JP2018149878A - Electronic device and display panel moving method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electronic device which causes a large size display panel to be reversely tilted in a proper manner and inhibits a lower end part of the display panel from entering into a housing in a reverse tilt posture.SOLUTION: An electronic device 10 has: a housing 12; a display panel 16; a slide part 18 which can move in a retreat direction and an advanced direction; a lower supporting point part 22 and an upper connection part 26 provided on a back surface 16B of the display panel 16; a lower arm part 28 provided between a front surface of the housing 12 and the display panel 16 and having one end part 48 rotatably connected to the lower supporting point part 22; an upper arm part 30 provided between the front surface of the housing 12 and the display panel 16 and having one end part 42 movably connected to the upper connection part 26; a middle supporting point part 32 which rotatably connects an end part 18A of the slide part 18, the other end part 50 of the lower arm part 28, and the other end part 44 of the upper arm part 30 to each other; an upper arm supporting point part 34 which is provided on the front surface of the housing 12 and contacts with the upper arm part 30; and a lower arm supporting point part 36 which is provided on the front surface of the housing 12 and contacts with the lower arm part 28.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an electronic device and a method for moving a display panel.

  For example, some electronic devices mounted on a vehicle have a display panel. Such an electronic device displays a navigation screen or the like on the display panel. Such an electronic device may have a structure in which a display panel is disposed on the front surface of a housing and the posture of the display panel can be changed. Examples of the posture of the display panel include an upright posture, a reverse tilt posture, and a forward tilt posture. The upright posture is a posture in which the surface of the display panel is in a direction along the front surface of the housing. The reverse tilt posture is a posture in which the display panel is tilted forward by projecting the upper end of the display panel forward from the lower end. The forward tilt posture is a posture in which the display panel is tilted rearward because the lower end portion of the display panel projects forward from the upper end portion.

  In-vehicle electronic devices may be mounted above the occupant's line of sight or may be mounted with the electronic device tilted. In such a case, it is desired that the display surface of the display panel be in an easy-to-view posture or that the front surface of the display panel is tilted downward, that is, the above-described reverse tilt posture is used in order to avoid reflection of sunlight. Is done. Patent Document 1 describes an electronic device in which a slide member provided in a housing is retracted to place a display panel in a reverse tilt posture (forward tilt posture). In the electronic device disclosed in Patent Document 1, the lower end of the display panel is moved backward to enter the housing, thereby bringing the display panel into a reverse tilt posture.

JP, 2015-12123, A

  In recent years, it has been required to increase the size of the display panel. However, when the reverse tilt posture is realized with the structure as in Patent Document 1, when the display panel is enlarged with respect to the casing, for example, the display panel protrudes below the lower end of the casing, Even if reverse tilting is attempted, the lower end of the display panel cannot be moved into the housing, making it difficult to realize a reverse tilt posture. Accordingly, there is a need for a technique that appropriately reverse tilts a large display panel and suppresses the lower end of the display panel from entering the housing when the display panel is in the reverse tilt posture.

  In view of the above problems, the present invention appropriately electronically tilts a large-sized display panel and suppresses the lower end of the display panel from entering the housing in the reverse tilt posture. It aims at providing the movement method of a panel.

  An electronic device according to one embodiment of the present invention includes a housing, a display panel provided on the front surface of the housing, and a direction from the front surface of the housing to a surface opposite to the front surface. A sliding portion that is movable in a backward direction and a forward direction opposite to the backward direction, a lower fulcrum portion provided on a rear surface that is a surface on the housing side of the display panel, and a rear surface of the display panel Provided between the upper connecting portion provided on the upper end side of the display panel with respect to the lower fulcrum portion, and between the front surface of the housing and the back surface of the display panel, and one end portion is the lower fulcrum point. A lower arm portion that is rotatably connected to a portion, and an upper arm that is provided between the front surface of the housing and the back surface of the display panel, and has one end portion movably connected to the upper connection portion Between the front surface of the housing and the back surface of the display panel. A middle fulcrum portion rotatably connecting the end portion of the slide portion on the front surface side, the other end portion of the lower arm portion, and the other end portion of the upper arm portion; Provided on the front surface of the upper arm, the upper arm fulcrum part contacting the portion between the one end and the other end of the upper arm part, and provided on the front surface of the housing, A lower arm fulcrum that contacts a portion between one end and the other end.

  According to the present invention, it is possible to appropriately reverse-tilt a large display panel, and to prevent the lower end of the display panel from entering the housing when in a reverse-tilt posture.

FIG. 1 is a schematic diagram illustrating a vehicle on which an electronic apparatus according to this embodiment is mounted. FIG. 2 is a schematic diagram of the electronic apparatus according to the present embodiment. FIG. 3 is a schematic enlarged view showing the upper connection portion and the upper arm portion according to the present embodiment. FIG. 4 is a schematic enlarged view showing the auxiliary unit according to the present embodiment. FIG. 5 is a schematic enlarged view showing the protective plate according to the present embodiment. FIG. 6 is a schematic diagram illustrating a reverse tilt posture of the display panel according to the present embodiment. FIG. 7 is a schematic diagram showing a forward tilt posture of the display panel according to the present embodiment.

  Embodiments of the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments described below.

  FIG. 1 is a schematic diagram illustrating a vehicle on which an electronic apparatus according to this embodiment is mounted. As shown in FIG. 1, the electronic device 10 according to this embodiment is mounted in a vehicle 100. The electronic device 10 includes a housing 12 and a display panel 16. The housing 12 houses a drive device for driving the electronic device 10 and is housed inside the vehicle 100. The casing 12 is fixed with respect to the vehicle 100 and does not move with respect to the vehicle 100. The display panel 16 is a panel that displays an image and is exposed to the driver's seat side. The electronic device 10 is, for example, an AV integrated car navigation device.

(Structure of electronic equipment)
FIG. 2 is a schematic diagram of the electronic apparatus according to the present embodiment. FIG. 2 is a diagram when the display panel 16 is in the upright posture. As shown in FIG. 2, the electronic device 10 includes a housing 12, a sub-panel 14, a display panel 16, a slide part 18, a slide drive part 19, a lower fulcrum part 22, an upper connection part 26, and a lower part. The arm portion 28, the upper arm portion 30, the middle fulcrum portion 32, the upper arm fulcrum portion 34, the lower arm fulcrum portion 36, and the auxiliary portion 38 are provided. The electronic device 10 changes the posture of the display panel 16 by moving the slide unit 18 along a direction X described later by the slide drive unit 19.

  As shown in FIG. 2, the sub-panel 14 is a member provided on the direction X1 side (front side) of the housing 12. The position of the sub panel 14 is fixed with respect to the housing 12 and does not move with respect to the housing 12. The direction X1 is a direction from the surface 15 on the opposite side of the sub panel 14 of the housing 12 toward the sub panel 14 side (the front side of the housing 12), and can also be referred to as a forward direction. The direction X2 is the direction opposite to the direction X1, that is, the direction from the sub-panel 14 toward the surface 15, and can also be referred to as the backward direction. Hereinafter, the direction along the direction X1 and the direction X2 is appropriately referred to as a direction X. The direction Y is a direction orthogonal to the direction X. The direction Z is a direction orthogonal to the direction X and the direction Y. The direction Z is a vertical direction when the electronic device 10 is attached to the vehicle 100. Moreover, the direction Z1 which is one direction among the directions Z is a direction from the lower end portion 14A2 of the sub-panel 14 described later toward the upper end portion 14A1. The direction Z1 is a direction from the lower side in the vertical direction (the ground surface side) to the upper side in the vertical direction when the electronic device 10 is attached to the vehicle 100. In addition, the direction Z2 which is the other of the directions Z is a direction opposite to the direction Z1 and is a direction from the upper end portion 14A1 of the sub-panel 14 toward the lower end portion 14A2.

  As shown in FIG. 2, the sub-panel 14 is disposed on the direction X1 side of the housing 12 and can be said to be the front surface of the housing 12. The sub-panel 14 has a surface portion 14A, a side surface portion 14B, an upper surface portion 14C, and an opening portion 14D. The surface portion 14 </ b> A is a plate-like member located on the direction X <b> 1 side of the housing 12. The surface portion 14 </ b> A has a surface that extends along a direction orthogonal to the direction X <b> 1, that is, the direction Y and the direction Z. Hereinafter, the end on the direction Z1 side of the surface portion 14A is referred to as an upper end 14A1, and the end on the direction Z2 side is referred to as a lower end 14A2.

  One side surface portion 14B is provided at each end portion (side end portion) along the direction Y of the surface portion 14A. The side surface portion 14B protrudes in the direction X1 from the side end portion of the surface portion 14A. For convenience of explanation, in FIG. 2, the side surface portion 14B is indicated by a dotted line. The upper surface portion 14C is provided on the upper end portion 14A1 of the surface portion 14A, and projects from the upper end portion 14A1 along the direction X1. In the present embodiment, the lower end portion 14A2 of the surface portion 14A is not provided with a plate-like member (a member protruding in the direction X1 side) corresponding to the upper surface portion 14C.

  The opening 14D is an opening provided in the surface portion 14A. The opening 14D penetrates from the surface on the direction X1 side to the surface on the direction X2 side of the surface portion 14A, and two openings 14D are provided along the direction Y in this embodiment.

  As shown in FIG. 2, the display panel 16 is provided on the direction X <b> 1 side of the sub-panel 14, that is, on the front surface of the housing 12. The display panel 16 is positioned in a direction along the surface portion 14 </ b> A of the sub-panel 14 in the upright posture. In the display panel 16, the surface on the direction X1 side is a display surface 16A for displaying an image. Further, hereinafter, the surface opposite to the display surface 16A of the display panel 16 is referred to as a back surface 16B, the upper end portion of the display panel 16 is referred to as an upper end portion 16C, and the lower end portion of the display panel 16 is referred to as a lower end. Part 16D. That is, the back surface 16B is the surface on the direction X2 side of the display panel 16, and faces the surface on the housing 12 (sub-panel 14) side in the upright posture. Further, the upper end portion 16C is an end portion on the direction Z1 side of the display panel 16 in the upright posture. The lower end 16D is the end opposite to the upper end 16C, and is the end on the direction Z2 side of the display panel 16 in the upright posture. When the display panel 16 is in the upright posture, the lower end 16D is located on the direction Z2 side with respect to the lower end 14A2 of the sub-panel 14.

  As shown in FIG. 2, the slide portion 18 is provided in the housing 12 and extends along the direction X. The slide part 18 has a structure capable of moving (sliding) along the direction X1 and the direction X2. Two slide portions 18 are provided along the direction Y. The two slide portions 18 are connected to each other and constitute a slide unit 18S that moves (slids) along the direction X1 and the direction X2. At least a part of the slide portion 18 on the side in the direction X1 is exposed from the inside of the housing 12 through the opening portion 14D of the sub-panel 14. That is, the end 18 </ b> A on the direction X <b> 1 side of the slide portion 18 is located between the sub panel 14 (surface portion 14 </ b> A) and the display panel 16.

  As shown in FIG. 2, the slide drive unit 19 is provided in the housing 12. The slide drive unit 19 drives the slide unit 18 to move the slide unit 18 along the direction X1 and the direction X2. In addition, the shape of the slide part 18 of FIG. 2 is shown typically, and the shape is not limited to that shown in FIG.

  As shown in FIG. 2, the middle fulcrum portion 32 is connected to the end portion 18 </ b> A of the slide portion 18. The middle fulcrum portion 32 is a shaft-like member extending along the direction Y, and is rotatably inserted into an opening provided in the end portion 18A.

  As shown in FIG. 2, the lower fulcrum part 22 has an attachment part 24 and a shaft part 25. The attachment portion 24 is provided in a state of being fixed to the back surface 16B of the display panel 16, and has an opening. That is, the attachment portion 24 does not move with respect to the display panel 16. Two attachment portions 24 are provided along the direction Y. The shaft portion 25 is a shaft-like member attached to the two attachment portions 24. The shaft portion 25 is fixedly attached to the attachment portion 24. The lower fulcrum portion 22 is provided on the lower end 16D side (the lower end portion 16D side of the center of the rear surface 16B) on the back surface 16B of the display panel 16. In the present embodiment, the lower fulcrum part 22 is provided on the direction Z2 side with respect to the lower end part 14A2 of the sub-panel 14 in the upright posture.

  FIG. 3 is a schematic enlarged view showing the upper connection portion and the upper arm portion according to the present embodiment. The upper connecting portion 26 is provided on the inner side (the center side of the display panel 16) along the direction Y than the auxiliary portion 38 shown in FIG. FIG. 3 is a diagram excluding the auxiliary portion 38 for convenience of explanation. As shown in FIG. 3, the upper connection portion 26 is provided on the back surface 16 </ b> B of the display panel 16. Furthermore, the upper connection portion 26 is provided in a state of being fixed to the back surface 16 </ b> B of the display panel 16 and does not move with respect to the display panel 16. The upper connection portion 26 is provided on the back surface 16B of the display panel 16 on the upper end portion 16C side (upper end portion 16C side than the center of the back surface 16B). That is, the upper connection portion 26 is provided on the upper end portion 16C side (direction Z1 side) with respect to the lower fulcrum portion 22. Further, the upper connection portion 26 has a groove portion 40. The groove portion 40 is a groove that extends along a direction from the upper end portion 16C toward the lower end portion 16D (direction Z in the upright posture). Two upper connection portions 26 are provided along the direction Y.

  As shown in FIGS. 2 and 3, the upper arm portion 30 is provided between the surface portion 14 </ b> A (the front surface of the housing 12) of the sub-panel 14 and the back surface 16 </ b> B of the display panel 16. The upper arm portion 30 is a member that extends from one end portion 42 to the other end portion 44. Two upper arm portions 30 are provided along the direction Y, and the two may be connected to each other by a connecting member (not shown).

  As shown in FIG. 3, the upper arm portion 30 has one end portion 42 movably connected to the upper connection portion 26. More specifically, the upper arm portion 30 is provided with a protruding portion 43 at one end portion 42. The upper arm portion 30 is connected to the upper connection portion 26 by inserting the protrusion 43 into the groove portion 40 of the upper connection portion 26. The protrusion 43 can move in the groove 40 along the extending direction of the groove 40 (the direction from the upper end 16C toward the lower end 16D). Accordingly, one end 42 of the upper arm portion 30 is movable along the groove portion 40 with respect to the upper connection portion 26. The protrusion 43 receives a load in the direction of the end surface on the upper end portion 16C side of the groove 40 by a spring or the like (not shown). Accordingly, the protruding portion 43 is positioned so as to be pressed against the end surface on the upper end portion 16C side of the groove portion 40 in the upright posture. Thus, the one end portion 42 of the upper arm portion 30 is movably connected to the display panel 16 via the upper connection portion 26. Furthermore, one end portion 42 of the upper arm portion 30 is connected to the display panel 16 (upper connection portion 26) so as to be movable in a direction from the upper end portion 16C toward the lower end portion 16D.

  Further, the upper arm portion 30 has the other end portion 44 connected to the middle fulcrum portion 32. Specifically, in the upper arm portion 30, the middle fulcrum portion 32 is rotatably inserted into an opening provided in the other end portion 44. As described above, the upper arm portion 30 extends from the upper connection portion 26 to which one end portion 42 is connected to the middle fulcrum portion 32 to which the other end portion 44 is connected.

  Further, a portion between one end portion 42 and the other end portion 44 of the upper arm portion 30 is defined as an intermediate portion 46. The intermediate portion 46 of the upper arm portion 30 is in contact with the upper arm fulcrum portion 34 in the upright posture. The upper arm fulcrum portion 34 is provided on the sub-panel 14 (front surface of the housing 12), and more specifically, is provided on the surface (front surface of the housing 12) on the direction X1 side of the surface portion 14A of the sub-panel 14. . The upper arm fulcrum part 34 is a bearing that contacts the surface of the intermediate part 46 on the direction X2 side. In the present embodiment, the upper arm fulcrum portion 34 is a roller that can rotate about the direction Y as a central axis, and is in contact with the surface of the intermediate portion 46 on the direction X2 side so as to be rotatable. However, the upper arm fulcrum part 34 may not be a roller, and may be, for example, a sliding bearing. As will be described in detail later, the upper arm portion 30 is rotatable with the upper arm fulcrum portion 34 as a fulcrum and an axis along the direction Y on the intermediate portion 46 as a rotation axis. The position of the upper arm fulcrum part 34 is fixed with respect to the sub-panel 14 and is not connected to the upper arm part 30, so that the position moves with the movement of the upper arm part 30. There is nothing.

  As shown in FIG. 2, the lower arm portion 28 is provided between the surface portion 14 </ b> A (the front surface of the housing 12) of the sub-panel 14 and the back surface 16 </ b> B of the display panel 16. The lower arm part 28 is located on the direction Z2 side with respect to the upper arm part 30, in other words, on the lower end part 16D side of the display panel 16 with respect to the upper arm part 30. The lower arm portion 28 is a member that extends from one end portion 48 to the other end portion 50. Two lower arm portions 28 are provided along the direction Y, and the two may be connected to each other by a connecting member (not shown).

  One end portion 48 of the lower arm portion 28 is rotatably connected to the lower fulcrum portion 22. More specifically, in the lower arm portion 28, the shaft portion 25 of the lower fulcrum portion 22 is rotatably inserted into an opening provided in one end portion 48. Accordingly, one end 48 of the lower arm portion 28 can rotate with respect to the display panel 16 with the direction Y as the central axis. In other words, one end portion 48 of the lower arm portion 28 is connected to the display panel 16 via the lower fulcrum portion 22 and can rotate about the direction Y as the central axis with respect to the display panel 16 (lower fulcrum portion 22). ing.

  Further, the lower arm portion 28 has the other end portion 50 connected to the middle fulcrum portion 32. Specifically, in the lower arm portion 28, the middle fulcrum portion 32 is rotatably inserted into an opening provided in the other end portion 50. That is, the middle fulcrum portion 32 is rotatable to the opening of the end portion 18A of the slide portion 18, the opening of the other end portion 44 of the upper arm portion 30, and the opening of the other end portion 50 of the lower arm portion 28. Is inserted. Accordingly, the end portion 18A of the slide portion 18, the other end portion 44 of the upper arm portion 30, and the other end portion 50 of the lower arm portion 28 are connected to the middle fulcrum portion 32, so that the direction Y is changed. The rotary shafts can rotate with each other.

  Further, a portion between one end 48 and the other end 50 of the lower arm portion 28 is defined as an intermediate portion 52. The intermediate arm 52 is in contact with the lower arm fulcrum portion 36 in the upright posture. The lower arm fulcrum portion 36 is provided on the sub-panel 14 (the front surface of the housing 12). More specifically, the lower arm fulcrum portion 36 is provided on the inner surface (center side of the surface portion 14A) along the direction Y of the side surface portion 14B of the sub-panel 14. Is provided. The lower arm fulcrum part 36 is arranged on the direction Z2 side with respect to the upper arm fulcrum part 34. The lower arm fulcrum portion 36 is a bearing that contacts the surface of the intermediate portion 52 on the direction X2 side. In the present embodiment, the lower arm fulcrum portion 36 is a roller that can rotate about the direction Y as a central axis, and is in contact with the surface of the intermediate portion 52 on the direction X2 side so as to be rotatable. However, the lower arm fulcrum portion 36 may not be a roller, and may be, for example, a sliding bearing. As will be described in detail later, the lower arm portion 28 is rotatable with the lower arm fulcrum portion 36 as a fulcrum and an axis along the direction Y on the intermediate portion 52 as a rotation axis. Note that the position of the lower arm fulcrum portion 36 is fixed with respect to the sub-panel 14 and is not connected to the lower arm portion 28, so that the position moves with the movement of the lower arm portion 28. There is nothing.

  Here, as shown in FIG. 3, the length from one end portion 42 of the upper arm portion 30 to the intermediate portion 46 is a length A1, and the length from the intermediate portion 46 to the other end portion 44 is The length is A2. In this case, the length A1 of the upper arm portion 30 is longer than the length A2. In addition, as shown in FIG. 2, the length from one end 48 of the lower arm portion 28 to the intermediate portion 52 is defined as length B1, and the length from the intermediate portion 52 to the other end 50 is defined as long. Let B2. In this case, the lower arm portion 28 has a length B1 shorter than the length B2. The length from one end 42 of the upper arm 30 to the other end 44 (the total length of the length A1 and the length A2) is from one end 48 of the lower arm 28 to the other. It is longer than the length to the end portion 50 (total length of the length B1 and the length B2). The ratio of length A1 to length A2 (length A1 / length A2) is higher than the ratio of length B1 to length B2 (length B1 / length B2). However, the relationship between the ratio of the length A1 to the length A2 and the ratio of the length B1 to the length B2 is not limited to this relationship and may vary depending on the tilt angle.

  FIG. 4 is a schematic enlarged view showing the auxiliary unit according to the present embodiment. As shown in FIGS. 2 and 4, the auxiliary portion 38 is provided between the surface portion 14 </ b> A (the front surface of the housing 12) of the sub-panel 14 and the back surface 16 </ b> B of the display panel 16. The auxiliary portion 38 is located on the outer side (the direction side away from the center of the surface portion 14A) along the direction Y of the upper arm portion 30. As shown in FIG. 4, the auxiliary portion 38 is a member that extends from one end portion 64 to the other end portion 66. Two auxiliary portions 38 are provided along the direction Y, and the two may be connected to each other by a connecting member (not shown).

  As shown in FIG. 4, the auxiliary portion 38 is connected such that one end portion 64 is movable with respect to the sub-panel 14. Specifically, the auxiliary portion 38 has a protruding portion 65 at one end portion 64. A groove portion 60 is provided in the side surface portion 14B of the sub panel 14. The groove portion 60 is a groove extending along the direction Z. The auxiliary portion 38 has one end portion 64 connected to the side surface portion 14 </ b> B of the sub-panel 14 by inserting the protruding portion 65 into the groove portion 60. The protrusion 65 is movable in the groove 60 along the direction Z that is the extending direction of the groove 60. Accordingly, one end portion 64 of the auxiliary portion 38 is movable with respect to the sub-panel 14 along the groove portion 60 (along the direction Z). The protrusion 65 receives a load along the direction Y of the groove 60 by a spring or the like (not shown). Accordingly, the protrusion 65 is prevented from being loose with respect to the groove 60. However, the protrusion 65 does not need to receive a load in this way. Thus, the one end portion 64 of the auxiliary portion 38 is movably connected to the sub-panel 14. Furthermore, one end portion 64 of the auxiliary portion 38 is connected to the sub-panel 14 (housing 12) so as to be movable in the direction Z.

  Further, the other end portion 66 of the auxiliary portion 38 is rotatably connected to the fulcrum portion 62. The fulcrum part 62 is connected to the back surface 16B of the display panel 16, and has an attachment part 63 and a shaft part 63A. The attachment portion 63 is provided in a state of being fixed to the back surface 16B of the display panel 16, and has an opening. That is, the attachment portion 63 does not move with respect to the display panel 16. Two attachment portions 63 are provided along the direction Y. The shaft portion 63 </ b> A is a shaft-like member attached to the two attachment portions 63. The shaft portion 63A is fixedly attached to the attachment portion 63. In the auxiliary portion 38, the shaft portion 63A is rotatably inserted into an opening provided in the other end portion 66. Therefore, the other end portion 66 of the auxiliary portion 38 is rotatable with respect to the display panel 16 with the direction Y as the central axis. In other words, the other end portion 66 of the auxiliary portion 38 is connected to the display panel 16 via the fulcrum portion 62 and is rotatable about the direction Y as the central axis with respect to the display panel 16 (fulcrum portion 62).

  Since the auxiliary portion 38 has such a structure, the auxiliary portion 38 assists the display panel 16 to be in a forward tilt posture described later.

  FIG. 5 is a schematic enlarged view showing the protective plate according to the present embodiment. Although not shown in FIG. 2 for convenience of explanation, as shown in FIG. 5, the electronic device 10 further includes a fulcrum part 70, a connection part 74, and a protection plate 80. The fulcrum part 70 is connected to the back surface 16 </ b> B of the display panel 16 and has an attachment part 71 and a shaft part 72. The attachment portion 71 is provided in a state of being fixed to the back surface 16B of the display panel 16, and has an opening. That is, the attachment portion 71 does not move with respect to the display panel 16. Two attachment portions 71 are provided along the direction Y. The shaft portion 72 is a shaft-like member attached to the two attachment portions 71. The shaft portion 72 is fixedly attached to the attachment portion 71. The fulcrum part 70 is provided on the back surface 16B of the display panel 16 on the upper end part 16C side.

  The connecting portion 74 is attached to the auxiliary portion 38 and is located on the inner side (direction side toward the center of the surface portion 14A) along the direction Y than the auxiliary portion 38. The connecting portion 74 is attached in a state of being fixed to the auxiliary portion 38. That is, the connecting portion 74 is connected to the sub panel 14 (housing 12) through the auxiliary portion 38. The connecting portion 74 has a groove 76. The groove portion 76 is a groove extending in the direction Z in an upright posture. The extending direction of the groove portion 76 is slightly inclined from the direction Z in an upright posture and intersects the direction X and the direction Y. Two connecting portions 74 are provided along the direction Y.

  The protective plate 80 is provided between the surface portion 14 </ b> A (the front surface of the housing 12) of the sub-panel 14 and the back surface 16 </ b> B of the display panel 16. Furthermore, the protection plate 80 is provided on the upper end portion 16C side of the display panel 16, and is positioned on the direction Z1 side with respect to the upper arm portion 30 in the reverse tilt posture described later. The protective plate 80 is a plate-like member extending along the Y direction, and has a side surface 81 that is an end surface along the Y direction.

  The guard plate 80 is attached to the fulcrum 70 so that one end 82 of the side surface 81 is rotatable. Specifically, one end portion 82 of the side surface 81 has an opening, and the shaft portion 72 of the fulcrum portion 70 is rotatably inserted into the opening. Therefore, one end 82 of the protective plate 80 is rotatable with respect to the display panel 16 with the direction Y as the central axis. In other words, one end 82 of the protective plate 80 is connected to the display panel 16 via the fulcrum part 70 and is rotatable with respect to the display panel 16 (fulcrum part 70) about the direction Y as a central axis.

  In addition, the other end 84 of the side surface 81 of the protective plate 80 is movably connected to the connecting portion 74. More specifically, the protective plate 80 is provided with a protrusion 85 at the other end 84. The protective plate 80 is connected to the connecting portion 74 by inserting the protrusion 85 into the groove 76 of the connecting portion 74. The protrusion 85 can move in the groove 76 along the extending direction of the groove 76. Due to this structure, the other end 84 of the protection plate 80 is connected to the sub-panel 14 (housing 12) via the connecting portion 74 and the auxiliary portion 38. Furthermore, the other end portion 84 of the protection plate 80 is movably connected to the auxiliary portion 38 (the sub panel 14 and the housing 12).

  Since the protection plate 80 has such a structure, it covers the upper side (direction Z1 side) of the space generated between the sub panel 14 and the display panel 16 in the reverse tilt posture described later.

(Operation of electronic equipment)
Next, the operation of the electronic device 10, that is, the movement operation of the display panel 16 will be described. The electronic device 10 switches the posture of the display panel 16 to one of the upright posture, the reverse tilt posture, and the forward tilt posture by moving the slide portion 18 in the directions X1 and X2 by the slide drive portion 19. The slide drive unit 19 executes the switching of the posture when detecting the operation of the operator on the electronic device 10, for example. The upright posture is a posture in which the surface of the display panel 16 (the display surface 16A and the back surface 16B) is along the surface of the surface portion 14A of the sub-panel 14 (the front surface of the housing 12), in other words, the surface of the display panel 16. Is a posture parallel to the direction Z. The reverse tilt posture is a posture in which the upper end portion 16C of the display panel 16 protrudes in the direction X1 side from the lower end portion 16D, and the display panel 16 tilts forward. The forward tilt posture is a posture in which the lower end portion 16D of the display panel 16 protrudes toward the direction X1 with respect to the upper end portion 16C, and the display panel 16 tilts backward.

  FIG. 2 shows a state in which the display panel 16 is in the upright posture. As shown in FIG. 2, when the display panel 16 is in the upright posture, the position of the slide portion 18 is the initial position. The initial position is a predetermined position and is a position of the slide unit 18 in which the display panel 16 is in an upright posture. When the slide portion 18 is in the initial position, the end portion 18A of the slide portion 18 is located between the sub-panel 14 (surface portion 14A) and the display panel 16. As a result, one end portion 42 of the upper arm portion 30 and one end portion 48 of the lower arm portion 28 are positioned along the direction Z, and the direction X between the upper end portion 16C and the lower end portion 16D of the display panel 16 is determined. The display panel 16 is set in an upright posture. In the upright posture, the upper arm portion 30 has the intermediate portion 46 in contact with the upper arm fulcrum portion 34, and the lower arm portion 28 has the intermediate portion 52 in contact with the lower arm fulcrum portion 36.

  Next, the operation in the reverse tilt posture will be described. FIG. 6 is a schematic diagram illustrating a reverse tilt posture of the display panel according to the present embodiment. For example, when the slide drive unit 19 detects an operation from the operator to set the reverse tilt posture, the slide drive unit 19 moves the slide unit 18 from the initial position to the reverse tilt position. The reverse tilt position is a position on the direction X2 side from the initial position. That is, the slide drive unit 19 moves the slide unit 18 to the direction X2 side from the initial position. Thus, the slide drive unit 19 moves the end 18A of the slide unit 18 in the direction X2, rotates the lower arm unit 28 with the lower arm fulcrum unit 36 as a fulcrum, and moves the upper arm fulcrum unit 34 with the upper arm fulcrum unit 34 as a fulcrum. The arm part 30 is rotated. Thereby, the slide drive unit 19 sets the display panel 16 to the reverse tilt posture. Hereinafter, this operation will be described in more detail.

  As shown in FIG. 6, when the slide portion 18 moves to the direction X2 side from the initial position, the end portion 18A of the slide portion 18 moves to the direction X2 side, and the middle fulcrum portion 32 connected to the end portion 18A also moves. Accordingly, it moves in the direction X2. When the middle fulcrum part 32 moves in the direction X2, a force directed in the direction X2 also acts on the other end 44 of the upper arm part 30. Thereby, the upper arm portion 30 rotates around the axis along the direction Y on the intermediate portion 46 with the upper arm fulcrum portion 34 as a fulcrum. By this rotation, a moment in the direction X2 and the direction Z1 (counterclockwise moment in FIG. 6) acts on the other end 44 of the upper arm portion 30. The other end portion 44 of the upper arm portion 30 moves to the direction X2 side from the position in the upright posture as the slide portion 18 moves. A moment in the direction X1 and the direction Z2 (counterclockwise moment in FIG. 6) acts on one end portion 42 of the upper arm portion 30. Due to this moment, one end portion 42 of the upper arm portion 30 moves slightly from the position in the upright posture toward the direction X1 side and slightly toward the direction Z2 side (less than the amount of movement toward the direction X1 side). . Then, the one end portion 42 of the upper arm portion 30 applies the force in the direction X1 and the direction Z2 to the upper end portion 16C of the display panel 16 via the upper connection portion 26. As a result, the upper arm portion 30 moves the upper end portion 16C of the display panel 16 slightly toward the direction Z2 side (less than the amount of movement toward the direction X1 side) while moving toward the direction X1 side. At this time, one end portion 42 of the upper arm portion 30 causes the projection 43 to move along the groove portion 40 from the upper end portion 16C side to the lower end portion 16D side, that is, the groove portion 40 side. It moves from the end surface on the upper end portion 16C side to the end surface on the lower end portion 16D side.

  Further, as shown in FIG. 6, when the middle fulcrum portion 32 moves in the direction X <b> 2, a force directed in the direction X <b> 2 also acts on the other end portion 50 of the lower arm portion 28. Accordingly, the lower arm portion 28 rotates around an axis along the direction Y on the intermediate portion 52 with the lower arm fulcrum portion 36 as a fulcrum. By this rotation, a moment in the direction X2 and the direction Z2 (clockwise moment in FIG. 6) acts on the other end portion 50 of the lower arm portion 28. The other end portion 50 of the lower arm portion 28 moves from the position in the upright posture to the direction X2 side as the slide portion 18 moves. On the other hand, a moment in the direction X1 and the direction Z1 (clockwise moment in FIG. 6) acts on one end 48 of the lower arm portion. Due to this moment, one end 48 of the lower arm portion 28 moves from the position in the upright posture to the direction X1 side, and slightly to the direction Z1 side (less than the movement amount to the direction X1 side). . Then, one end 48 of the lower arm 28 applies a force in the direction X1 and the direction Z1 to the lower end 16D of the display panel 16 via the lower fulcrum 22. As a result, the lower arm portion 28 moves the lower end portion 16D of the display panel 16 slightly toward the direction Z1 side (less than the movement amount toward the direction X1 side) while moving toward the direction X1 side.

  Here, the upper arm portion 30 makes the amount of movement of the upper end portion 16C of the display panel 16 in the direction X1 larger than the amount of movement of the lower end portion 16D of the display panel 16 in the direction X1 by the lower arm portion 28. . Therefore, the display panel 16 has a reverse tilt posture in which the upper end portion 16C protrudes toward the direction X1 from the lower end portion 16D. Further, at this time, since the upper end portion 16C and the lower end portion 16D protrude in the direction X1 (does not move in the direction X2), the display panel 16 enters the inside of the housing 12 even in the reverse tilt posture. do not do.

  As shown in FIG. 6, in the auxiliary portion 38, the other end portion 66 moves to the direction X <b> 1 side via the fulcrum portion 62 as the upper end portion 16 </ b> C of the display panel 16 moves in the direction X <b> 1. And the auxiliary | assistant part 38 has one edge part 64 continuing to be located in the end surface by the side of the direction Z1 of the groove part 60 of the subpanel 14. FIG. Therefore, the auxiliary portion 38 rotates with the one end portion 64 as a fulcrum.

  As shown in FIG. 6, the protection plate 80 moves in the direction X <b> 1 side through the fulcrum 70 with one end 82 as the upper end 16 </ b> C of the display panel 16 moves in the direction X <b> 1. And as for the protection board 80, the projection part 85 of the other edge part 84 moves the groove part 76 of the connection part 74 to the direction Z1 side. Therefore, the protection plate 80 rotates around an axis along the direction Y on the one end portion 82 and covers the upper side (direction Z1 side) of the space V. The space V is a space generated between the sub panel 14 and the display panel 16 in the reverse tilt posture. Thereby, it can suppress that a foreign material mixes in the space V. FIG.

  Next, the operation in the forward tilt posture will be described. FIG. 7 is a schematic diagram showing a forward tilt posture of the display panel according to the present embodiment. For example, when the slide drive unit 19 detects an operation from the operator to set the forward tilt posture, the slide drive unit 19 moves the slide unit 18 from the initial position to the forward tilt position. The forward tilt position is a position on the direction X1 side from the initial position. That is, the slide drive unit 19 moves the slide unit 18 to the direction X1 side from the initial position. The slide drive unit 19 moves the end portion 18A of the slide portion 18 in the direction X1 and moves the lower end portion 16D of the display panel 16 in the direction X1 via the middle fulcrum portion 32 and the lower arm portion 28. Thereby, the slide drive unit 19 sets the display panel 16 to the forward tilt posture. Hereinafter, this operation will be described in more detail.

  As shown in FIG. 7, when the slide portion 18 moves to the direction X1 side from the initial position, the end portion 18A of the slide portion 18 moves to the direction X1 side, and the middle fulcrum portion 32 connected to the end portion 18A also moves. Accordingly, it moves in the direction X1. In this case, a force directed in the direction X1 also acts on the other end portion 44 of the upper arm portion 30. Therefore, a moment (clockwise moment in FIG. 7) with the direction Y on the one end portion 42 as the rotation center acts on the upper arm portion 30. However, the upper arm portion 30 is blocked by the display panel 16 and is prevented from rotating clockwise around the one end portion 42. In addition, the upper arm portion 30 may be provided with a spring or the like that applies a force that suppresses clockwise rotation around the one end portion 42 from the upright posture.

  Further, as shown in FIG. 7, when the middle fulcrum portion 32 moves in the direction X <b> 1, a force directed in the direction X <b> 1 also acts on the other end portion 50 of the lower arm portion 28. Therefore, a moment (a counterclockwise moment in FIG. 7) acts on the lower arm portion 28 with the direction Y on the one end portion 48 as the rotation center. However, the lower arm portion 28 is blocked by the display panel 16 and is prevented from rotating counterclockwise about the one end portion 48. Further, the lower arm portion 28 may be provided with a spring or the like that applies a force that suppresses counterclockwise rotation around the one end portion 48 from the upright posture.

  Due to the above action, the force of the middle fulcrum part 32 in the direction X1 is transmitted to the lower end part 16D of the display panel 16 via the lower arm part 28, and moves the lower end part 16D in the direction X1. Accordingly, a force directed in the direction Z2 acts on the upper end portion 16C of the display panel 16. Therefore, the other end portion 66 of the auxiliary portion 38 moves to the direction X1 side via the fulcrum portion 62. And as for the auxiliary | assistant part 38, the projection part 65 provided in the one edge part 64 moves the groove part 60 of the subpanel 14 toward the direction Z2 side. As a result, the upper end portion 16C of the display panel 16 moves in the direction Z2. In the upright posture and the reverse tilt posture, the intermediate portion 46 of the upper arm portion 30 is in contact with the upper arm fulcrum portion 34, and the intermediate portion 52 of the lower arm portion 28 is in contact with the lower arm fulcrum portion 36. . However, in the forward tilt posture, the intermediate portion 46 of the upper arm portion 30 is separated from the upper arm fulcrum portion 34, and the intermediate portion 52 of the lower arm portion 28 is separated from the lower arm fulcrum portion 36.

  By such an action, the display panel 16 has a forward tilt posture in which the lower end portion 16D protrudes toward the direction X1 from the upper end portion 16C.

  In the above description, the change from the erect posture to the reverse tilt posture and the change from the erect posture to the forward tilt posture have been described. That is, when changing from the erect posture to the reverse tilt posture, the electronic device 10 of the present embodiment can directly change to the reverse tilt posture without going through the forward tilt posture. Similarly, when the electronic device 10 according to the present embodiment is changed from the erect posture to the forward tilt posture, it can be directly changed to the forward tilt posture without going through the reverse tilt posture. When an operation for changing the forward tilt posture to the reverse tilt posture is detected, the slide drive unit 19 moves the slide unit 18 from the forward tilt position to the reverse tilt position through the initial position. Accordingly, the display panel 16 changes from the reverse tilt posture to the forward tilt posture through the upright posture. Similarly, when an operation for changing the reverse tilt posture to the forward tilt posture is detected, the slide drive unit 19 moves the slide unit 18 from the reverse tilt position to the forward tilt position through the initial position. Accordingly, the display panel 16 changes from the reverse tilt posture to the forward tilt posture through the upright posture.

  As described above, the electronic apparatus 10 according to the present embodiment includes the housing 12, the display panel 16 provided on the front surface of the housing 12 (the direction X1 side of the sub panel 14), the slide portion 18, and the lower fulcrum portion. 22, an upper connection part 26, a lower arm part 28, an upper arm part 30, a middle fulcrum part 32, an upper arm fulcrum part 34, and a lower arm fulcrum part 36. The slide portion 18 is provided in the housing 12, and a retreat direction (direction X <b> 2) that is a direction from the front surface (subpanel 14) of the housing 12 to the surface 15 opposite to the front surface, and a forward movement opposite to the retreat direction. It can move in the direction (direction X1). The lower fulcrum portion 22 is provided on the back surface 16B, which is the surface of the display panel 16 on the housing 12 side. The upper connection portion 26 is provided on the upper end portion (upper end portion 16 </ b> C) side of the display panel 16 with respect to the lower fulcrum portion 22 of the back surface 16 </ b> B of the display panel 16. The lower arm portion 28 is provided between the front surface (sub-panel 14) of the housing 12 and the rear surface 16B of the display panel 16, and one end portion 48 is rotatably connected to the lower fulcrum portion 22. The upper arm portion 30 is provided between the front surface (sub-panel 14) of the housing 12 and the back surface 16B of the display panel 16, and one end portion 42 with respect to the upper connection portion 26 is an upper end portion 16C and a lower end portion 16D. Are movably connected along the direction connecting the two. The middle fulcrum portion 32 is provided between the front surface (sub-panel 14) of the housing 12 and the back surface 16B of the display panel 16. The middle fulcrum portion 32 is rotatable with respect to the end portion 18A on the front surface side of the housing 12 of the slide portion 18, the other end portion 50 of the lower arm portion 28, and the other end portion 44 of the upper arm portion 30. Connect to. The upper arm fulcrum part 34 is provided on the front surface (sub-panel 14) of the housing 12 and contacts the intermediate part 46 of the upper arm part 30. The lower arm fulcrum part 36 is provided on the front surface (sub-panel 14) of the housing 12 and contacts the intermediate part 52 of the lower arm part 28.

  Since the electronic apparatus 10 has the above-described structure, the following operation can be performed by moving the slide portion 18 in the backward direction (direction X2). That is, the electronic device 10 rotates the lower arm portion 28 with the lower arm fulcrum portion 36 as a fulcrum by moving the other end portion 50 of the lower arm portion 28 to the direction X1 side via the middle fulcrum portion 32. Accordingly, the electronic device 10 moves the lower end portion 16D of the display panel 16 to the direction X1 side via the one end portion 48 of the lower arm portion 28. And the electronic device 10 rotates the upper arm part 30 by using the upper arm fulcrum part 34 as a fulcrum by moving the other end part 44 of the upper arm part 30 to the direction X1 side via the middle fulcrum part 32. Accordingly, the electronic device 10 moves the upper end portion 16C of the display panel 16 to the direction X1 side from the lower end portion 16D via the one end portion 42 of the upper arm portion 30. Therefore, the electronic device 10 can set the display panel 16 to the reverse tilt posture, and the lower end portion 16D is moved in the direction X1. Therefore, the lower end portion 16D of the display panel 16 enters the housing 12. To suppress. In addition, since the electronic device 10 does not include the upper arm unit 30 and the lower arm unit 28 for moving the display panel 16 inside the housing 12, a space in the housing 12 can be secured.

  The slide portion 18 moves the lower arm fulcrum portion 36 from the initial position where the back surface 16B of the display panel 16 is positioned along the front surface (subpanel 14) of the housing 12 in the backward direction (direction X2). The lower arm portion 28 is rotated as a fulcrum, and the upper arm portion 30 is rotated with the upper arm fulcrum portion 34 as a fulcrum, so that the display panel 16 is in a reverse tilt posture. The electronic apparatus 10 suppresses the lower end portion 16D of the display panel 16 from entering the housing 12 by setting the display panel 16 to the reverse tilt posture through such an operation.

  Further, when the slide portion 18 moves in the backward direction (direction X2) from the initial position, the lower arm portion 28 moves in the backward direction (direction X2) side with the movement of the middle fulcrum portion 32. Then, the one end 48 moves toward the forward direction (direction X1), thereby causing the lower end 16D of the display panel 16 to protrude in the forward direction. Then, when the slide part 18 moves in the backward direction (direction X2) from the initial position, the upper arm part 30 moves in the backward direction (direction X2) side with the movement of the middle fulcrum part 32. Then, the one end portion 42 moves in the forward direction (direction X1) side, so that the upper end portion 16C of the display panel 16 protrudes in the forward direction (direction X1) side from the lower end portion 16D. The electronic apparatus 10 suppresses the lower end portion 16D of the display panel 16 from entering the housing 12 by setting the display panel 16 to the reverse tilt posture through such an operation.

  In addition, the slide portion 18 moves in the forward direction (direction X1) from the initial position, thereby moving the lower end portion 16D of the display panel 16 in the forward direction (direction X1) via the middle fulcrum portion 32 and the lower arm portion 28. Thus, the display panel 16 is set to the forward tilt posture. The electronic device 10 can be changed from the upright posture to the forward tilt posture without going through the reverse tilt posture by adopting the forward tilt posture by such an operation.

  Further, the length from one end portion 42 of the upper arm portion 30 to the other end portion 44 is longer than the length from one end portion 48 of the lower arm portion 28 to the other end portion 50. Thereby, the electronic device 10 can appropriately set the display panel 16 to the reverse tilt posture.

  The electronic device 10 further includes a protective plate 80. The protective plate 80 is provided between the front surface (subpanel 14) of the housing 12 and the back surface 16B of the display panel 16, and one end portion 82 is rotatable to the display panel 16 (fulcrum portion 70 in this embodiment). It is attached and the other end 84 is connected to the housing 12 (in this embodiment, the connecting portion 74). When the slide portion 18 moves in the backward direction (direction X2) from the initial position, the protective plate 80 moves in the forward direction (direction X1) side with the movement of the display panel 16, The upper side of the space V is covered in the reverse tilt posture. This space V is a space generated between the front surface (sub-panel 14) of the housing 12 and the back surface 16B of the display panel 16 in the reverse tilt posture. In the electronic device 10, the protective plate 80 covers the space V in the reverse tilt posture, so that foreign matter can be prevented from entering the space V.

  In the present embodiment, the display panel 16 can be moved by driving the slide unit 18 by the slide drive unit 19. The display panel 16 is moved by moving the slide portion 18 in the backward direction (direction X2) from the initial position, thereby rotating the lower arm portion 28 with the lower arm fulcrum portion 36 as a fulcrum and moving the upper arm fulcrum portion 34 to the upper arm fulcrum portion 34. The upper arm part 30 is rotated as a fulcrum, and the display panel 16 is set in the reverse tilt posture. According to this method of moving the display panel 16, it is possible to appropriately tilt a large display panel, and the lower end portion 16 </ b> D of the display panel 16 enters the housing 12 when the display panel 16 is in a reverse tilt posture. Can be suppressed.

  As mentioned above, although embodiment of this invention was described, embodiment is not limited by the content of these embodiment. In addition, the above-described constituent elements include those that can be easily assumed by those skilled in the art, those that are substantially the same, and those in a so-called equivalent range. Furthermore, the above-described components can be appropriately combined. Furthermore, various omissions, substitutions, or changes of the components can be made without departing from the spirit of the above-described embodiment.

DESCRIPTION OF SYMBOLS 10 Electronic device 12 Case 14 Sub panel 16 Display panel 16B Back surface 18 Slide part 18A End part 19 Slide drive part 22 Lower fulcrum part 26 Upper connection part 28 Lower arm part 30 Upper arm part 32 Middle fulcrum part 34 Upper arm fulcrum part 36 Lower Arm fulcrum 42, 48 One end 44, 50 The other end

Claims (7)

A housing,
A display panel provided on the front surface of the housing;
A slide part that is provided in the housing and is movable in a backward direction that is a direction from the front surface of the housing to a surface opposite to the front surface, and a forward direction opposite to the backward direction;
A lower fulcrum portion provided on the back surface which is the surface of the display panel on the housing side;
An upper connecting portion provided on an upper end side of the display panel with respect to the lower fulcrum portion on the back surface of the display panel;
A lower arm portion provided between the front surface of the housing and the back surface of the display panel, and having one end rotatably connected to the lower fulcrum portion;
An upper arm portion provided between the front surface of the housing and the back surface of the display panel, one end of which is movably connected to the upper connection portion;
Provided between the front surface of the housing and the back surface of the display panel, and the end portion of the slide portion on the front surface side of the housing, the other end portion of the lower arm portion, and the other end of the upper arm portion. A middle fulcrum part that connects the parts to each other in a rotatable manner;
An upper arm fulcrum provided on the front surface of the housing and in contact with a location between the one end and the other end of the upper arm;
A lower arm fulcrum provided on the front surface of the housing and in contact with a location between the one end of the lower arm and the other end;
Electronic equipment having   The slide part rotates in the backward direction from the initial position in which the back surface of the display panel is in an upright posture along the front surface of the housing, thereby rotating the lower arm part with the lower arm fulcrum part as a fulcrum. The upper arm portion is rotated with the upper arm fulcrum portion as a fulcrum, and the display panel is set to a reverse tilt posture in which the upper end protrudes toward the forward direction side from the lower end. The electronic device according to claim 1. When the slide portion moves in the backward direction from the initial position, the lower arm portion moves to the backward direction side with the movement of the middle fulcrum portion, and the one end portion Is moved to the forward direction side to project the lower end of the display panel in the forward direction,
When the slide portion moves in the backward direction from the initial position, the upper arm portion moves to the backward direction side with the movement of the middle fulcrum portion, and the one end portion The electronic apparatus according to claim 2, wherein the upper end portion of the display panel protrudes more toward the forward direction side than the lower end portion by moving toward the forward direction side.   The slide portion moves in the forward direction from the initial position, thereby moving the lower end of the display panel in the forward direction via the middle fulcrum portion and the lower arm portion, and the display 4. The electronic device according to claim 2, wherein the panel has a forward tilt posture in which the lower end protrudes toward the forward direction side from the upper end. 5.   The length from the one end to the other end of the upper arm is longer than the length from the one end to the other end of the lower arm. Item 5. The electronic device according to any one of items 4 to 4. There is further provided a protective plate provided between the front surface of the housing and the back surface of the display panel, one end of which is rotatably attached to the display panel and the other end connected to the housing. And
When the slide part moves in the backward direction from the initial position, the protective plate moves in the forward direction along with the movement of the display panel, so that the reverse tilt posture is achieved. The electronic device according to claim 1, wherein the electronic device covers an upper side of a space generated between the front surface of the housing and the back surface of the display panel. A method of moving a display panel included in the electronic device according to claim 1,
By moving the slide part in the backward direction from the initial position with the back surface of the display panel along the front surface of the housing, the upper arm part is rotated with the upper arm fulcrum part as a fulcrum, By rotating the lower arm portion with the lower arm fulcrum portion as a fulcrum, the display panel has a reverse tilt posture in which the upper end portion protrudes in the forward direction direction from the lower end portion. A method for moving a display panel, comprising steps.

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