven pin when the hinge device of FIG. 2 operates.

FIG. 8 is an explanatory diagram showing shapes of a hinge shaft and a slide piece according to a modification of the first embodiment.

FIG. 9 is a sectional view of a hinge device according to a second embodiment of the present invention.

FIG. 10 is a sectional view of a hinge device according to a third embodiment of the present invention.

FIG. 11 is a sectional view of a hinge device according to a fourth embodiment of the present invention.

FIG. 12 is a cross-sectional view showing a state in which a conventional hinge device is attached to a portable wireless device.

FIG. 13 is a side view showing a configuration of a conventional hinge device.

FIG. 14 is a sectional view of a cam portion showing a cam shape of a conventional hinge device.

FIG. 15 is an explanatory diagram showing a positional relationship between a cam portion and a leaf spring during operation of a conventional hinge device.

[Explanation of symbols]

50 body case, 51 mounting base, 52 flip, 5
3 Hinge device, 63 hinge body, 65 hinge body cylinder, 67 bottom plate, 77 hinge shaft, 79 shaft portion, 81
Shaft mounting boss, 83 Follower pin, 85 Slide piece, 8
9 Spring mounting boss, 91 hinge spring, 93 end face cam.

Claims (9)

(57) [Claims] 1. A hinge device for a portable wireless device which pivotally supports a main body cover so as to be openable and closable with respect to a radio device main body. A hinge shaft non-rotatably provided on the other of the main body cover or the wireless device main body and rotatably supported on the hinge main body; and a slide piece provided slidably in the hinge main body in the axial direction. And an elastic member provided on the hinge main body and for urging the slide piece in the axial direction to make contact with the hinge shaft. A cam part is provided on one of the two contact portions of the hinge shaft or the slide piece. However, the other driven portion is provided, and the cam portion is configured to transmit the urging force of the elastic member to the hinge shaft so that the main body cover is held in the open state and / or the closed state. The cam surface has a minimum cam height at a position corresponding to the open state of the main body cover, and is intermediate between the open state and the closed state from a position corresponding to the open state. The cam height increases toward a position corresponding to the predetermined cover opening angle, reaches a cam apex where the cam height becomes highest at a position corresponding to the predetermined cover opening angle, and the closed state from the cam apex. The height of the cam is set so as to decrease toward a position corresponding to the hinge body . Further, the hinge main body is a guide into which the slide piece is inserted.
The slide piece has a polygonal prism side surface
And the inner surface of the guide portion is the polygonal prism side shape.
Is formed so as to engage with the outer surface of the slide piece.
When the inner surface of the guide portion is engaged,
A hinge device for a portable wireless device , wherein rotation of a do-piece is suppressed . 2. A hinge device for a portable wireless device which pivotally supports a main body cover so as to be openable and closable with respect to a radio device main body, wherein: A hinge shaft non-rotatably provided on the other of the main body cover or the wireless device main body and rotatably supported on the hinge main body; and a slide piece provided slidably in the hinge main body in the axial direction. And an elastic member provided on the hinge main body and for urging the slide piece in the axial direction to make contact with the hinge shaft. A cam part is provided on one of the two contact portions of the hinge shaft or the slide piece. However, a driven portion is provided, and the cam portion is configured to transmit the urging force of the elastic member to the hinge shaft so that the main body cover is held in the open state and / or the closed state. The cam surface has a minimum cam height at a position corresponding to the open state of the main body cover, and is located between the open state and the closed state from a position corresponding to the open state. The cam height increases toward a position corresponding to the predetermined cover opening angle, reaches a cam apex where the cam height becomes the highest at a position corresponding to the predetermined cover opening angle, and the closed state from the cam apex. The height of the cam is set so as to decrease toward the position corresponding to the above , and further, the outer side surface of the hinge body is formed into a polygonal prism side surface, and a polygonal column-shaped mounting boss is provided on the hinge shaft. , One of the radio body or the body cover,
Hinge body engaging with said polygonal prism side shape of hinge body
A storage section is provided, and the other side of the wireless device main body or the main body cover includes the
A hinge shaft mounting hole for engaging with the mounting boss of the hinge shaft is provided.
Portable radio of the hinge and wherein the digit. 3. The cam surface further moves from a position where the cam height corresponding to the open state is lowest to a direction in which the main body cover is further opened, and the cam height is increased in accordance with an increase in the cover opening angle. 3. The hinge device for a portable wireless device according to claim 1, wherein the hinge device is inclined so as to increase. Wherein said elastic member is attached at one end to said hinge main body, a mobile according to any one of claims 1-3, characterized in that the other end is a coil spring mounted to the slide piece Hinge device for radio equipment. 5. The hinge device for a portable wireless device according to claim 4 , wherein a plurality of said coil springs are provided in parallel. 6. The hinge device according to claim 1, wherein the driven portion is a driven pin protruding from an end surface of the hinge shaft or the slide piece. 7. The portable wireless device according to claim 1, wherein the hinge shaft has a cable passage for passing a cable connecting the wireless device main body and the main body cover. Machine hinge device. 8. The wireless communication device according to claim 1, wherein at least one of the hinge body and the hinge shaft is provided integrally with the wireless device body or the body cover.
A hinge device for a portable wireless device according to any one of the above. 9. The cam surface is provided with two cam vertices opposed to each other with the hinge axis center interposed therebetween, and the cam surface is set symmetrically with respect to a line connecting these two cam vertices. The hinge device for a portable wireless device according to claim 1, wherein: