JP2018128791A - Portable terminal - Google Patents

Abstract

[Problem] To provide a technology that improves the operability of a mobile terminal by a user. [Solution] The mobile terminal comprises a main body that can be held by a user, an operation unit provided on the front side of the main body, and a belt provided on the rear side of the main body into which the user can insert his/her finger, the belt being slidable in the vertical direction between an upper end position and a lower end position on the rear side of the main body. [Selected Figure] Figure 1

Description

  The technology disclosed in this specification relates to a portable terminal including an operation unit.

  Patent Document 1 discloses a portable terminal including an operation button and a touch panel. The portable terminal further includes a belt unit for inserting a finger when the user holds the case main body of the portable terminal.

JP 2013-50807 A

  In the technique of Patent Document 1, a user normally uses a portable terminal using only one hand. Specifically, the user inserts a finger excluding the thumb into the belt unit to hold the case body, and operates the operation button or the touch panel with the thumb. In this case, since the finger inserted into the belt unit is difficult to move, for example, when the operation button and the touch panel are arranged over a wide range of the mobile terminal, the user can use the thumb as the operation button or the operation part of the touch panel. May be difficult to reach. The present specification discloses a technique for improving the operability of a mobile terminal by a user.

  The portable terminal disclosed in this specification is provided with a main body that can be gripped by a user, an operation unit provided on the front surface of the main body, and a rear surface of the main body, and can insert the user's finger. The belt is slidable in the vertical direction between the upper end position and the lower end position on the rear surface of the main body.

  In the portable terminal described above, the user can slide the belt in the vertical direction between the upper end position and the lower end position on the rear surface of the main body with the finger inserted into the belt. Accordingly, the user can move the finger inserted into the belt to a position where the operation unit can be easily operated by sliding the belt. Therefore, according to said portable terminal, the operativity of the portable terminal by a user can be improved.

The perspective view of a portable terminal is shown. The rear view of the portable terminal of 1st Example is shown. III-III sectional drawing of FIG. 2 is shown. The perspective view of a portable terminal in the state where the belt is arranged near the upper end position is shown. The perspective view of the portable terminal of the state where the belt is arrange | positioned near the lower end position is shown. The rear view of the portable terminal of 2nd Example is shown. The figure explaining the holding | maintenance part for hold | maintaining a belt is shown. The rear view of the portable terminal of 3rd Example is shown. IX-IX sectional drawing of FIG. 8 is shown. The flowchart of the process of a portable terminal is shown. The rear view of the portable terminal of 4th Example is shown.

  The main features of the embodiments described below are listed. In addition, the technical elements shown below are independent technical elements and exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. .

(Characteristic 1) The belt is arranged in a position where the lower end position is higher than the upper end position from an upright state where the upper end position of the portable terminal is higher than the lower end position. When changing to the inverted state, the rear surface of the main body slides in the direction toward the lower end position, and when the posture of the mobile terminal changes from the inverted state to the upright state, the rear surface of the main body , It may slide in the direction toward the upper end position.

  According to the configuration of feature 1, the belt slides in response to the posture of the mobile terminal changing between the upright state and the inverted state. That is, the user can easily move the finger inserted into the belt by changing the posture of the mobile terminal.

(Feature 2) The portable terminal may further include a holding unit for holding the belt at a predetermined position between the upper end position and the lower end position on the rear surface of the main body.

(Characteristic 3) The holding portion includes a torsion coil spring. When the torsion coil spring is not elastically deformed, the holding unit holds the belt at the predetermined position, and the torsion coil spring is elastically deformed. The belt may not be held at the predetermined position.

  According to the features 2 and 3, the mobile terminal can hold the belt in a predetermined position. This prevents the belt from sliding against the user's intention and prevents the finger inserted into the belt from moving to a position not intended by the user.

(Feature 4) The portable terminal further includes a sensor that detects an inclination of an axis connecting the upper end position and the lower end position with respect to a horizontal plane, and the holding unit has an inclination smaller than a predetermined threshold by the sensor. If detected, the belt is held at the predetermined position, and the belt may not be held at the predetermined position when the sensor detects an inclination larger than the predetermined threshold. .

  When a user operates a mobile terminal, the front surface of the main body of the mobile terminal is often directed upward. Moreover, the axis | shaft which connects an upper end position and a lower end position among the back surfaces of a main body is often inclined comparatively small with respect to a horizontal surface. According to the configuration of the feature 4, when the posture of the mobile terminal is a posture in which the user is highly likely to operate the mobile terminal, the belt can be held in a predetermined position. Therefore, the belt can be prevented from sliding while the user operates the mobile terminal.

(Feature 5) The holding portion holds the belt at the upper end position when the belt is arranged at the upper end position, and holds the belt when the belt is arranged at the lower end position. It is not necessary to hold at the lower end position.

  When the belt is arranged at the uppermost position (that is, the upper end position) of the belt movable range, the user is likely to hold the finger inserted into the belt as high as possible. In this case, it is highly possible that the belt slides toward the lower end position against the user's intention. In addition, when the belt is disposed at the lowest position (that is, the lower end position) of the belt movable range, the user may want to hold the finger inserted into the belt as low as possible. high. In this case, it is highly possible that the belt slides toward the upper end position against the user's intention. According to the configuration of the characteristic 5, the mobile terminal can prevent the belt from moving in these cases against the user's intention.

(First embodiment)
With reference to FIGS. 1-5, the portable terminal 10a of a present Example is demonstrated. As shown in FIG. 1, the mobile terminal 10a is an optical information reader for reading an information code (for example, a barcode or a two-dimensional code). The mobile terminal 10a includes a main body 2, a display screen 4, an operation unit 5, two key buttons 6 (only one key button is shown in FIG. 1), a reading unit 7, Is provided. Hereinafter, of the surfaces of the main body 2, a surface that is parallel to the XY plane of the coordinate system in the drawing and faces in the positive direction of the Z axis is referred to as a “front surface”. Of each surface of the main body 2, a surface that is parallel to the XY plane of the coordinate system in the drawing and faces the negative direction of the Z axis is referred to as a “rear surface”. Of the surfaces of the main body 2, two surfaces that are parallel to the YZ plane of the coordinate system in the drawing are called “side surfaces”. Of the ends of the main body 2, the negative and positive ends of the Y axis are referred to as “upper end” and “lower end”, respectively.

  The display screen 4 is a liquid crystal screen provided on the front surface of the main body 2. The display screen 4 can display information recorded in the read information code, information input to the operation unit 5, and the like. The display screen 4 also functions as a so-called touch panel (that is, also functions as an operation unit). The operation unit 5 is provided on the front surface of the main body 2. The operation unit 5 is located in the positive direction of the Y axis when viewed from the display screen 4. The operation unit 5 includes a plurality of buttons. The user can input various instructions to the mobile terminal 10 a by operating the operation unit 5.

  A key button 6 is provided on each of the two side surfaces of the main body 2. When the user presses one or both of the two key buttons 6 in the direction toward the side surface (X-axis direction), a reading instruction is input to the mobile terminal 10a. The reading instruction is an instruction for the mobile terminal 10 a to read the information code using the reading unit 7.

  A rubber belt 9 is provided on the lower surface of the main body 2. The belt 9 viewed from the X-axis direction has a ring shape. Four fingers other than the user's thumb can be inserted into the belt 9 (specifically, the internal space of the belt 9). The user can grip the main body 2 with four fingers inserted into the belt 9. As will be described in detail later, the belt 9 is slidable in the vertical direction (that is, the Y-axis direction) between the upper end position and the lower end position on the rear surface of the main body 2.

  As shown in FIG. 2, a groove 12 is provided on the rear surface of the main body 2 along the Y-axis direction. As shown in FIG. 3, the cross section of the groove 12 cut along the XZ plane has a T shape with the negative direction of the Z axis as the upper side.

  A slide member 14 is fitted in the groove 12. The cross section of the slide member 14 cut along the XZ plane has substantially the same shape as the cross section of the groove 12, but is slightly smaller. In the Y-axis direction, the length of the slide member 14 is smaller than the length of the groove 12. The slide member 14 includes a protruding portion 14a that protrudes from the inside of the main body 2 in the positive direction of the Z axis. The belt 9 is joined to the protruding portion 14a. In the Y-axis direction, the length of the protrusion 14 a is substantially equal to the length of the belt 9. Accordingly, the slide member 14 and the belt 9 can slide in the vertical direction along the groove 12 between the upper end position and the lower end position on the rear surface of the main body 2.

  The mechanism by which the belt 9 slides will be described with reference to FIGS. 4 and 5, the downward direction of the drawing is the direction of gravity. In FIG. 4, the posture of the mobile terminal 10 a is a state where the upper end position is arranged at a position higher than the lower end position (hereinafter referred to as “upright state”). In this case, the main body 2 is pulled in the positive direction of the Y axis by gravity with reference to the position of the belt 9 fixed by the user's finger. In other words, the belt 9 is pulled in the negative direction of the Y axis with reference to the position of the main body 2. In this case, the slide member 14 joined to the belt 9 slides in the groove 12 toward the upper end position by being pulled in the negative direction of the Y axis, and contacts the upper end of the groove 12. As a result, the belt 9 is disposed at the upper end position. In the state of FIG. 4, since the user's thumb is located near the display screen 4, the user can easily operate the touch panel. Hereinafter, the movement of the belt 9 as the slide member 14 slides may be referred to as “the belt 9 slides”.

  In FIG. 5, the posture of the mobile terminal 10a is a state where the lower end position is higher than the upper end position (hereinafter referred to as “inverted state”). In this case, the main body 2 is pulled in the negative direction of the Y axis by gravity with reference to the position of the belt 9 fixed by the user's finger. In other words, the belt 9 is pulled in the positive direction of the Y axis with respect to the position of the main body 2. In this case, the slide member 14 joined to the belt 9 slides in the groove 12 toward the lower end position by being pulled in the positive direction of the Y axis, and contacts the lower end of the groove 12. As a result, the belt 9 is disposed at the lower end position. In the state of FIG. 5, the user's thumb is located near the operation unit 5, so that the user can easily operate the operation unit 5.

  The user can change the attitude of the mobile terminal 10a between the upright state of FIG. 4 and the inverted state of FIG. When the posture of the mobile terminal 10a changes from the upright state to the inverted state, the belt 9 slides on the rear surface of the main body 2 in the positive direction of the Y axis (that is, in the direction toward the lower end position). Further, when the posture of the mobile terminal 10a changes from the inverted state to the upright state, the belt 9 slides on the rear surface of the main body 2 in the negative direction of the Y axis (that is, in the direction toward the upper end position).

(Effects of the first embodiment)
In the mobile terminal 10a of the present embodiment, the user inserts his / her finger into the belt 9 and moves the belt 9 in the vertical direction (that is, in the Y-axis direction) between the upper end position and the lower end position on the rear surface of the main body 2. It can be slid (see FIGS. 4 and 5). Thereby, the user can move the finger inserted into the belt 9 to a position where the touch panel or the operation unit 5 can be easily operated by sliding the belt 9. Therefore, according to the mobile terminal 10a, the operability of the mobile terminal 10a by the user can be improved.

  Further, the belt 9 slides in response to the change of the posture of the mobile terminal 10a between the upright state of FIG. 4 and the inverted state of FIG. That is, the user can easily move the finger inserted into the belt 9 by changing the posture of the mobile terminal 10a.

(Second embodiment)
With reference to FIGS. 6 and 7, the present embodiment will be described focusing on differences from the first embodiment. The mobile terminal 10b of the present embodiment includes holding portions 21a to 21d for holding the belt 9 in a predetermined position.

  Each part 2, 4, 5, 6, 7, 9, 12, 14 of the portable terminal 10b of the present embodiment is the same as that of the first embodiment. In the mobile terminal 10 b, as shown in FIGS. 6 and 7, the rear surface of the main body 2 includes four holding portions 21 a to 21 d for holding the belt 9. The holding portions 21a to 21d include struts 22a to 22d and torsion springs 24a to 24d wound around the struts 22a to 22d.

  In the holding part 21a, the central part of the torsion spring 24a is wound around the support 22a. In a state where both end portions of the torsion spring 24a are not elastically deformed, one end portion 25a of the torsion spring 24a extends in the negative direction of the X axis, and the other end portion 26a of the torsion spring 24a is It extends in the negative direction of the shaft. The end portion 26a is fixed so as not to rotate. The holding part 21b has a configuration symmetrical to the holding part 21a with the center line L1 extending along the Y-axis direction as the axis of symmetry. The holding parts 21c and 21d have configurations symmetrical to the holding parts 21a and 21b, respectively, with the center line L2 extending along the X-axis direction as the axis of symmetry.

  As shown in FIG. 6, the relationship between the holding portions 21 a to 21 d and the belt 9 when the position of the belt 9 is the lower end position (that is, the posture of the mobile terminal 10 b is the inverted state of FIG. 5) will be described. To do. An end portion 25a extending in the negative direction of the X axis of the torsion spring 24a and an end portion 25b extending in the positive direction of the X axis of the torsion spring 24b are in contact with the upper end of the slide member 14 (see FIG. 3). Thus, the belt 9 is held at the lower end position. An end portion 25c of the torsion spring 24c extending in the negative direction of the X axis is pushed by the slide member 14 and moved to a position that rotates counterclockwise with the support column 22c as a fulcrum (that is, the torsion spring 24c is elastically deformed). doing). Since the other end 26c is fixed, the position does not change. Similarly, the end 25d of the torsion spring 24d extending in the positive direction of the X-axis is pushed by the slide member 14 and moved to a position that rotates clockwise around the support 22d (that is, the torsion spring 24d is rotated). Elastically deformed). Since the other end 26d is fixed, the position does not change. The torsion springs 24 c and 24 d in this state are not in contact with the end of the slide member 14. That is, the torsion springs 24 c and 24 d in this state do not contribute to the holding of the belt 9 at the lower end position.

  The movement of the belt 9 when the posture of the mobile terminal 10b changes from the inverted state of FIG. 6 to the upright state will be described. Here, the erect state is the first erect state where the difference in height between the upper end position and the lower end position is small (that is, the inclination of the axis connecting the upper end position and the lower end position is small) and the upper end position. And a second upright state in which the difference in height between the lower end position and the lower end position is large (the inclination of the axis connecting the upper end position and the lower end position with respect to the horizontal plane is large). Hereinafter, the inclination of the axis connecting the upper end position and the lower end position with respect to the horizontal plane is referred to as “inclination”.

  When the posture of the mobile terminal 10b changes to the first erect state or the second erect state, the slide member 14 is pulled in the negative direction of the Y axis with respect to the position of the main body 2. Thereby, the slide member 14 pushes up the torsion springs 24a and 24b in the negative direction of the Y axis. In this case, the torsion springs 24a and 24b are elastically deformed when the force for pushing up the torsion springs 24a and 24b is equal to or greater than a certain value, but when the force is less than the certain value, the torsion springs 24a and 24b are almost Does not elastically deform.

  In the first upright state, since the inclination of the main body 2 is small, the Y-axis component of gravity applied to the main body 2 is small. Therefore, the force pulling the belt 9 and the slide member 14 is small, and the force by which the slide member 14 pushes up the end portions 25a and 25b of the torsion springs 24a and 24b is less than a certain value. Therefore, the torsion springs 24a and 24b are hardly elastically deformed. As a result, in the first upright state, the torsion springs 24a and 24b continue to hold the belt 9 at the lower end position.

  On the other hand, since the inclination of the main body 2 is large in the second upright state, the Y-axis component of gravity applied to the main body 2 is large. Therefore, the force pulling the belt 9 and the slide member 14 is large, and the force by which the slide member 14 pushes up the end portions 25a and 25b of the torsion springs 24a and 24b is a certain value or more. Therefore, the torsion springs 24a and 24b are elastically deformed. That is, the end 25a of the torsion spring 24a moves so as to rotate clockwise around the support 22a, and the end 25b of the torsion spring 24b moves so as to rotate counterclockwise around the support 22b. To do. As a result, in the second upright state, the state in which the torsion springs 24a and 24b hold the belt 9 at the lower end position is released, and the belt 9 slides in the negative direction of the Y axis.

  Although not shown, the relationship between the holding portions 21a to 21d and the belt 9 when the position of the belt 9 is the lower end position (that is, the posture of the mobile terminal 10b is in the upright state in FIG. 4) will be described. To do. As described above, the end 25a of the torsion spring 24a has moved to a position that rotates clockwise with the support 22a as a fulcrum. The end 25b of the torsion spring 24b has moved to a position that rotates counterclockwise with the support 22b as a fulcrum. The torsion springs 24 a and 24 b in this state are not in contact with the end of the slide member 14. That is, the torsion springs 24 a and 24 b in this state do not contribute to the holding of the belt 9 at the upper end position. On the other hand, the end 25c of the torsion spring 24c and the end 25d of the torsion spring 24d are released from being pressed by the slide member 14, and return to their original positions by elastic force. The end 25c and the end 25d that have returned to their original positions come into contact with the lower end of the slide member 14, whereby the belt 9 is held at the upper end position.

  The movement of the belt 9 when the posture of the mobile terminal 10b changes from the upright state to the inverted state will be described. Here, in the inverted state, the first inverted state in which the height difference between the upper end position and the lower end position is small (that is, the inclination of the axis connecting the upper end position and the lower end position with respect to the horizontal plane is small), the upper end position, and the lower end position. The second inverted state in which the difference in height from the position is large (the inclination of the axis connecting the upper end position and the lower end position with respect to the horizontal plane is large) is classified.

  The first inverted state and the second inverted state can be considered in the same manner as the first upright state and the second upright state described above. That is, in the first inverted state, the torsion springs 24c and 24d hold the belt 9 at the upper end position. In the second inverted state, the state in which the torsion springs 24c and 24d hold the belt 9 in the upper end position is released, and the belt 9 slides in the positive direction of the Y axis.

(Effect of the second embodiment)
Also in the mobile terminal 10b of the present embodiment, the operability of the mobile terminal 10b by the user can be improved as in the first embodiment. In the present embodiment, the mobile terminal 10b can hold the belt 9 at the upper end position or the lower end position by the torsion springs 24a to 24d. Thereby, it is possible to prevent the belt 9 from sliding against the user's intention and moving the finger inserted into the belt 9 to a position not intended by the user. Specifically, the user can maintain the belt 9 at the lower end position even when the posture of the mobile terminal 10b is changed from the inverted state to the first upright state. Further, the user can maintain the belt 9 at the upper end position even when the posture of the mobile terminal 10b is changed from the upright state to the first inverted state.

  Further, when the belt 9 is disposed at the upper end position, the user is highly likely to hold the finger inserted into the belt 9 as high as possible. In this case, it is highly possible that the belt 9 slides toward the lower end position against the user's intention. Moreover, when the belt 9 is arrange | positioned in a lower end position, a user has high possibility of holding the finger inserted in the belt 9 as low as possible. In this case, it is highly possible that the belt 9 slides toward the upper end position against the user's intention. In the present embodiment, the mobile terminal 10b holds the belt 9 by the torsion springs 24a to 24d when the belt 9 is arranged at the upper end position or the lower end position. It can be prevented from moving.

(Third embodiment)
With reference to FIGS. 8 to 10, the present embodiment will be described with a focus on differences from the first embodiment. In the mobile terminal 10c of this embodiment, a CPU (not shown) in the mobile terminal 10c controls the holding unit 33.

  Each part 2, 4, 5, 6, 7, 9 of the portable terminal 10c of the present embodiment is the same as that of the first embodiment. In the present embodiment, the structures of the groove 32 and the slide member 14 are different from those of the first embodiment. As shown in FIG. 9, the mobile terminal 10 c further includes a sensor 31 inside the main body 2. The sensor 31 is an inclination sensor, an acceleration sensor, or the like for detecting the inclination of the main body 2.

  As shown in FIG. 8, a groove 32 is provided on the rear surface of the main body 2 along the Y-axis direction. The width of the groove 32 in the X-axis direction is basically constant. However, along the Y-axis direction of the groove 32, there are provided protruding groove portions 32a and 32c protruding in the positive direction of the X-axis and protruding groove portions 32b and 32d protruding in the negative direction of the X-axis. The protruding groove portions 32a and 32b face each other along the X axis, and the protruding groove portions 32c and 32d face each other along the X axis.

  The protruding portion 14a of the slide member 14 includes a holding portion 33 on each of two surfaces facing the positive direction and the negative direction of the X axis. The two holding portions 33 are disposed near the center of the protruding portion 14a in the Y-axis direction. The two holding portions 33 protrude from the protruding portion 14a in the positive and negative directions of the X axis (see FIG. 9), and are stored in the protruding portion 14a and are not protruded from the protruding portion 14a. An expansion / contraction mechanism (not shown) that changes between states is incorporated. The expansion / contraction mechanism is controlled by the CPU in the mobile terminal 10c executing the process shown in FIG.

  As shown in FIG. 8, when the belt 9 is disposed at the lower end position (that is, the posture of the mobile terminal 10c is the inverted state of FIG. 5), and the two holding portions 33 are in the protruding state, FIG. 2, the two holding portions 33 are fitted into the protruding groove portions 32c and 32d. In this case, the two holding portions 33 hold the belt 9 at the lower end position. Although not shown, when the belt 9 is disposed at the upper end position (that is, the posture of the mobile terminal 10c is in the upright state in FIG. 4), and the two holding portions 33 are in the protruding state, The two holding portions 33 are fitted into the protruding groove portions 32a and 32b. In this case, the two holding portions 33 hold the belt 9 at the upper end position.

  With reference to FIG. 10, a process executed by a CPU (not shown) included in the mobile terminal 10c will be described. In S <b> 10, the CPU determines whether or not an inclination smaller than a predetermined threshold is detected by the sensor 31. The CPU proceeds to S20 when an inclination smaller than the predetermined threshold is detected (YES in S10), and proceeds to S30 when an inclination equal to or greater than the predetermined threshold is detected (NO in S10).

  In S20, the CPU operates the expansion / contraction mechanism to change the two holding portions 33 to the protruding state. If the two holding portions 33 are already in the protruding state at the time of S20, the CPU maintains the protruding state of the two holding portions 33 without operating the expansion / contraction mechanism. As a result, the belt 9 is held at the current position (that is, the lower end position or the upper end position). When S20 ends, the process returns to S10.

  In S30, the CPU operates the expansion / contraction mechanism to change the two holding portions 33 to the non-projecting state. Note that if the two holding portions 33 are already in the non-projecting state at the time of S30, the CPU maintains the non-projecting state of the two holding portions 33 without operating the expansion / contraction mechanism. As a result, the belt 9 is not held. That is, the belt 9 can slide. When S30 ends, the process returns to S10.

(Effect of the third embodiment)
Also in the mobile terminal 10c of the present embodiment, the operability of the mobile terminal 10c by the user can be improved as in the first embodiment.

  When the user operates the mobile terminal 10c, the front surface of the main body 2 of the mobile terminal 10c is often directed upward. In many cases, the inclination of the main body 2 is relatively small. In this embodiment, when the posture of the mobile terminal 10c is a posture in which the user is highly likely to operate the mobile terminal 10c (YES in S10 in FIG. 10), the belt 9 is held at the upper end position or the lower end position. (S20). Therefore, the belt 9 can be prevented from sliding while the user is operating the mobile terminal 10c. In this embodiment, the belt 9 can be automatically prevented from sliding by the control using the CPU.

(Fourth embodiment)
With reference to FIG. 11, the present embodiment will be described with a focus on differences from the first embodiment. In the mobile terminal 10d of the present embodiment, the user operates the holding units 41a to 41d.

  Each part 2, 4, 5, 6, 7, 9, 14 of the portable terminal 10c of the present embodiment is the same as that of the first embodiment. In this embodiment, the structure of the groove 42 is different from that of the first embodiment. As shown in FIG. 11, a groove 42 is provided on the rear surface of the main body 2 along the Y-axis direction. The width of the groove 42 in the X-axis direction is basically constant. However, along the Y-axis direction of the groove 42, there are provided protruding groove portions 42a and 42c protruding in the positive direction of the X-axis and protruding groove portions 42b and 42d protruding in the negative direction of the X-axis. The protruding groove portions 42a and 42b face each other along the X axis, and the protruding groove portions 42c and 42d face each other along the X axis.

  The mobile terminal 10 d includes four holding portions 41 a to 41 d for holding the belt 9. The holding parts 41a to 41d include locking members 43a to 43d and push springs 44a to 44d.

  The configuration of the holding unit 41a will be described. The locking member 43a of the holding portion 41a is slidable along the X-axis direction in the protruding groove portion 42a. The locking member 43a is urged in the negative direction in the X-axis direction (that is, the direction of the groove 42) by the pressing spring 44a. While the locking member 43a is not pressed by the slide member 14 (that is, while the pressing spring 44a is not elastically deformed), the distal end portion (that is, the end portion on the negative side of the X axis) of the locking member 43a. Is disposed at the position of the center line L1 (that is, protrudes into the groove 42). The holding part 41b has a configuration symmetrical to the holding part 41a with the center line L1 as the axis of symmetry. The holding portions 41c and 41d have configurations that are symmetrical with the holding portions 41a and 41b, respectively, with the center line L2 as the axis of symmetry. As shown in the holding portion 41c, while the locking member 43c is being pressed by the slide member 14 (that is, while the pressing spring 44c is elastically deformed), the distal end portion of the locking member 43c is in the groove 42. And is accommodated in the protruding groove 42c. Similarly, in the holding portion 41d, while the locking member 43d is pressed by the slide member 14 (that is, while the pressing spring 44d is elastically deformed), the distal end portion of the locking member 43d is in the groove 42. It does not protrude and is accommodated in the protruding groove 42d.

  As shown in FIG. 11, the relationship between the holding portions 41 a to 41 d and the belt 9 when the belt 9 is arranged at the lower end position (that is, the posture of the mobile terminal 10 d is the inverted state of FIG. 5). explain. The locking members 43 a and 43 b of the holding portions 41 a and 41 b are not pushed by the slide member 14. Therefore, the push springs 44a and 44b are not elastically deformed, and the distal ends of the locking members 43a and 43b are arranged at the position of the center line L1. And the locking members 43a and 43b arrange | positioned in such a position are contacting the upper end of the slide member 14 (refer FIG. 3), and are holding the belt 9 in a lower end position. On the other hand, the locking members 43c and 43d are in a state where the push springs are elastically deformed by being pushed by the slide member 14 and are accommodated in the protruding grooves 42c and 42d. The locking members 43c and 43d in this state are not in contact with the end portion of the slide member 14, and do not contribute to the holding of the belt 9 at the lower end position.

  In this embodiment, even if the posture of the mobile terminal 10d changes from the inverted state to the upright state, the positions of the locking members 43a and 43b do not change automatically, so the belt 9 is held at the lower end position. to continue. In this case, when the user spreads the locking members 43a and 43b in both directions of the X axis with fingers, the holding of the slide member 14 (that is, the belt 9) at the lower end position is released, and the slide member 14 is negative on the Y axis. Slide in the direction.

  Although not shown, regarding the relationship between each holding portion 41a to 41d and the belt 9 when the belt 9 is disposed at the lower end position (that is, the posture of the mobile terminal 10b is in the upright state of FIG. 4). explain. The locking members 43c and 43d of the holding portions 41c and 41d are not pushed by the slide member 14. Therefore, the push springs 44c and 44d are not elastically deformed, and the distal end portions of the locking members 43c and 43d are arranged at the position of the center line L1 (that is, project into the groove 42). And the locking members 43c and 43d arrange | positioned in such a position are contacting the lower end of the slide member 14 (refer FIG. 3), and the belt 9 is hold | maintained in an upper end position. On the other hand, the locking members 43a and 43b are in a state where the push springs are elastically deformed by being pushed by the slide member 14 and are accommodated in the protruding grooves 42a and 42b. The locking members 43a and 43b in this state are not in contact with the end portion of the slide member 14 and do not contribute to the holding of the belt 9 at the upper end position.

  Even when the posture of the mobile terminal 10d changes from the upright state to the inverted state, the positions of the locking members 43c and 43d do not change automatically, and thus the belt 9 is continuously held at the upper end position. In this case, when the user spreads the locking members 43c and 43d in both directions of the X axis with his / her fingers, the holding of the slide member 14 (that is, the belt 9) at the upper end position is released, and the slide member 14 is positively aligned with the Y axis. Slide in the direction.

(Effect of the fourth embodiment)
Also in the mobile terminal 10d of the present embodiment, the operability of the mobile terminal 10d by the user can be improved as in the first embodiment. Further, in a state where the belt 9 is held at the upper end position or the lower end position, the user selects whether to hold the belt 9 at the upper end position or the lower end position by operating the locking members 43a to 43d. can do.

  As mentioned above, although the Example of this invention was described in detail, these are only illustrations and do not limit a claim. The technology described in the claims includes various modifications and changes of the specific examples illustrated above. For example, the following modifications may be included.

(Modification 1) In each of the above-described embodiments, the belt 9 slides according to the postures of the mobile terminals 10a to 10d. In the modification, for example, the belt 9 may be slid by a user operating a button. That is, the “belt” does not have to slide in accordance with the change in the posture of the mobile terminal.

(Modification 2) In each of the above embodiments, a holding portion may be further arranged so that the belt 9 is held at a position different from the upper end position and the lower end position.

2: Main body 4: Display screen 5: Operation unit 6: Key button 7: Reading unit 9: Belts 10a to 10d: Mobile terminals 12, 32, 42: Groove 14: Slide member 14a: Protruding portions 21a to 21d, 33, 41a ˜41d: holding portions 22a-22d: struts 24a-24d: torsion springs 25a-25d: end 31: sensors 32a-32d, 42a-42d: projecting grooves 43a-43d: locking members L1, L2: center line

Claims (6)

A mobile device,
A user-gripable body,
An operation unit provided on a front surface of the main body;
A belt provided on a rear surface of the main body and capable of inserting the user's finger;
With
The belt is slidable in the vertical direction between the upper end position and the lower end position on the rear surface of the main body.
Mobile device. The belt is
When the posture of the mobile terminal changes from an upright state in which the upper end position is arranged at a position higher than the lower end position, to an inverted state in which the lower end position is arranged at a position higher than the upper end position, On the rear surface of the main body, slide in the direction toward the lower end position,
The portable terminal according to claim 1, wherein when the posture of the portable terminal changes from the inverted state to the upright state, the portable terminal slides in a direction toward the upper end position on the rear surface of the main body. The mobile terminal further includes:
3. The mobile terminal according to claim 1, further comprising: a holding unit configured to hold the belt at a predetermined position between the upper end position and the lower end position on the rear surface of the main body. The holding part is
Including a torsion coil spring,
In a state where the torsion coil spring is not elastically deformed, the belt is held at the predetermined position,
The mobile terminal according to claim 3, wherein the belt is not held at the predetermined position in a state where the torsion coil spring is elastically deformed. The mobile terminal further includes:
A sensor for detecting an inclination of the axis connecting the upper end position and the lower end position with respect to a horizontal plane;
The holding part is
When the sensor detects an inclination smaller than a predetermined threshold, the belt is held at the predetermined position;
The portable terminal according to claim 3, wherein the belt is not held at the predetermined position when an inclination greater than the predetermined threshold is detected by the sensor. The holding part is
When the belt is disposed at the upper end position, the belt is held at the upper end position;
The portable terminal according to any one of claims 3 to 5, wherein the belt is held at the lower end position when the belt is disposed at the lower end position.

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