JP2006050204A - Slide unit, and portable product - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a portable product to be easily opened/closed in a slide cover, and also to provide a slide unit which is suitablly used in the portable product so as to make the portable product itself small/thin. <P>SOLUTION: The slide unit 20 comprises: a fixing board 21; a mobile board 22 slidably attached to the fixing board 21; and a linear or thin plate-like elastic member 23 attached to a part between the fixing board 21 and the mobile board 22. The elastic member 23 in a wave shape is attached between the fixing board 21 and the mobile board 23. The elastic member 23 is elastically deformed when the mobile board 22 is moved so as to allow an attachment part 23c to the mobile board 22 in the elastic member 23 to approach the attachment part 23b to the fixing board 21 in the elastic member 23, is elastically recovered when an attachment part 23c to the mobile board 22 in the elastic member 23 passes through the reverse point of the elastic member 23, and energizes the mobile board 22 in the movement direction. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a portable product such as a mobile phone or a digital camera including a PHS (Personal Handyphone System) terminal, and more particularly to a portable product provided with a slide cover and a slide unit suitably used for the portable product.

2. Description of the Related Art Conventionally, mobile phones have a structure in which a key operation unit is covered with a slide cover that opens and closes (see, for example, Patent Document 1 and Patent Document 2).
JP 2001-119456 A JP 2002-55737 A

  However, in any of the above mobile phones, the slide cover is simply attached to the housing (equipment main body) so that it can be opened and closed. Therefore, it is difficult to perform the opening and closing operation with one hand. Must be done with both hands. However, in the case of a mobile phone, there are many cases where both hands cannot be used when receiving a call and it is desired to operate with only one hand. Therefore, it is desired to provide a structure that can easily open and close the slide cover with one hand.

  In general, portable products are required to be small and thin because they must be carried around. Therefore, as described above, provision of a slide cover moving mechanism, such as a slide unit, that enables the opening and closing operation of the slide cover to be easily performed with one hand, as well as making the portable product itself smaller and thinner. Is desired.

  The present invention has been made in view of the above circumstances, and an object thereof is to be suitably used as a portable product provided with a slide cover, in particular, a portable product that can be easily opened and closed, and the portable product. Thus, it is an object of the present invention to provide a slide unit that enables the portable product itself to be reduced in size and thickness.

  The slide unit of the present invention includes a fixed plate, a movable plate slidably attached to the fixed plate, and a linear or thin plate-like elastic member attached between the fixed plate and the movable plate. The elastic member is formed into a corrugated shape, and the elastic member moves to the movable plate when the movable plate moves so that the mounting portion of the elastic member to the movable plate is connected to the fixed plate of the elastic member. The elastic member is elastically deformed by approaching the attachment portion of the elastic member, and the elastic member is elastically restored when the attachment portion of the elastic member to the movable plate passes through the inversion point of the elastic member, and the movable plate is urged in the moving direction. As described above, the means for solving the above-described problems is that the fixed plate and the movable plate are attached.

  According to this slide unit, since it is basically composed of a fixed plate, a movable plate, and an elastic member, the whole structure becomes simple and the unit itself can be reduced in size and thickness. It is also possible to reduce the size and thickness of the product used. In addition, since the movable plate is urged in the moving direction by the elastic return force of the elastic member by passing the reversal point of the elastic member, the movable plate can be easily moved without requiring a complicated mechanism. Can be moved.

Moreover, in the slide unit, it is preferable that the elastic member has a loop portion wound at least once around a crest or a trough in the corrugation.
In this way, the elastic member has a loop portion at the peak or valley of the corrugation that becomes wider or narrower due to elastic deformation and elastic return of the elastic member. Increases durability.

In the slide unit, it is preferable that the elastic member is composed of two spring members, and these spring members are respectively disposed on both sides of the center line along the moving direction of the movable plate.
In this way, it is possible to arrange other components between the spring members, and therefore it is possible to add functions without impairing the size and thickness of the slide unit.

Further, in the slide unit, the fixed plate and the movable plate are movable by guiding a plate-shaped engagement plate formed on the other inside a groove-shaped guide groove formed on one of the fixed plate and the movable plate. It is preferable that the plate is slidable with respect to the fixed plate, and the plate-like engagement plate is formed with a bulge portion that bulges from the plate surface and contacts the inner wall surface of the guide groove. .
In this way, when the engagement plate relatively moves in the guide groove, the bulging portion is in contact with the inner wall surface of the guide groove, so that there is no rattling between the engagement plate and the guide groove. Therefore, the movable plate can be smoothly slid with respect to the fixed plate.

  The portable product of the present invention includes a device main body and a slide cover attached to the device main body, and the slide cover covers at least a part of the operation unit or the function unit of the device main body and exposes the state. In a portable product that is movably mounted between states, the slide unit is between the outer surface of the device main body and the inner surface of the slide cover, and the fixing plate is the outer surface of the device main body and the slide. The means for solving the problems is that the movable plate is attached to one of the inner surface of the cover and the movable plate is attached to the other of the outer surface of the device main body and the inner surface of the slide cover.

  According to this portable product, since the slide unit is provided between the outer surface of the device main body and the inner surface of the slide cover, as described above, the size and thickness of the slide unit have reduced the size of the portable product itself. Thinning is achieved. In addition, as described above, the slide unit can easily move the movable plate without requiring a complicated mechanism. Therefore, the portable product equipped with the slide unit particularly opens and closes the slide cover. Easy to operate.

In the slide unit of the present invention, since the unit itself can be reduced in size and thickness, a product using the slide unit can be reduced in size and thickness.
In addition, since the movable plate is urged in the moving direction by the elastic return force of the elastic member by passing the reversal point of the elastic member, the movable plate can be easily moved without requiring a complicated mechanism. Can be moved. Therefore, in a product using the slide unit, for example, by attaching a moving member such as a slide cover to the movable plate, the moving member can be easily moved with one hand, and thus the operability is improved. Can do.

In the portable product of the present invention, as described above, the portable product itself can be reduced in size and thickness by reducing the size and thickness of the slide unit.
In addition, as described above, the slide unit can easily move the movable plate without requiring a complicated mechanism. Therefore, the portable product equipped with the slide unit particularly opens and closes the slide cover. The operation can be easily performed with one hand, and thus the operability is improved.

The present invention will be described in detail below.
FIG. 1 and FIG. 2 are diagrams showing an embodiment of a mobile phone as a portable product provided with the slide unit of the present invention. In these drawings, reference numeral 1 is a mobile phone. The mobile phone 1 includes a device main body 2, a slide cover 3 attached to the device main body 2, and a slide unit 20 provided between the device main body 2 and the slide cover 3.

  The device main body 2 has a substantially rectangular parallelepiped bowl-like shape, has an antenna 4 on the upper end surface, and further, on the front surface (outer surface), from the upper side to the lower side, the receiver 5, the display unit 6, and the key operation unit 7. The transmitter 8 is provided in this order. Further, a fixed plate 21 of the slide unit 20 is attached to the front surface (outer surface) of the device main body 2 below the transmitter 8.

  The slide cover 3 is made of resin formed and arranged so as to cover at least a part of the key operation unit 7 and the like of the device main body 2, and is formed on the cover plate 3a covering the key operation unit 7 and the like and on both sides thereof. The side plates 3b and 3b are provided. In the slide cover 3, a movable plate 22 of the slide unit 20 is attached to the inner surface of the cover plate 3a. Under such a configuration, the slide cover 3 is attached to the device main body 2 via the slide unit 20.

  The slide unit 20 is an embodiment of the slide unit of the present invention. As shown in FIG. 3A, a fixed plate 21 and a movable plate 22 slidably attached to the fixed plate 21 are provided. The elastic member 23 includes a pair of spring members 23 a and 23 a attached between the fixed plate 21 and the movable plate 22. The fixing plate 21 is attached to the front surface (outer surface) of the device main body 2 as described above, and the fixing plate main body 24 formed in a substantially U shape and a pair of thin plate portions 24 a of the fixing plate main body 24. It consists of a pair of spring fixing | fixed part 25 formed inside.

A plurality of screw fixing holes 24b are formed in the fixed plate main body 24, and screws (not shown) are inserted into the holes 24b. The fixed plate 21 is fixed to the device main body 2 as described above by screwing the inserted screw into a screw hole (not shown) formed on the front surface (outer surface) of the device main body 2. It has become.
As shown in FIG. 3B, the spring fixing portions 25, 25 are partially bent so that the tip ends are lifted to the movable plate 22 side. As shown in FIG. 3A, mounting pins 25a for attaching the spring members 23a, 23a are attached to the lifted tip, and the spring members 23a are attached to the attachment pins 25a. One end portion (attachment portion) 23b is attached.

  Further, the fixed plate body 24 is formed with a rail 24c by bending an end portion upward at an outer portion of the thin plate portion 24a and further bending outward. Further, a stopper pin 26 is attached to one end side of these rails 24c, that is, the side opposite to the tip of the thin plate portion 24a. Further, a stopper 24d is formed at the distal end of the thin plate portion 24a by raising the thin plate portion 24a toward the movable plate 22 side.

  The movable plate 22 is substantially U-shaped with a plurality of screw fastening holes 22a. A screw (not shown) is inserted into the hole 22a, and the inserted screw is formed on the inner surface of the slide cover 3. By screwing into a screw hole (not shown), it is attached to the inner surface of the slide cover 3 as described above. The movable plate 22 has a plurality of engaging portions 27 formed on the outer side thereof by hemming bending so as to engage with the rail 24c while being sandwiched. With this configuration, the movable plate 22 can be smoothly moved in the length direction of the rail 24c by the engagement portion 27 being guided by the rail 24c of the fixed plate 21. In particular, since the engaging portion 27 is formed by a hemming bending process, the engaging portion 27 is guided by the rail 24c without causing backlash.

  However, since the movable plate 22 is provided with the stopper pin 26 on one side of the fixed plate 21 and the stopper 24d on the other side, as described above, the stopper plate 26 and the stopper 24d are connected to each other. It is restricted so that it can only move between the two. Therefore, the movable plate 22 is prevented from being detached from the fixed plate 21, and the slide cover 3 to which the movable plate 22 is attached is set without being detached from the device body 2 to which the fixed plate 21 is attached. It is designed to move only the stroke that has been changed.

  The movable plate 22 has mounting pins 28 attached to both sides thereof, that is, the side on which the engaging portion 27 is formed. The other end portion (mounting portion) 23c of the spring material 23a is attached to the mounting pin 28. It is attached. Here, the mounting pins 28, 28 on the movable plate 22 side are located outside the mounting pins 25 a, 25 a on the fixed plate 21 side, so that the movable plate 22 is located with respect to the fixed plate 21. The mounting pins 25a and 25a do not interfere with the mounting pins 28 and 28 when moved.

  The spring members 23a and 23a constituting the elastic member 23 are made of a metal such as stainless steel or high-tensile steel, or a synthetic resin. In the present embodiment, a metal wire is formed into a corrugated shape. . Although there is no particular limitation on the shape of the waveform, in this embodiment, a W-shaped one is used in plan view as shown in FIG. That is, the spring material 23a of the present embodiment forms two peaks and one valley on one side formed into a waveform, and conversely forms one peak and two valleys on the other side. It is a thing. And especially in this embodiment, the loop part 29 formed by winding a wire round is formed in the peak part (or trough part) located in the center. As will be described later, when the spring member 23a is elastically deformed / returned elastically, the loop portion 29 is, in particular, the degree to which the peak (or valley) at the center becomes wider or narrower. Therefore, by winding the wire around here, the spring material 23a can be easily expanded and contracted and its durability is enhanced.

  Further, as described above, one end portion 23b of the spring member 23a is attached to the attachment pin 25a of the fixed plate 21, and the other end portion 23c is attached to the attachment pin 28 of the movable plate 22, but these attachment pins 25a (28 The end portion (one end portion 23b or the other end portion 23c) to be attached is formed by winding the wire rod once (or a plurality of turns) in the same manner as the loop portion 29, and thereby the attachment pin 25a (28). It is attached so that rotation is possible. Therefore, since both ends of the spring material 23a are rotatable with respect to the mounting pins 25a (28), the spring material 23a itself is also rotatable with respect to the mounting pins 25a and 28. .

  That is, when the movable plate 22 is moved from the state shown in FIG. 3A to the state shown in FIG. 4, the spring member 23 a is particularly located on the other end 23 c side attached to the attachment pin 28 of the movable plate 22. The outer end of the fixing plate 21 is attached to the mounting pin 25a, and the outer side of the fixing plate 21 rotates around the one end 23b. If viewed relatively, the one end portion 23b side attached to the attachment pin 25a of the fixed plate 21 rotates inside the other end portion 23c attached to the attachment pin 28 of the movable plate 22. It is also. Further, when moving from the state shown in FIG. 4 to the state shown in FIG. 3A, the other end 23c side on the movable plate 22 side rotates in the opposite direction.

  At this time, the distance between the one end portion 23b and the other end portion 23c of the spring material 23a (the distance between the mounting pin 25a and the mounting pin 28) is displaced with the movement of the movable plate 22. 23a expands and contracts according to the amount of displacement. That is, when the movable plate 22 is moved from the state shown in FIG. 3A to the state shown in FIG. 4, the spring member 23a is displaced as shown in FIG. FIG. 5 schematically shows the relative operation (displacement) of the spring member 23a. The other end 23b attached to the attachment pin 25a of the fixed plate 21 is the moving side, and the movable plate 22 is moved. The one end portion 23c attached to the attachment pin 28 is the fixed side.

  Here, the operation of the spring member 23a will be described. First, in the state shown in FIG. 3A, the spring member 23a is W-shaped as shown by a solid line in FIG. In this state, the spring member 23a is biased in the direction of expanding the waveform by the elastic restoring force, that is, in the direction of separating the mounting pin 25a from the mounting pin 28. In this state, since the movable plate 22 is in contact with the stopper 24d as shown in FIG. 3A, the movement toward the stopper 24d is not made any further.

  Further, in FIG. 5, if the direction in which the mounting pin 25a moves relative to the mounting pin 28 (the moving direction of the movable plate 22) is the Y direction and the direction orthogonal thereto is the X direction, FIG. In the state shown in FIG. 5, the load (biasing force) applied to the mounting pin 25a in the Y direction by the spring member 23a is G1 as shown in FIG. Therefore, in order to move the mounting pin 25a relative to the mounting pin 28, it is necessary to apply a force exceeding G1 to the mounting pin 25a. In other words, by applying a force exceeding G1 to the movable plate 22, the movable plate 22 moves only against the urging force of the spring member 23a. Actually, since two spring members 23a are provided between the fixed plate 21 and the movable plate 22, in order to move the movable plate 22, a force twice as large as G1 is required. Become. However, regarding FIG. 5, in order to simplify the description, the spring material 23a is considered as one as described above.

  When a force exceeding G1 is relatively applied to the mounting pin 25a, the one end 23b of the spring member 23a approaches the other end 23c. Then, when the distance between them becomes short, the spring material 23a is compressed and elastically deformed. Then, as shown by a broken line in FIG. 5, when one end 23 b of the spring material 23 a comes closest to the other end 23 c, the spring material 23 a moves in the direction in which the movable plate 22 is moved relative to the fixed plate 21, that is, in the Y direction. The biasing force (G1) becomes zero. This position becomes the reversal point of the spring material 23a. As the one end portion 23b of the spring member 23a is brought closer to the other end portion 23c in this way, G1 gradually decreases, so that the movable plate 22 can be moved easily, that is, smoothly. I understand that

  When a force is further applied to the mounting pin 25a, the one end portion 23b (relatively the other end portion 23c) of the spring member 23a passes through the reversal point, so that the spring member 23a is elastically restored. Wake up. Thereby, the movable plate 22 is biased in the moving direction by the spring member 23a. Therefore, even if no force is applied to the movable plate 22 in the moving direction, the movable plate 22 automatically moves due to the biasing force of the spring member 23a. When such movement proceeds, the movable plate 22 comes into contact with the stopper pin 26 as shown in FIG. 4, and the movement stops. At this time, the spring material 23a becomes as indicated by a two-dot chain line in FIG. 5, and the load (biasing force) indicated by G2 is applied to the mounting pin 25a by the spring material 23a. Note that G2 has a sign opposite to that of G1, and therefore the spring member 23a is urged in the direction opposite to that shown by the solid line in FIG.

  Here, as shown in FIG. 5, when the distance W between the mounting pin 25a and the mounting pin 28 in the X direction is short and the movement distance L of the mounting pin 25a in the Y direction is long, the loop portion 29 is formed. The angle θ1 at the valley is increased. Therefore, if the spring material 23a is designed so that the difference (θ1−θ2) from the angle θ2 at the inversion point indicated by the broken line in FIG. 5 is reduced, the durability is improved and the life is extended. Can do. In addition, about the length of each edge | side l1, l2, l3, l4 which comprises the spring material 23a, it determines according to the said movement distance L (stroke) and load G1, G2 to require. The inversion point can be adjusted by appropriately changing the lengths of the sides l1, l2, l3, and l4.

For comparison, FIG. 6 shows a case where a general spring material is used.
Even in the spring material 30 shown in FIG. 6, the durability increases as the difference (θ1−θ2) between the angle θ1 in the state indicated by the solid line and the angle θ2 at the inversion point indicated by the broken line decreases, Its life is extended.
Here, since the spring material 30 shown in FIG. 6 has a larger θ1 than the spring material 23a shown in FIG. 5, the force applied to the loop portion 29 before reaching the reversal point is applied to the loop portion 29. The force is applied in the direction of shifting rather than the force to rotate, and therefore the durability of this portion is deteriorated. Moreover, since (θ1−θ2) is larger than that of the spring member 23a shown in FIG. 5, the durability is further deteriorated. Therefore, it can be seen that the spring material 23a of the present embodiment shown in FIG. 5 is particularly excellent in durability as compared with a general spring material.

  In the cellular phone 1 having the slide unit 20 having such a configuration, the slide cover 3 is opened as shown in FIG. 1 in the use state, and therefore the transmitter 8 and the key operation unit 7 are the slide cover. 3 is exposed without being covered by 3. In this state, the slide unit 20 is in a state where the movable plate 22 biased by the spring member 23a is in contact with the stopper 24d as shown in FIG.

  To end use and close the slide cover 3 from the opened state, the slide cover 3 is slid toward the antenna 4 with the thumb of the hand while holding the mobile phone 1 with one hand. Then, the movable plate 22 moves with the movement of the slide cover 3. At this time, in the initial stage of movement, the spring member 23a is elastically deformed as described above. Then, in particular, when the attachment portion of the spring material 23a to the movable plate 22, that is, the other end portion 23c of the spring material 23a passes through the reversal point, the spring material 23a turns from the state where it has been elastically deformed until then. The elastic plate is caused to return, and thereafter, the movable plate 22 is easily moved by the urging force of the elastic return force, and is moved until it comes into contact with the stopper pin 26 as shown in FIG. As a result, the slide cover 3 also slides smoothly, and closes in a state where the transmission section 8 and the key operation section 7 are covered as shown in FIG.

  Further, when the cover is closed in this way and is used again, the slide cover 3 is slid from the closed state to the side opposite to the antenna 4 with a thumb or the like. Then, in the slide unit 20, the movable plate 22 moves in the direction opposite to the previous time, and again moves until the movable plate 22 contacts the stopper 24d as shown in FIG. As a result, the slide cover 3 is opened as shown in FIG. 1, and the transmitter 8 and the key operation unit 7 are exposed.

Since the slide unit 20 in such a cellular phone 1 is configured by the fixed plate 21, the movable plate 22, and the elastic member 23 including the pair of spring members 23a, the entire unit has a simple configuration. The device itself is reduced in size and thickness. Therefore, it is possible to reduce the size and thickness of the mobile phone 1 using the same.
Further, since the movable plate 22 is urged in the moving direction by the elastic restoring force of the elastic member 23 by passing the reversal point of the elastic member 23, it is easy without requiring a complicated mechanism. The movable plate 22 can be moved. Therefore, in the mobile phone 1 using the slide unit 20, by attaching the slide cover 3 to the movable plate 22, the slide cover 3 can be easily moved with one hand, thus improving its operability. can do.

Moreover, since the loop part 29 was formed in the peak part (valley part) in the waveform about the spring material 23a, the expansion and contraction when the spring material 23a is elastically deformed and elastically returned can be facilitated, and the durability thereof is further improved. It can also improve sex.
Further, since the elastic member 23 is formed by the two spring members 23a, other components such as a flexible substrate can be arranged between the spring members 23a and 23a, and thus the slide unit 20 can be made smaller and thinner. Other functions can be added without impairing the function.

  In the mobile phone 1, since the slide unit 20 is reduced in size and thickness as described above, the mobile phone 1 itself is also reduced in size and thickness. Further, as described above, the slide unit 20 can easily move the movable plate 22 without requiring a complicated mechanism. Therefore, the mobile phone 1 equipped with the slide unit 20 is particularly slid. The opening and closing operation of the cover 3 can be easily performed with one hand, and thus the operability is improved.

  In the above embodiment, the fixed plate 21 of the slide unit 20 is attached to the front surface (outer surface) of the device main body 2 and the movable plate 22 of the slide unit 20 is attached to the slide cover 3, but the present invention is limited to this. Instead, the movable plate 22 of the slide unit 20 may be attached to the device main body 2 side, and the fixed plate 21 of the slide unit 20 may be attached to the slide cover 3 side.

FIGS. 7A, 7B, and 8 are views showing other embodiments of the slide unit of the present invention. In these drawings, reference numeral 40 denotes a slide unit. The main difference of the slide unit 40 from the slide unit 20 is the configuration of a mechanism for moving (sliding) the movable plate relative to the fixed plate, and the other configurations are basically the same as those of the slide unit 20. .
That is, the slide unit 40 includes a fixed plate 41, a movable plate 42 slidably attached to the fixed plate 21, and a space between the fixed plate 41 and the movable plate 42 as shown in FIG. And an elastic member 43 made of a pair of spring members 43a and 43a. The fixing plate 41 is attached to the front surface (outer surface) of the device main body 2 or the inner surface of the slide cover 3 in the mobile phone 1 shown in FIGS. 1 and 2, for example, and is formed in a substantially U shape. The fixing plate main body 44 and a pair of spring fixing portions 45 formed inside the pair of thin plate portions 44a of the fixing plate main body 44 are provided.

The fixing plate main body 44 is formed with a plurality of screw-fastening holes 44b, and screws (not shown) are inserted into the holes 44b. Then, when the inserted screw is screwed into, for example, a screw hole (not shown) formed in the device main body 2 or the slide cover 3, the fixing plate 41 is fixed to the device main body 2 or the slide cover 3 as described above. It is supposed to be fixed to.
As shown in FIG. 7B, the spring fixing portions 45, 45 are partially bent so that the tip ends thereof are pulled down to the movable plate 22 side. Then, as shown in FIG. 7A, mounting pins 45a for mounting the spring members 43a, 43a are attached to the pulled-down tip, and the spring members 43a are attached to the mounting pins 45a. One end portion (attachment portion) 43b is attached.

  The fixed plate main body 44 has a plate-like shape that engages with a guide groove, which will be described later, by bending the end of the narrow plate portion 44a downward and further bending outward. An engagement plate 44c is formed. As shown in FIG. 8, the engaging plate 44c is formed in a state in which a plurality of bulged portions 44d that bulge out from one surface and come into contact with the inner wall surface of the guide groove are arranged as shown in FIG. Yes. These bulging portions 44d are formed by drawing, and have a spring property that biases them in the bulging direction.

  Further, the thin plate portion 44a is formed with a notch 46 at the tip end side, and a stopper 46a bent downward is formed in the notch 46. Further, as shown in FIG. 7 (a), in the vicinity of the position where the spring fixing portion 45 is formed in the thin plate portion 44a, a stopper 47 formed by bending a part thereof downward on the inner side thereof. Is formed.

  The movable plate 42 is substantially U-shaped with a plurality of screw fastening holes 42a. A screw (not shown) is inserted into the hole 42a, and the inserted screw is shown in FIGS. 1 and 2, for example. The mobile phone 1 is attached to the inner surface of the slide cover 3 by being screwed into an inner surface of the slide cover 3 of the mobile phone 1 or a screw hole (not shown) formed on the front surface (outer surface) of the device main body 2. 2 is attached to the front (outer surface). As shown in FIG. 7B, a groove-shaped guide groove 48 is formed on the movable plate 42 by bending the plate portion into a U-shape. The guide groove 48 relatively guides the engagement plate 44c described above along its length direction.

  With such a configuration, the movable plate 42 can move in the length direction of the engagement plate 44c by the guide groove 48 being guided along the engagement plate 44c. Here, the bulging portion 44 formed on the engagement plate 44 c is bulged so as to come into contact with one side wall surface (inner wall surface) of the guide groove 48. Therefore, when the engaging plate 44c moves relatively inside the guide groove 48, the bulging portion 44d abuts against and presses the side wall surface of the guide groove 48, so that the engaging plate 44c and the guide groove 48 Therefore, the movable plate 42 can be smoothly slid with respect to the fixed plate 41.

  Further, a stopper pin 49 is fixed to the movable plate 42 by a caulking process on the side where the guide groove 48 is formed, and a stopper piece 50 is formed by bending on the inner side of the distal end portion of the thin plate portion 44a. Is formed. Then, as shown in FIG. 7A, the movable plate 42 is restricted from moving on one side with respect to the fixed plate 41 by the stopper pin 49 coming into contact with the stopper 46 a of the fixed plate 41. Further, when the stopper piece 50 of the movable plate 42 comes into contact with the stopper 47 of the fixed plate 41, the movement on the other side is restricted. As a result, the movable plate 42 is restricted in the range of movement relative to the fixed plate 41 so as not to be detached from the fixed plate 21.

  The movable plate 42 has mounting pins 51 attached to both sides thereof, that is, the side where the guide groove 48 is formed. The other end portion (attachment portion) 43c of the spring material 43a is attached to the mounting pin 51. It has been. Here, the mounting pins 28, 28 on the movable plate 22 side are located outside the mounting pins 45 a, 45 a on the fixed plate 41 side, so that the movable plate 42 is relative to the fixed plate 41. The mounting pins 51, 51 do not interfere with the mounting pins 45a, 45a.

The spring members 43a, 43a constituting the elastic member 43 are W-shaped in a plan view as shown in FIG. 7 (a), like the spring member 23a in the slide unit 20, and have a loop at the center thereof. The part 52 is formed.
Therefore, even in the slide unit 40 of the present embodiment, the operation relating to the elastic member 43 (spring material 43a) and the actions and effects obtained therefrom are the same as those of the slide unit 20.

Further, in the slide unit 20 described above, the engagement portion 27 is formed by hemming bending, so that the rail 24c is held without rattling, as shown in FIG. 3B. On the outer side of the rail 24c, a portion crushed by hemming bending is formed, and this amount results in a slight increase in the width of the slide unit 20. On the other hand, the slide unit 40 according to the present embodiment does not cause backlash between the guide groove 48 by forming the bulging portion 44d on the engagement plate 44c without using hemming bending as described above. The engaging plate 44c can be smoothly moved relative to the guide groove 48.
Therefore, in the slide unit 40, the width can be particularly narrowed, and the size can be further reduced. Therefore, it is possible to reduce the size of portable products using the same.

  In the above embodiment, the elastic member 23 is formed by the two spring members 23a. However, the present invention is not limited to this, and the elastic member is formed by one or three or more spring members. Can do. Also, the shape of the spring member 23a is not limited to a W shape as long as it is a waveform, and various other shapes can be employed.

  Moreover, in the said embodiment, although the mobile telephone 1 of the structure which covers the key operation part 7 grade | etc., With the slide cover 3 was shown as a portable product of this invention, this invention is not limited to these, For example, in a mobile telephone The present invention can also be applied to a configuration in which the camera unit and the flash are covered with a slide cover, and a configuration in which the lens unit is covered with a slide cover in a digital camera.

It is a perspective view which shows schematic structure of one Embodiment of the mobile telephone of this invention. It is a perspective view which shows schematic structure of one Embodiment of the mobile telephone of this invention. (A) is a top view which shows schematic structure of one Embodiment of the slide unit of this invention, (b) is a front view of (a). It is a top view which shows schematic structure of the same slide unit as Fig.3 (a). It is a schematic diagram for demonstrating operation | movement of the elastic member (spring material) in a slide unit. It is a schematic diagram for demonstrating operation | movement of the comparative example about the elastic member (spring material) in a slide unit. (A) is a top view which shows schematic structure of other embodiment of the slide unit of this invention, (b) is a front view of (a). FIG. 8 is a side view of the slide unit shown in FIG. 7.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Mobile phone, 2 ... Device main body, 3 ... Slide cover, 7 ... Key operation part,
20, 40 ... slide unit, 21, 41 ... fixed plate, 22, 42 ... movable plate,
23, 43 ... elastic member, 23a, 43a ... spring material,
23b, 43b ... one end (attachment portion), 23c, 43c ... the other end (attachment portion),
25a, 45a ... mounting pin, 28, 51 ... mounting pin, 29 ... loop part,
44c ... engaging plate, 44d ... bulge, 48 ... guide groove

Claims (5)

A fixed plate, a movable plate slidably attached to the fixed plate, and a linear or thin elastic member attached between the fixed plate and the movable plate,
The elastic member is formed into a corrugated shape, and the elastic member moves when the movable plate moves so that the attachment portion of the elastic member to the movable plate is relative to the attachment portion of the elastic member to the fixed plate. The fixed portion is elastically deformed by approaching, and the elastic member is elastically restored by passing through the reversing point of the elastic member and the movable plate is biased in the moving direction. A slide unit mounted between a plate and a movable plate.   The slide unit according to claim 1, wherein the elastic member has a loop portion wound at least once around a crest or a trough in the corrugation.   The slide unit according to claim 1 or 2, wherein the elastic member includes two spring members, and the spring members are respectively disposed on both sides of a center line along a moving direction of the movable plate. .   The movable plate slides with respect to the fixed plate by guiding the plate-shaped engagement plate formed on the other inside the groove-shaped guide groove formed on one of the fixed plate and the movable plate. The bulging part which bulges from the plate surface and contacts the inner wall surface of the guide groove is formed on the plate-like engagement plate. The slide unit as described in any one of Claims. An apparatus main body and a slide cover attached to the apparatus main body are provided, and the slide cover is movable between a state in which at least a part of an operation unit or a function unit of the device main body is covered and a state in which the operation unit or function unit is exposed. In mobile products attached to
Between the outer surface of the said apparatus main body and the inner surface of the said slide cover, the slide unit as described in any one of Claims 1-4 WHEREIN: The fixing plate is the outer surface of the said apparatus main body, and the inner surface of the said slide cover. A portable product attached to one side, wherein the movable plate is attached to the other of the outer surface of the device main body and the inner surface of the slide cover.

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