JP2012014546A - Electronic equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide electronic equipment having excellent operability when a second housing is rotationally moved to a first housing, and capable of reducing impact to the first housing by the second housing.SOLUTION: Electronic equipment comprises: a rotational movement guide member 7 that connects a second housing 2 to a first housing, rotatably to a laterally-directed state and to a vertically-directed state; and a brake unit 10 provided at the rotational movement guide member 7 and configured to brake rotational movement of the second housing to the first housing. Accordingly, the second housing 2 can start moving smoothly when the second housing 2 is rotationally moved toward the first housing 1. Furthermore, when the second housing 2 rotationally moved and stopped, halfway through the rotational movement of the second housing 2, the brake unit 10 brakes the rotational movement of the second housing 2 so that the second housing 2 can be rotationally moved in slow movement and then stopped.

Description

  The present invention relates to a display device such as a photo frame type, and an electronic device such as a personal computer and a mobile phone, and more particularly to an electronic device having a mechanism for rotating a display screen vertically and horizontally.

  Conventionally, in an electronic device such as a mobile phone, as described in Patent Document 1, a first casing, a second casing having a display unit, and the second casing are connected to the first casing. A rotationally-moving guide member that is rotatably connected to the housing in a lateral state and a vertical state, and urges the second housing so that the second housing is in a lateral state and a vertical state. The thing of the structure provided with the torsion coil spring to perform is known.

JP 2008-86039 A

  In such an electronic device, when the second casing is in the sideways state with respect to the first casing, the second casing is biased to be in the sideways state by the spring force of the torsion coil spring. When the second housing starts to rotate from the horizontal state to the vertical state when the second housing rotates from the horizontal state, the spring force of the torsion coil spring gradually increases.

  When the second casing rotates and reaches the vicinity of the intermediate position, the spring force of the torsion coil spring becomes the strongest, and when the second casing further rotates in this state, the second casing is further turned vertically. The urging direction by the torsion coil spring is reversed, and the spring force of the torsion coil spring is gradually weakened. For this reason, the second housing is biased so as to be in the vertical state with a weak spring force.

  In this electronic device, when the second casing is rotated from the vertical state to the horizontal state with respect to the first casing, the second casing starts to rotate from the vertical state. When the spring force of the torsion coil spring gradually increases and the second casing rotates to reach the vicinity of the intermediate position, the spring force of the torsion coil spring becomes the strongest. Then, when the second casing is further rotated so as to be in the lateral direction, the urging direction by the torsion coil spring is reversed, and the spring force of the torsion coil spring is gradually weakened. For this reason, the second housing is biased to be in a lateral state with a weak spring force.

  However, in such a conventional electronic device, when the second casing rotates relative to the first casing, the spring force of the torsion coil spring becomes strongest during the rotational movement. Therefore, the torsion coil spring not only allows the second housing to be smoothly rotated and moved, but also the torsion coil spring causes the second housing to be in the horizontal state and the vertical state. Since it is energized, when the second casing is rotated and moved from the landscape orientation to the portrait orientation, and when the second chassis is rotated from the portrait orientation to the landscape orientation, the movement of the second enclosure becomes heavy, There is a problem that the second casing cannot be smoothly rotated.

  In addition, when such an electronic device is used in, for example, a personal computer and the first casing is placed on a table and used with the second casing upright, the second casing is When rotationally moving from the orientation state to the lateral state, the rotation of the second housing is accelerated by the rotational moment and gravity due to the weight of the second housing, and an acceleration is generated in the second housing. And the spring force of the torsion coil spring cause the second housing to rotate vigorously and enter a lateral state, and therefore an impact is applied to the second housing, and the electrons incorporated into the second housing by this impact. There is also a problem that parts are damaged or abnormal sounds such as impact sounds are generated.

  The problem to be solved by the present invention is that the operability when rotating the second casing relative to the first casing is good, and the impact of the second casing on the first casing is reduced. It is to provide an electronic device that can be used.

In order to solve the above problems, the present invention includes the following components.
According to the first aspect of the present invention, the first housing, the second housing, and the second housing can be rotated and moved between the horizontal state and the vertical state with respect to the first housing. A rotation movement guide member coupled to the rotation movement guide member, and a braking portion that is provided on the rotation movement guide member and brakes by changing the rotation movement of the second case relative to the first case. It is a featured electronic device.

  According to a second aspect of the present invention, in the electronic device according to the first aspect, the rotational movement guide member is configured such that the second housing rotates when the second housing rotates relative to the first housing. A first rotational movement guide portion that regulates the vertical movement of the second casing; and the first casing when the second casing rotates relative to the first casing. A second rotational movement guide portion that regulates lateral movement of the second casing relative to the first casing, and the braking portion is provided on the second rotational movement guide portion and is arranged relative to the first casing. The electronic apparatus is characterized in that braking is performed by changing the rotational movement of the second casing.

  According to a third aspect of the present invention, in the electronic device according to the second aspect, the first rotational movement guide portion is provided on a movable plate provided on the second casing and on the movable plate. A first movable shaft, a base plate provided on the first housing, and a first guide groove provided on the base plate for guiding the first movable shaft, and the second rotation. The movement guide portion includes a second movable shaft provided on the movable plate, and a second guide groove portion provided on the base plate for guiding the second movable shaft, wherein the first movable shaft is The second housing is attached to the first guide groove so as to be rotatable and the second movable shaft is attached to the second guide groove so as to be able to rotate. Rotating to connect to An electronic device characterized by and.

  According to a fourth aspect of the present invention, in the electronic device according to the second or third aspect, the first guide groove portion that guides the first movable shaft in the first rotational movement guide portion includes: In order to restrict the vertical movement of the second casing, the second casing is formed in a substantially circular arc shape that curves upward along the lateral direction of the base plate, and the second rotational movement guide section includes the second The second guide groove portion that guides the movable shaft of the second housing with respect to the first housing when the second housing rotates relative to the first housing. In order to restrict lateral movement, the electronic device is formed along the vertical direction of the base plate.

  According to a fifth aspect of the present invention, in the electronic device according to the third or fourth aspect, the braking unit is configured to move the second housing with a rotational movement of the second housing with respect to the first housing. An electronic apparatus provided in a part of the second guide groove portion for guiding the two movable shafts in the vertical direction, and changing the moving direction in the vertical direction of the second movable shaft in a different direction. It is.

  According to a sixth aspect of the present invention, in the electronic device according to the fifth aspect of the invention, the braking portion bends the substantially middle portion in the vertical direction of the second guide groove portion to the first casing. In the electronic device, the moving direction of the second movable shaft is gradually changed with the rotational movement of the second casing.

  According to a seventh aspect of the present invention, in the electronic device according to any one of the first to sixth aspects, when the second casing is in a horizontal state, the second casing is in a vertical state. And urging toward the direction of causing the second casing to be in the horizontal orientation when the second casing is in the vertical orientation, and the second casing is An electronic device comprising a biasing member that rotates and moves to a neutral state when tilted at an approximately middle position and minimizes the biasing force to the second housing. .

  According to the present invention, when the second casing is rotated and moved with respect to the first casing, the second casing can be moved smoothly, and the second casing can be moved. Even if the second casing is accelerated by the inertial force, the rotation speed of the second casing can be reduced by the braking unit. For this reason, the rotational operability of the second casing relative to the first casing is good, and the impact of the second casing on the first casing accompanying the rotational movement of the second casing can be reduced. Thus, it is easy to use, and it is possible to prevent an electronic component incorporated in the second housing from being damaged by an impact, and also to prevent an abnormal sound such as an impact sound.

It is the front view which showed one Embodiment of the electronic device to which this invention is applied. FIG. 2 is an enlarged side view in which a part of the electronic device shown in FIG. 1 is cut away. FIG. 3 is an enlarged perspective view showing the electronic device in an exploded state when viewed from the back side when the second housing of the electronic device shown in FIG. 1 is in the horizontal state. FIG. 4 is an enlarged front view of a main part of the electronic device shown in FIG. 3 as seen through the electronic device from the front side when the second housing of the electronic device is in the horizontal state. It is the figure which showed the positional relationship of the principal part when seeing the principal part in the electronic device shown by FIG. 1 through the front side. FIG. 3 is a front view of the electronic device shown in FIG. 1 when a second housing is in a vertical orientation. It is the figure which showed the positional relationship of the principal part when the principal part in the electronic device shown by FIG. 6 was seen through from the front side. In the neutral state in which the second casing of the electronic device shown in FIG. 1 is rotated by approximately 60 degrees and tilted obliquely at approximately the middle position, the main part is viewed through the front side. It is the figure which showed the positional relationship. FIG. 1 shows the positional relationship of the main part when the second part of the electronic device shown in FIG. 1 is rotated from the sideways state and tilted slightly obliquely when viewed through the front part from the front side. It is a figure. When the second casing of the electronic device shown in FIG. 9 further rotates and approaches a neutral state inclined obliquely at an approximately intermediate position, the main part is seen through the front side from the front side. It is the figure which showed these positional relationships.

An embodiment of an electronic apparatus to which the present invention is applied will be described below with reference to FIGS.
As shown in FIGS. 1 and 2, this electronic apparatus is a photo frame type display device including a first housing 1 and a second housing 2. The first housing 1 includes a pedestal portion 3 placed on a placement surface such as a tabletop, and a support case portion 4 provided upright on the pedestal portion 3. The second housing 2 includes a rectangular case portion 5 and an input display portion 6 that is incorporated in the case portion 5 and exposed to the front side (left side in FIG. 2).

  Although not shown, the input display unit 6 displays information such as an image and performs a touch operation while viewing the displayed information, and has a configuration in which a transparent touch panel and a display panel are stacked. The display panel is a flat display panel such as a liquid crystal display panel or an EL (electroluminescence) display panel, and is configured to display various information electro-optically. A transparent touch panel is provided on the surface of the display panel and performs touch processing while viewing information displayed on the display panel, so that image processing such as selection of images displayed on the display panel and enlargement / reduction of the images can be performed. Is configured to do.

  By the way, as shown in FIG. 1 and FIG. 2, the electronic device is in a sideways state in a state where the case portion 5 of the second housing 2 is raised with respect to the support case portion 4 of the first housing 1. And a rotational movement guide member 7 that is rotatably connected to the vertical direction, and a biasing member 8 that imparts a biasing force to the second housing 2 in the rotational direction. In this case, the horizontal state of the second housing 2 is a state in which the input display unit 6 displays information in a horizontal state in a state in which the input display unit 6 is long in the horizontal direction. Is a state in which the input display unit 6 displays information vertically in a state that is long in the vertical direction.

  As shown in FIGS. 1 to 4, the rotational movement guide member 7 moves in the vertical direction of the second housing 2 when the second housing 2 rotates relative to the first housing 1. When the second rotation guide part 11 that regulates the rotation of the second casing 2 and the second casing 2 rotate relative to the first casing 1, the side of the second casing 2 with respect to the first casing 1 A second rotational movement guide portion 12 that restricts the movement in the direction, and a brake provided by changing the rotational movement of the second housing 2 relative to the first housing 1 provided in the second rotational movement guide portion 12 And a braking unit 10 for performing the above operation.

  As shown in FIGS. 3 and 4, the first rotational movement guide portion 11 includes a movable plate 13 provided in the case portion 5 of the second casing 2 and a first plate provided in the movable plate 13. A movable shaft 14, a base plate 15 provided on the support case 4 of the first housing 1, and a first plate provided on the base plate 15 for guiding the first movable shaft 14 so as to be slidable and rotatable. The guide groove portion 16 is provided.

  Further, as shown in FIGS. 3 and 4, the second rotational movement guide portion 12 includes a movable plate 13 provided in the case portion 5 of the second housing 2 and a second plate provided in the movable plate 13. Two movable shafts 17, a base plate 15 provided on the support case 4 of the first housing 1, and a second movable shaft 17 provided on the base plate 15 to guide the second movable shaft 17 so as to be slidable and rotatable. And a second guide groove 18.

  In this case, as shown in FIG. 3, the first movable shaft 14 of the first rotational movement guide portion 11 has a pair of ring portions 14a that slidably sandwich the edge portion of the first guide groove portion 16 of the base plate 15. , 14b, and a pair of ring portions 14a, 14b, which are rotatably attached via washers 14c, and mounting pins 14d attached to the movable plate 13.

  Further, as shown in FIG. 3, the second movable shaft 17 of the second rotational movement guide portion 12 is inserted into the second guide groove portion 15 of the base plate 15 and attached to the movable plate 13. The cylindrical shaft 17a is attached to the cylindrical shaft 17a with a flange portion 17b provided at one end of the cylindrical shaft 17a for pulling the edge of the base plate 15 toward the movable plate 13 and an edge of the second guide groove 18 slidably. A pair of ring portions 17c and 17d and a washer 17e disposed between the ring portion 17c pressed by the flange portion 17b and the base plate 15 are provided.

  Accordingly, as shown in FIGS. 2 to 4, the rotational movement guide member 7 is attached to the first guide groove 16 so that the first movable shaft 14 of the first rotational movement guide 11 can be rotationally moved. The second movable shaft 17 of the second rotational movement guide portion 12 is attached to the second guide groove portion 18 so as to be capable of rotational movement, whereby the second housing 2 is moved relative to the first housing 1. And are connected so as to be rotatable.

  In this case, the movable plate 13 is made of a metal plate such as stainless steel, and as shown in FIGS. 2 and 3, the movable plate 13 is substantially at the center of the back surface (right side surface in FIG. 2) of the case portion 5 in the second housing 2. It is attached in an embedded state. Further, as shown in FIGS. 3 and 4, the first movable shaft 14 in the first rotational movement guide portion 11 is positioned at the lower left portion of the movable plate 13 when the second housing 2 is in the horizontal state. It is provided upright at the place to be. The second movable shaft 17 in the second rotational movement guide unit 12 stands up at a position located on the upper right side of the first movable shaft 14 in the movable plate 13 when the second housing 2 is in the horizontal state. Is provided.

  The base plate 15 is made of a metal plate such as stainless steel, and as shown in FIGS. 2 and 3, supports the first housing 1 facing the back surface (right side surface in FIG. 2) of the second housing 2. The case portion 4 is attached in a state where it is embedded in substantially the center of the front surface (left side surface in FIG. 2). As shown in FIGS. 3 and 4, the first guide groove portion 16 in the first rotational movement guide portion 11 guides the first movable shaft 14 with the rotational movement of the second housing 2. In the lower part of the base plate 15, the base plate 15 is formed in a substantially arc shape that is curved so as to protrude upward along the lateral direction (left and right direction in FIG. 4).

  In this case, as shown in FIGS. 3 and 4, the first guide groove portion 16 has the first movable shaft 14 at the left end portion of the first guide groove portion 16 when the second housing 2 is in the horizontal state. As shown in FIGS. 6 and 7, the first movable shaft 14 is positioned at the right end 16 b of the first guide groove 16 when the second housing 2 is in the vertical state. Is formed. For this reason, the first guide groove portion 16 includes a lower side portion when the second housing 2 is in the horizontal state as shown by a solid line in FIG. 1 and a second side portion as shown by a two-dot chain line in FIG. The left end portion 16a of the first guide groove portion 16 is formed at a position lower than the right end portion 16b so that the lower side portion when the casing 2 of the first housing 2 is in the vertical orientation is substantially in the same position.

  Further, as shown in FIGS. 5 and 7, the first guide groove portion 16 is shown in FIGS. 9 and 10 when the second housing 2 rotates and moves from the horizontal state to the vertical state. As shown, the first movable shaft 14 is configured to move gradually from the left end 16a of the first guide groove 16 toward the upper left side. Further, as shown in FIG. 8, the first guide groove portion 16 is in a neutral state when the second casing 2 is rotated by approximately 60 degrees and is inclined obliquely at an approximately intermediate position. The movable shaft 14 is configured to move to the highest position in the middle of the first guide groove 16.

  Further, as shown in FIG. 8, the first guide groove portion 16 is directed in a direction from the neutral state in which the second casing 2 is rotated approximately 60 degrees and inclined obliquely at an approximately intermediate position to the vertical state. The first movable shaft 14 is configured to gradually move toward the lower right side along the first guide groove portion 16 when rotating. In addition, as shown in FIG. 7, the first guide shaft 16 has the first movable shaft 14 that is in the first position when the second housing 2 is rotated 90 degrees from the horizontal position to the vertical position. It is configured to move to the right end portion 16 b of the one guide groove portion 16.

  Thereby, as shown in FIGS. 1 and 5, the first guide groove 16 is moved when the second housing 2 is rotated from the horizontal state to the vertical state, or when the second housing 2 is vertical. When rotating from the state to the sideways state, the position located at the lower portion of the second housing 2 is configured to move on a substantially linear housing movement trajectory K with little fluctuation in the vertical direction. Has been. That is, as shown in FIG. 1 and FIG. 6, the housing movement locus K draws an almost straight line in which the middle portion is slightly lowered and is almost curved, that is, an almost circular arc having a very large curvature radius. It is configured.

  On the other hand, the second guide groove portion 18 in the second rotational movement guide portion 12 guides the second movable shaft 17 with the rotational movement of the second housing 2 as shown in FIGS. 3 and 4. The base plate 15 is formed on the upper side of the first guide groove 16 on the base plate 15 from the lower part to the upper part. That is, as shown in FIG. 4, the second guide groove portion 18 is formed in a state in which it is slightly inclined in the vertical direction along a normal line orthogonal to the tangent at the substantially middle portion of the first guide groove portion 16. .

  As shown in FIGS. 3 and 4, the second guide groove portion 18 has the second movable shaft 17 positioned at the lower end portion 18 a when the second housing 2 is in the horizontal state, and the second housing groove 18. When the body 2 is in the vertical state, as shown in FIGS. 6 and 7, the second movable shaft 17 is positioned slightly above the lower end portion 18a, and the second casing 2 is rotated by approximately 60 degrees. As shown in FIG. 8, the second movable shaft 17 is formed so as to be closest to the upper end portion 18 b of the second guide groove portion 18 in a neutral state that is inclined obliquely at a substantially intermediate position.

  That is, when the second casing 2 rotates and moves from the horizontal state to the vertical state, as shown in FIG. When the second housing 2 is rotated by about 60 degrees and tilted obliquely at an approximately middle position as shown in FIG. 8, gradually moving upward from the lower end portion 18 a of the guide groove portion 18. Further, the second movable shaft 17 is formed so as to be closest to the upper end portion 18 b of the second guide groove portion 18.

  In addition, the second guide groove 18 is rotated when the second housing 2 is rotated so that the neutral state in which the second casing 2 is rotated approximately 60 degrees and inclined obliquely at an approximately intermediate position is further shifted to the vertical state. 7 and FIG. 8, the second movable shaft 17 gradually moves downward from the upper end portion 18b of the second guide groove portion 18, and as shown in FIG. The second movable shaft 17 is formed so as to be closest to the lower end portion 18a of the second guide groove portion 18 when is in a vertically oriented state.

  Similarly, when the second guide groove 18 rotates and moves from the vertically oriented state to the horizontally oriented state, the second movable shaft 17 has a lower end of the second guide groove 18 as shown in FIG. As shown in FIG. 8, when the second casing 2 is in a neutral state inclined obliquely at a substantially intermediate position, the second movable shaft 17 is moved to the second portion 18a. The guide groove 18 is formed so as to be closest to the upper end 18b.

Further, the second guide groove portion 18 is rotated when the second housing 2 is rotated so as to be further laterally moved from the neutral state inclined obliquely at a substantially intermediate position.
As shown in FIG. 5, the second movable shaft 17 gradually moves downward from the upper end portion 18 b of the second guide groove portion 18, and as shown in FIG. The second movable shaft 17 is formed so as to be positioned at the lower end portion 18 a of the second guide groove portion 18.

  Thereby, as shown in FIGS. 1 and 6, the second guide groove portion 18 is moved when the second housing 2 rotates and moves from the horizontal state to the vertical state, or when the second housing 2 is in the vertical direction. By restricting the movement of the second casing 2 in the horizontal direction (left-right direction in FIG. 1) when rotating from the state to the sideways state, The casing 2 is configured to guide the rotational movement.

  By the way, as shown in FIGS. 3 and 4, the second guide groove portion 18 includes a second guide groove portion 18 when the second housing 2 rotates relative to the first housing 1. A control unit 10 is provided for braking the movement of the second movable shaft 17 by changing the moving direction of the second movable shaft 17 that moves along the axis. That is, the control unit 10 is a bent portion that is provided in a substantially S-shaped curved portion at an intermediate portion in the vertical direction of the second guide groove portion 18, and moves along the second guide groove portion 18. The moving direction in the vertical direction of the movable shaft 17 is changed to a different direction (the left-right direction in FIG. 4).

  As a result, as shown in FIGS. 3 and 4, the braking unit 10 is configured so that when the second movable shaft 17 moves in the vertical direction along the second guide groove portion 18, the second movable shaft 17 is perpendicular to the second movable shaft 17. The direction vector is changed in an oblique direction to be dispersed into a left-right direction vector component and an up-down direction vector component, and the moving speed in the up-down direction of the second movable shaft 17 is reduced. Further, when the second movable shaft 17 moves in the vertical direction along the second guide groove portion 18, the braking portion 10 bends the second movable shaft 17 at an intermediate portion of the second guide groove portion. By moving, the moving direction of the second movable shaft 17 is gradually changed.

  In this case, as shown in FIGS. 8 to 10, when the second guide groove 18 approaches the neutral state in which the second housing 2 starts rotating from the sideways state and is inclined obliquely at the substantially intermediate position. Further, when the second movable shaft 17 gradually moves upward from the lower end portion 18 a of the second guide groove portion 18, the second movable shaft 17 is provided in the intermediate portion of the second guide groove portion 18. Thus, the second movable shaft 17 is configured to approach the upper end portion 18b of the second guide groove portion 18 after being bent and moved in an oblique lateral direction (obliquely upper right direction in FIG. 10).

  Further, the second guide groove portion 18 is rotated when the second casing 2 is further rotated from the neutral state inclined obliquely at the substantially intermediate position where the second casing 2 is rotated by approximately 60 degrees to the vertical state as shown in FIGS. As shown in FIG. 8, when the second movable shaft 17 gradually moves downward from the upper end portion 18 b of the second guide groove portion 18, the second movable shaft 17 is provided in the intermediate portion of the second guide groove portion 18. The second movable shaft 17 approaches the lower end portion 18a of the second guide groove 18 as shown in FIG. 7 after the controller 10 is bent and moved in the oblique lateral direction (obliquely rightward in FIG. 8). Is configured to do.

  Similarly, the second guide groove portion 18 starts rotating and moving in a direction in which the second casing 2 changes from the vertical state to the horizontal state and approaches a neutral state inclined obliquely at a substantially intermediate position. As shown in FIGS. 7 and 8, when the second movable shaft 17 gradually moves upward from the lower end portion 18 a of the second guide groove portion 18, the second movable shaft 17 is intermediate between the second guide groove portions 18. The second movable shaft 17 is configured to approach the upper end portion 18b of the second guide groove portion 18 after being bent and moved obliquely in the lateral direction by the control unit 10 provided in the portion.

  Further, the second guide groove portion 18 is, as shown in FIGS. 9 and 10, when the second housing 2 further rotates from the neutral state inclined obliquely at the substantially intermediate position to the lateral state, as shown in FIGS. When the second movable shaft 17 gradually moves downward from the upper end portion 18 b of the second guide groove portion 18, the second movable shaft 17 is moved by the control unit 10 provided in the intermediate portion of the second guide groove portion 18. The second movable shaft 17 is configured to be positioned at the lower end portion 18a of the second guide groove portion 18 as shown in FIG.

  By the way, as shown in FIGS. 3 to 5, the urging member 8 that applies the urging force to the second casing 2 is configured to vertically move the second casing 2 when the second casing 2 is in the horizontal state. While urging toward the direction in which the second housing 2 is in the vertical state, the second housing 2 is biased in the lateral direction when the second housing 2 is in the vertical state, as shown in FIG. In addition, as shown in FIG. 8, when the second casing 2 is rotated and rotated approximately 60 degrees and is in a neutral state inclined obliquely at an approximately intermediate position, the urging force against the second casing 2 is increased. It is configured to be minimal.

  That is, the urging member 8 includes a pair of coil springs 20 and 21 as shown in FIGS. One coil spring 20 has one end attached to the ring portion 17 d of the second movable shaft 17 of the second housing 2, and the other end of the second coil groove 20 in the base plate 15 of the first housing 1. 18 is attached to a first fixing portion 15a located on the left side near the middle portion.

  Moreover, as shown in FIGS. 3-5, the other coil spring 21 is attached to the ring part 17d in the 2nd movable shaft 17 of the 2nd housing | casing 2, and the other end part is 1st. The base plate 15 of the housing 1 is attached to the second fixing portion 15b located on the right side near the middle portion of the second guide groove portion 18.

  When the length of the pair of coil springs 20 and 21 is the longest, the spring force in the tensile direction is the strongest, and conversely, the spring force in the tensile direction is when the length is contracted the shortest. Are each configured to be weakest. As a result, the pair of coil springs 20 and 21 are in a state where the second movable shaft 17 is positioned at the lower end portion 18a of the second guide groove 18 as shown in FIGS. When the housing 2 is in the horizontal state and when the second housing 2 is in the vertical state, each extends the longest and moves the second movable shaft 17 toward the upper side of the second guide groove portion 18. In addition, the spring force is configured to work most strongly.

  Further, as shown in FIG. 8, the coil springs 20 and 21 are in a state where the second movable shaft 17 is positioned at the upper end portion 18b of the second guide groove portion 18, that is, the second casing 2 is oriented sideways. When the neutral state is rotated approximately 60 degrees from the state and tilted obliquely at approximately the middle position, the length is the shortest and the spring force is the weakest, and in any rotation direction of the second casing 2 The second housing 2 is configured to be in a freely rotatable state without acting (not energized).

Next, the operation of this electronic device will be described.
In this electronic apparatus, when the second casing 2 is in the horizontal direction with respect to the first casing 1, the first casing 1 and the second casing 2 are connected as shown in FIGS. 4 and 5. The first movable shaft 14 of the movable plate 13 provided in the second casing 2 in the first rotational movement guide portion 11 of the rotational movement guide member 7 to be connected is the base plate provided in the first casing 1. It is located at the left end portion 16 a of the 15 first guide groove portions 16.

  Further, the second movable shaft 17 of the movable plate 13 in the second rotational movement guide portion 12 is located at the lower end portion 18 a of the second guide groove portion 18 of the base plate 15. In this state, the pair of coil springs 20 and 21 of the urging member 8 are stretched most and the spring force is exerted (biased) in the direction of pulling up the second movable shaft 17. Thereby, the 2nd housing | casing 2 is urged | biased in the direction which becomes a vertical state by each spring force of a pair of coil springs 20 and 21. As shown in FIG.

  In this state, when the second housing 2 is rotated in the direction from the horizontal state to the vertical state, the second casing 2 is moved by the spring force of the pair of coil springs 20 and 21 of the urging member 8. The housing 2 can be rotated and moved with a light force. That is, when the second casing 2 is in the sideways state, the center of gravity G of the second casing 2 is the lowest and the rotational moment due to the weight of the second casing 2 is large. When rotationally moving in the direction from the landscape orientation to the portrait orientation, the load for rotationally moving the second housing 2 increases.

  However, at this time, depending on the weight of the second casing 2, the spring force of the pair of coil springs 20 and 21 of the biasing member 8 biased in the direction of causing the second casing 2 to be in the vertical orientation. Since the load is canceled out, the second casing 2 can be rotated and moved with a light force. For this reason, even when the weight of the second housing 2 is heavy and the weight of the first housing 1 is light, when the second housing 2 is rotated in the direction from the horizontal state to the vertical state, Since the first casing 1 does not float with the rotational movement of the second casing 2, it is not necessary to hold the first casing 1 by hand, and the second casing 2 is rotated well. be able to.

  Then, when the second housing 2 starts to rotate in the direction from the horizontal state to the vertical state, the first movable shaft 14 of the movable plate 13 is moved to the first position of the base plate 15 as shown in FIGS. While moving along one guide groove 16, the second movable shaft 17 of the movable plate 13 moves along the second guide groove 18 of the base plate 15. At this time, the first movable shaft 14 moves while gradually rotating from the left end portion 16 a of the first guide groove portion 16 toward the upper right side, and the second movable shaft 17 is moved to the lower end of the second guide groove portion 18. It moves while rotating upward from the portion 18a.

  For this reason, the second housing 2 rotates counterclockwise in FIGS. 9 and 10 with respect to the first housing 1. At this time, as shown in FIG. 10, the first movable shaft 14 gradually rotates and moves toward the upper right side along the first guide groove portion 16, so that the portion located at the lower portion of the second housing 2. Moves on a substantially linear housing movement locus K shown in FIG.

  In addition, when the second casing 2 rotates in this manner, as shown in FIGS. 9 and 10, the pair of coil springs of the urging member 8 is accompanied by the rotational movement of the first movable shaft 14. 20 and 21 are gradually contracted and shortened, and the spring force in the direction for causing the second housing 2 to be in the vertical orientation is gradually weakened. At this time, the second movable shaft 17 moves upward while being bent and moved by the braking portion 10 provided in the second guide groove portion 18.

  That is, when the second movable shaft 17 is curved and moved by the control unit 10, as shown in FIGS. 9 and 10, the moving direction of the second movable shaft 17 gradually increases along the curve of the control unit 10. Changes, the vertical vector of the second movable shaft 17 changes to a diagonal vector, and is distributed to the left and right vector components and the vertical vector component, and moves above the second movable shaft 17. The speed to do is decelerated. For this reason, the second casing 2 rotates and moves slowly.

  Then, when the second casing 2 is rotated by approximately 60 degrees and rotated obliquely at a substantially intermediate position, as shown in FIG. 8, the neutral state is established, and the first movable shaft 14 is moved to the first position. The second movable shaft 17 moves toward the upper end portion 18b of the second guide groove portion 18 and comes closest to the highest position located approximately in the middle of the guide groove portion 16. For this reason, the second housing 2 is inclined with respect to the first housing 1 as shown in FIG.

  At this time, since the first movable shaft 14 rotates and moves to the highest position of the first guide groove portion 16, the center of gravity G of the second housing 2 becomes the highest and the lower portion of the second housing 2 1 is located on the lowermost side, but the lower part moves on a substantially linear housing movement locus K shown in FIG.

  Further, when the second casing 2 is rotated approximately 60 degrees and rotated to a neutral state inclined at an approximately intermediate position in this way, as shown in FIG. Along with the rotational movement, the pair of coil springs 20 and 21 of the urging member 8 are contracted and shortened most, and each spring force is weakened accordingly. Thereby, in the neutral state, each spring force of the pair of coil springs 20, 21 does not work (does not urge) in any rotation direction of the second housing 2.

  After this, when the second casing 2 further rotates and passes through the neutral state, the first movable shaft 14 moves along the first guide groove 16 on the lower right side as shown in FIG. The second movable shaft 17 moves downward from the upper end portion 18b of the second guide groove portion 18 while moving while gradually rotating toward the bottom. For this reason, the second housing 2 rotates counterclockwise in FIG. 8 with respect to the first housing 1 and approaches the vertical orientation.

  At this time, the first movable shaft 14 gradually rotates and moves toward the lower right side along the first guide groove portion 16, so that the gravity center position G of the second housing 2 is slightly lowered from the highest position. The portion located at the lower part of the second casing 2 moves on the substantially linear casing movement locus K shown in FIGS. 1 and 5 with almost no fluctuation in the vertical direction.

  Further, when the second casing 2 rotates in this manner, as shown in FIG. 7, the pair of coil springs 20, 21 of the urging member 8 is accompanied by the rotational movement of the first movable shaft 14. However, the spring force in the direction that gradually extends and causes the second housing 2 to be in the horizontal state gradually increases. At this time, the second movable shaft 17 moves downward while being bent and moved by the braking portion 10 provided in the second guide groove portion 18.

  Also at this time, when the second movable shaft 17 is curved and moved by the control unit 10, the moving direction of the second movable shaft 17 follows the curve of the control unit 10 as shown in FIGS. 9 and 10. And the vertical vector of the second movable shaft 17 changes to an oblique vector, which is dispersed into a horizontal vector component and a vertical vector component. The speed of moving downward is reduced. For this reason, the second casing 2 rotates and moves slowly.

  When the second housing 2 is in the vertical state, the first movable shaft 14 moves to the right end portion 16b of the first guide groove 16 and the second movable shaft 17 as shown in FIG. Moves to a position approaching the lower end 18 a of the second guide groove 18. As a result, the second casing 2 rotates counterclockwise in FIG. 8 with respect to the first casing 1 and is in a vertically oriented state. At this time, since the first movable shaft 14 is located at the right end portion 16b of the first guide groove portion 16, the lower side portion of the second housing 2 is the same as the lower side portion of the second housing 2 in the horizontal state. Become position.

  When the second casing 2 is in the vertical orientation as described above, the center of gravity G of the second casing 2 moves slightly downward from the highest position as shown in FIG. Along with the rotational movement of the movable shaft 14, the pair of coil springs 20 and 21 of the urging member 8 extend the longest, and accordingly, the spring force in the direction that causes the second housing 2 to be in the lateral state becomes the strongest.

  In this state, when the second casing 2 is rotationally moved from the vertical position to the horizontal position, the second casing 2 is moved by the spring force of the pair of coil springs 20 and 21 of the biasing member 8. Since the body 2 is biased in the direction in which the body 2 is in the substantially horizontal state, the second housing 2 can be rotated and moved with a light force as in the case where the second housing 2 is in the horizontal state.

  Then, when the rotational movement is started so that the second housing 2 changes from the vertical state to the horizontal state, the first movable shaft 14 of the movable plate 13 moves along the first guide groove portion 16 of the base plate 15. At the same time, the second movable shaft 17 of the movable plate 13 moves along the second guide groove portion 18 of the base plate 15.

  At this time, as shown in FIGS. 7 and 8, the first movable shaft 14 moves while gradually rotating from the right end portion 16b of the first guide groove portion 16 toward the upper left side, and the second movable shaft. 17 moves upward from the lower end 18 a of the second guide groove 18. Therefore, the second housing 2 rotates clockwise in FIG. 7 with respect to the first housing 1.

  Also at this time, the first movable shaft 14 gradually rotates and moves toward the upper right side along the first guide groove 16, so that the portion located at the lower part of the second housing 2 is almost in the vertical direction. It moves on a substantially linear housing movement locus K shown in FIGS. 1 and 6 without fluctuation. Also at this time, as shown in FIGS. 7 and 8, the pair of coil springs 20, 21 of the biasing member 8 gradually contracts and becomes shorter as the first movable shaft 14 rotates. The spring force in the direction that causes the second housing 2 to be in the horizontal state gradually decreases.

  At this time, the second movable shaft 17 moves downward while being bent and moved by the braking portion 10 provided in the second guide groove portion 18. Also at this time, the moving direction of the second movable shaft 17 gradually changes along the curve of the control unit 10, and the vertical vector of the second movable shaft 17 changes to a diagonal vector, so that The direction vector component and the vertical vector component are dispersed, and the speed of movement below the second movable shaft 17 is reduced. For this reason, the second casing 2 rotates and moves slowly.

  Then, when the second housing 2 rotates and moves to a slanted neutral state, the first movable shaft 14 is positioned approximately in the middle of the first guide groove 16 as shown in FIG. While rotating to the highest position, the second movable shaft 17 moves toward the upper end portion 18b of the second guide groove 18 and comes closest. For this reason, the second housing 2 is inclined with respect to the first housing 1 as shown in FIG. 8, and the center of gravity G of the second housing 2 is the highest.

  At this time, as shown in FIG. 8, the pair of coil springs 20 and 21 of the biasing member 8 contracts and shortens most with the rotational movement of the first movable shaft 14. It becomes the weakest. Thereby, in the neutral state, each spring force of the pair of coil springs 20, 21 does not work (does not urge) in any rotation direction of the second housing 2.

  Thereafter, when the second casing 2 further rotates and passes through the neutral state, the first movable shaft 14 extends along the first guide groove 16 as shown in FIGS. While moving gradually toward the lower left side, the second movable shaft 17 moves downward from the upper end portion 18b of the second guide groove portion 18. For this reason, the second casing 2 rotates clockwise in FIG. 10 with respect to the first casing 1 and approaches a sideways state.

  At this time, since the first movable shaft 14 gradually rotates and moves toward the lower left side along the first guide groove portion 16, the center of gravity position G of the second housing 2 is slightly lowered from the highest position, The portion located at the lower part of the second casing 2 moves on a substantially linear casing movement locus K shown in FIGS. 1 and 6 with almost no fluctuation in the vertical direction.

  Further, when the second casing 2 rotates in this manner, as shown in FIG. 10, the pair of coil springs 20, 21 of the biasing member 8 is accompanied by the rotational movement of the first movable shaft 14. However, the spring force in the direction that gradually extends to bring the second housing 2 into the vertical state gradually increases. At this time, the second movable shaft 17 moves downward while being bent and moved by the braking portion 10 provided in the second guide groove portion 18.

  Also at this time, when the second movable shaft 17 is curved and moved by the control unit 10, the moving direction of the second movable shaft 17 follows the curve of the control unit 10 as shown in FIGS. 9 and 10. And the vertical vector of the second movable shaft 17 changes to an oblique vector, which is dispersed into a horizontal vector component and a vertical vector component. The speed of moving downward is reduced. For this reason, the second casing 2 rotates and moves slowly.

  At this time, the center of gravity G of the second housing 2 gradually decreases and the rotational moment due to the weight of the second housing 2 gradually increases, so that the second housing 2 is accelerated by gravity and accelerated. Occurs, and the second housing 2 rotates at a high speed. However, since the second movable shaft 17 moves downward while being curved and moved by the braking portion 10 provided in the second guide groove portion 18, the moving speed of the second movable shaft 17 is reduced, The rotational speed of the second housing 2 is braked.

  As a result, even if an inertial force due to the acceleration is generated in the second casing 2, the inertial force is reduced by the braking portion 10 provided in the second guide groove portion 18, and the second casing 2 is slowly moved. Rotate and move. At this time, the pair of coil springs 20 and 21 of the urging member 8 gradually become stronger in the direction that causes the second casing 2 to be in the vertical orientation. The rotational speed of the second housing 2 can also be braked by force. As a result, even if an inertial force accompanying acceleration is generated in the second casing 2, the inertial force is reduced and the second casing 2 is slowly rotated.

  Then, when the second casing 2 is in the horizontal state, the first movable shaft 14 moves to the left end portion 16a of the first guide groove 16 and stops, as shown in FIG. The shaft 17 moves to the lower end 18a of the second guide groove 18 and stops. For this reason, the second housing 2 slowly rotates clockwise in FIG. 9 with respect to the first housing 1 to be in a lateral state, and the rotation of the second housing 2 with respect to the first housing 1 is performed. The impact caused by the movement is absorbed and alleviated by the braking portion 10 of the second guide groove 18 and the pair of coil springs 20 and 21.

  As described above, according to this electronic apparatus, the rotational movement guide member 7 that connects the second casing 2 to the first casing 1 so as to be able to rotate and move between the horizontal orientation and the vertical orientation, and the rotation And a braking unit 10 that is provided on the movement guide member 7 and changes the rotational movement of the second casing 2 relative to the first casing 1 to brake the first casing 1. The operability when rotating the second casing 2 is good, and the impact of the second casing 2 on the first casing 1 can be reduced.

  That is, according to this electronic apparatus, when the second casing 2 is rotated with respect to the first casing 1, the second casing 2 can be smoothly moved. In addition, when the second casing 2 rotates and stops, the braking unit 10 brakes the rotational movement of the second casing 2 in the middle of the rotational movement of the second casing 2, and the second casing 2 The housing 2 can be slowly rotated and stopped.

  For this reason, according to this electronic apparatus, when the second casing 2 is rotationally moved with respect to the first casing 1, the operability of the rotational movement is good and the first casing 1 can be operated with respect to the first casing 1. The impact associated with the rotational movement of the two housings 2 can be reduced by the braking of the braking unit 10. Thereby, it is possible to prevent the electronic components such as the input display unit 6 incorporated in the second housing 2 from being damaged by an impact, and it is also possible to prevent the generation of abnormal noise such as an impact sound.

  In this case, the rotational movement guide member 7 performs the first rotation that regulates the vertical movement of the second casing 2 when the second casing 2 rotates relative to the first casing 1. When the movement guide unit 11 and the second housing 2 are rotationally moved with respect to the first housing 1, the movement guide portion 11 and the second housing 2 that restrict the lateral movement of the second housing 2 with respect to the first housing 1 are regulated. Two rotational movement guide parts 12, and the braking part 10 is provided in the second rotational movement guide part 12 to change the rotational movement of the second casing 2 relative to the first casing 1 to brake the second casing 2. Therefore, the second casing 2 can be rotated and moved without substantially changing the portion located below the second casing 2 in the vertical direction, and the first casing can be satisfactorily achieved with a simple structure. The impact associated with the rotational movement of the second housing 2 relative to 1 can be mitigated by the braking of the braking unit 10.

  The first rotational movement guide unit 11 is provided on the movable plate 13 provided in the second casing 2, the first movable shaft 14 provided on the movable plate 13, and the first casing 1. A base plate 15 provided and a first guide groove portion 16 provided on the base plate 15 for guiding the first movable shaft 14 are provided. The second rotational movement guide portion 12 is provided on the movable plate 13. A second movable shaft 17 and a second guide groove portion 18 provided on the base plate 15 for guiding the second movable shaft 17 are provided, and the first movable shaft 14 can rotate and move to the first guide groove portion 16. And the second movable shaft 17 is rotatably attached to the second guide groove 18 to connect the second housing 2 to the first housing 1 so as to be rotationally movable. From the second housing 2 Of reliably it is and favorably attached to the housing 1, it is possible to smoothly be and favorably rotational movement of the second housing 2 with respect to the first housing 1.

  Further, the first guide groove 16 that guides the first movable shaft 11 in the first rotational movement guide portion 11 of the rotational movement guide member 7 is such that the second casing 2 is relative to the first casing 1. When the second casing 2 is rotated and moved, the second casing 2 is formed in a substantially arc shape that curves upward along the lateral direction of the base plate 15 so as to restrict the vertical movement of the second casing 2. The portion located in the lower part of the housing 2 is hardly changed in the vertical direction, and can be moved smoothly and satisfactorily in a stable state along the substantially linear housing movement locus K.

  That is, when the second housing 2 is rotated and moved from the horizontal state to the vertical state, or when the second housing 2 is rotated and moved from the vertical state to the horizontal state, the first guide groove 16 is provided. Since the first movable shaft 14 is gradually moved upward along the first guide groove 16, even if the corners at the lower portions on both sides of the second housing 2 are rotated downward, the second It is possible to prevent the casing 2 of the second casing 2 from gradually moving upward along the first guide groove 16 and protruding the corners of the second casing 2 downward. Thereby, the part located in the lower part of the second casing 2 hardly fluctuates in the vertical direction, and the part located in the lower part of the second casing 2 is moved in a horizontal, substantially linear case movement locus K. Can be moved in a stable state.

  The second guide groove 18 that guides the second movable shaft 17 in the second rotational movement guide portion 12 of the rotational movement guide member 7 is configured so that the second casing 2 is relative to the first casing 1. The second casing 2 is formed along the vertical direction of the base plate 15 so as to restrict the lateral movement of the second casing 2 with respect to the first casing 1 when rotating. The second movable shaft 17 is moved up and down by the second guide groove 18 when the second housing 2 is rotated from the horizontal state to the vertical state or when the second housing 2 is rotated from the vertical state to the horizontal state. By guiding in the direction, the movement of the second casing 2 in the lateral direction is regulated, and the second casing 2 is smoothly stabilized in a stable state so that the second casing 2 does not swing sideways. Moreover, it can be rotated and moved smoothly.

  Further, the braking unit 10 is provided in a part of the second guide groove 18 that guides the second movable shaft 17 in the vertical direction in accordance with the rotational movement of the second housing 2 with respect to the first housing 1. When the second movable shaft 17 moves in the vertical direction along the second guide groove 18 by changing the moving direction in the vertical direction of the second movable shaft 17 to a different direction. The vector in the vertical direction of the second movable shaft 17 can be changed in an oblique direction to be dispersed into the vector component in the left-right direction and the vector component in the up-down direction, whereby the vertical direction of the second movable shaft 17 can be dispersed. Can be reliably and well decelerated.

  In this case, the braking unit 10 bends the substantially middle part of the second guide groove 18 in the vertical direction, and the second movable shaft 17 accompanying the rotational movement of the second housing 2 relative to the first housing 1. The moving direction of the second guide groove 18 is curved when the second movable shaft 17 moves up and down as the second casing 2 rotates. The moving direction of the second movable shaft 17 can be gently changed by the braking unit 10 to favorably reduce the moving speed of the second movable shaft 17, and this also causes the second movement relative to the first housing 1. The impact associated with the rotational movement of the casing 2 can be reliably and satisfactorily mitigated by the braking unit 10.

  In addition, the braking unit 10 is configured so that the second housing 2 rotates when the second housing 2 rotates from the horizontal state to the vertical state or when the second housing 2 rotates from the vertical state to the horizontal state. Since the movable shaft 17 reciprocates twice in the vertical direction of the second guide groove portion 18, the second movable shaft 17 can be braked twice by the braking portion 10. Thereby, the moving speed of the 2nd movable shaft 17 can be decelerated still more reliably. For this reason, the impact accompanying the rotational movement of the second housing 2 relative to the first housing 1 can be reliably and satisfactorily mitigated by the braking unit 10.

  Further, in this electronic device, when the second casing 2 is in the horizontal state, the second casing 2 is urged toward the vertical direction, and the second casing 2 is in the vertical state. When the second casing 2 is urged toward the sideways state and the second casing 2 is rotated and tilted at an almost intermediate position, the neutral state is obtained. Since the urging member 8 that minimizes the urging force with respect to the second casing 2 is provided, the urging member 8 also rotates and moves the second casing 2 relative to the first casing 1. The operability at the time of making it good, and the impact by the 2nd housing | casing 2 with respect to the 1st housing | casing 1 can be relieved.

  That is, when the second casing 2 is rotated with respect to the first casing 1, the second casing 2 can be smoothly moved by the biasing force of the biasing member 8. When the second housing 2 starts to move, the urging force of the urging member 8 gradually weakens, so that the second housing 2 can be rotated and moved smoothly and smoothly. In addition, when the second casing 2 rotates and stops, the braking movement of the second casing 2 is braked by the braking unit 10, and the second casing 2 is also applied by the biasing force of the biasing member 8. 2 can be slowly rotated and stopped.

  For this reason, according to this electronic apparatus, when the second casing 2 is rotationally moved with respect to the second first casing 1, the second casing is driven by the braking unit 10 and the biasing member 8. The second casing 2 can be rotated and moved smoothly and smoothly with respect to the first casing 1, and the second casing 2 with respect to the first casing 1 can be moved smoothly. The impact associated with the rotational movement of the body 2 can be reliably and satisfactorily mitigated by the braking of the braking unit 10 and the urging force of the urging member 8, whereby the input display unit incorporated in the second housing 2. It is possible to reliably prevent the electronic components such as 6 from being damaged by an impact.

  In the above embodiment, the case where the urging member 8 for applying the urging force to the second casing 2 is described. However, the urging member 8 is not necessarily used, and the second casing is not necessarily used. When the body 2 rotates, the configuration may be such that only the braking unit 10 that brakes by changing the rotational movement of the second casing is provided. In this case, the braking portion 10 may be a curved portion having a sharp curve with a small curvature radius formed in a part of the second guide groove portion 18 or a curved portion having a gentle curve with a large curvature radius. May be.

  Moreover, in the said embodiment, in the 2nd rotational movement guide part 12 which regulates the horizontal movement of the 2nd housing | casing 2 with respect to the 1st housing | casing 1, the 2nd movable shaft 17 is guided. Although the case where the braking portion 10 is provided in the guide groove portion 18 has been described, the present invention is not limited thereto, and for example, a first rotational movement guide portion that restricts the vertical movement of the second housing 2 relative to the first housing 1. 11, the first guide groove portion 16 that guides the first movable shaft 14 may be provided with a braking portion.

  Further, in the above-described embodiment, the case where the present invention is applied to a photo frame type display device including the first housing 1 and the second housing 2 has been described. However, the photo frame type display device is not necessarily required. For example, the present invention can be widely applied to an electronic device such as a personal computer or a mobile phone in which the second housing rotates and moves in a horizontal state and a vertical state with respect to the first housing.

DESCRIPTION OF SYMBOLS 1 1st housing | casing 2 2nd housing | casing 6 Input display part 7 Rotation movement guide member 8 Energizing member 10 Braking part 11 1st rotation movement guide part 12 2nd rotation movement guide part 13 Movable plate 14 1st Movable base 15 base plate 16 first guide groove 17 second movable shaft 18 second guide groove 20, 21 coil spring K housing movement locus G center of gravity position

Claims (7)

A first housing;
A second housing;
A rotational movement guide member that couples the second casing to the first casing so as to be able to rotate and move between a horizontal orientation and a vertical orientation;
A braking portion provided on the rotational movement guide member for changing and braking the rotational movement of the second casing with respect to the first casing;
An electronic device comprising: The electronic device according to claim 1,
The rotational movement guide member is a first rotational movement guide portion that regulates the vertical movement of the second casing when the second casing rotates relative to the first casing. And a second rotational movement that restricts a lateral movement of the second casing relative to the first casing when the second casing rotates relative to the first casing. With a guide part,
The electronic device according to claim 1, wherein the braking unit is provided in the second rotational movement guide unit and brakes by changing a rotational movement of the second housing relative to the first housing. The electronic device according to claim 2,
The first rotational movement guide portion includes a movable plate provided in the second casing, a first movable shaft provided in the movable plate, and a base plate provided in the first casing. A first guide groove provided on the base plate for guiding the first movable shaft,
The second rotational movement guide portion includes a second movable shaft provided on the movable plate, and a second guide groove portion provided on the base plate for guiding the second movable shaft,
The first movable shaft is rotatably attached to the first guide groove and the second movable shaft is rotatably attached to the second guide groove. Is connected to the first housing in a rotatable manner. In the electronic device according to claim 2 or 3,
The first guide groove portion that guides the first movable shaft in the first rotational movement guide portion extends along a lateral direction of the base plate in order to restrict vertical movement of the second casing. Is formed in a substantially arc shape that curves upward,
The second guide groove portion that guides the second movable shaft in the second rotational movement guide portion is configured so that the second housing rotates when the second housing rotates relative to the first housing. An electronic device, wherein the electronic device is formed along a vertical direction of the base plate in order to restrict lateral movement of the second housing relative to one housing. In the electronic device according to claim 3 or claim 4,
The braking portion is provided in a part of the second guide groove portion that guides the second movable shaft in the vertical direction in accordance with the rotational movement of the second housing with respect to the first housing, An electronic apparatus characterized in that the moving direction in the vertical direction of the second movable shaft is changed in a different direction. The electronic device according to claim 5,
The braking portion bends the substantially middle portion in the vertical direction of the second guide groove portion, and the moving direction of the second movable shaft accompanying the rotational movement of the second housing relative to the first housing. An electronic device characterized by gradually changing. In the electronic device according to any one of claims 1 to 6,
When the second casing is in the horizontal state, the second casing is urged in the vertical direction, and when the second casing is in the vertical state, the second casing When the second casing is biased in a direction to turn it sideways and the second casing is rotated and tilted obliquely at a substantially intermediate position, the neutral state is reached. An electronic device comprising an urging member that minimizes the urging force against the electric device.

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