KR100624018B1 - sliding mechanism apparatus for slide type portable phone - Google Patents

Abstract

A sliding device is disclosed that allows two components of a sliding cell phone to be opened and closed in a sliding manner. The guide rail member and the slide member are engaged to slide in a linear direction. The first torsion spring has one end coupled to the left edge of the slide member and the other end coupled to the right half region of the guide rail member. The second torsion spring has one end coupled to the right edge of the slide member and the other end coupled to the left half region of the guide rail member. In the initial state where the first and second torsion springs are fully extended, when an external force is applied to each of the slide member and the guide rail member in different directions, the first and second torsion springs are folded at an acute angle during the pivoting motion and then again by the elastic force. It spreads enough. Thereby, the slide member is moved to the lowest point or the highest point. The distance between the ends of both arms of the first torsion spring is at least half of the width of the slide member, and the second torsion spring is the same. Therefore, the first torsion springs and the second torsion springs are pivoted by utilizing the width of the guide rail member as wide as possible, thereby increasing the maximum moving distance of the slide member.

Description

Sliding mechanism apparatus for slide type mobile phone {sliding mechanism apparatus for slide type portable phone}

1 is an exploded perspective view of a sliding device according to a first embodiment of the present invention,

2A to 2D are reference diagrams for explaining a process of changing the position state of the assembled sliding device of FIG. 1 from the highest state to the lowest state,

3A and 3B are assembly state diagrams of a sliding device according to a second embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100, 200: sliding device

110, 210: slide member

120, 220: first torsion spring

130, 230: second torsion spring

140, 240: guide rail member

The present invention relates to a sliding device for a slide-type mobile phone, and more particularly to a sliding device using the elastic force of the torsion spring.

There are many types of mobile phones. In the past, flip type, folder type and bar type were widely used, and recently, slide type mobile phones have attracted the attention of consumers as another new model.

In general, the slide-type portable terminal consists of a main body and a cover slidably installed on the main body. Conventional technologies related to such slide type portable terminals include Korean Patent Publication No. 1999-0073913, "Sliding Type Mobile Phone", Korean Patent Publication No. 2002-0074870, "Slide Type Mobile Phone Using Slide Module," Korea Utility Model Publication No. 2001- 0000622, "Dual Slide Cell Phone", and US Patent No. 6,073,027, "Portable Radiotelephone with Sliding Cover and Automatic Antenna Extension." Each of these conventional slide modules is configured to realize their own unique sliding method.

Patent Publication No. 1999-0073913 proposes a slide method using a guide groove and a guide rail. Utility Model Publication No. 2001-0000622 proposes a slide method using a rack and pinion. And Patent Publication No. 2002-0074870 proposes a slide structure of a special structure using a sliding member supported on the support plate, a guide plate formed with a guide hole for guiding the sliding member, and a leaf spring. US Patent No. 6,073,027 proposes a slide method of opening and closing a cover by slidably connecting a cover having a latch, a latch catch and an actuator to a housing by a tension spring.

However, the slide method of the related arts does not have a separate moving force providing means, so that the user can move the slide cover only as long as the user pushes up or pushes down.

The present invention is to slide the slide member along the guide rail member to move only a certain distance by the force applied by the user to be further moved by the elastic force of the torsion spring, in particular the ratio of the movement distance is very large compared to the width of the slide member It is an object of the present invention to provide a sliding device that is very suitable for manufacturing a short and thin mobile phone.

According to the present invention for achieving the above object, a guide rail member; A slide member coupled to the guide rail member to enable a sliding motion in a linear direction; A first coil wound in a circular shape and two arms extending a predetermined length from both ends of the first coil, the first coil being disposed in a space between the slide member and the guide rail member, and one end of the arm A first torsion spring coupled to a first point near the left edge and having an end of the other arm coupled to a second point in the right half region of the slide member; And a second coil wound in a circular shape and two arms extending a predetermined length from both ends of the second coil, and disposed in a space between the slide member and the guide rail member, and one end of the arm is the guide rail member. A second torsion spring coupled to a third point near the right edge of the second arm and having an end of the other arm coupled to a fourth point in the left half region of the slide member; The guide rail member has first and second guide bars extending along opposite parallel sides of the first rectangular plate, and the first point and the third point positioned at both edges of the first rectangular plate. A coupling hole and a second coupling hole are respectively formed; The slide member is formed with a sliding engaging hand for slidably holding the first and second guide bars on opposite parallel edges of the second rectangular plate, and at the second and fourth points of the second rectangular plate. A sliding device for a sliding type mobile phone having a structure in which third and fourth coupling holes into which the bent ends of the first and second torsion springs can be inserted is formed, respectively.

In the sliding device, the distance between the first point and the second point is preferably equal to the distance between the third point and the fourth point.

According to a preferred embodiment of the sliding device, the guide rail member extends the first and second guide rails having a predetermined width and height along opposite parallel side edges of the first rectangular plate, and the first And first and second guide rail grooves extending in a length direction on an outer side surface of the second guide rail, the first coupling being to the first point of the first guide rail and the third point of the second guide rail. A ball and a second coupling hole are formed respectively; The slide member has protruding first and second rails formed along opposite parallel edges of the second rectangular plate, and the first and second rails slide in the first and second guide rail grooves, respectively. It is possible to engage, and the second and fourth points of the second rectangular plate has a structure in which the third and fourth coupling holes are formed, respectively, into which the bent ends of the first and second torsion springs can be inserted. It is done.

According to another preferred embodiment of the sliding device, the guide rail member extends the first and second guide bars along opposite parallel sides of the first rectangular plate and is located at both edges of the first rectangular plate. A first coupling hole and a second coupling hole are formed at the first point and the third point, respectively; The slide member is provided with a coupling hand slidably holding the first and second guide bars on opposite parallel edges of the second rectangular plate, and at the second and fourth points of the second rectangular plate. It characterized in that it has a structure in which the third and fourth coupling holes that can be inserted bent ends of the first and second torsion springs are formed, respectively.

In the sliding device, it is preferable that a plurality of screw grooves are formed on the outer surfaces of the slide member and the guide rail member, respectively, for screwing the components of the mobile phone.

According to the sliding device of the present invention as described above, in the state where no external force is applied, the slide member has a position relative to the guide rail member in any one of the highest point or the lowest point, and the first and second positions. The torsion spring takes the initial state of being fully extended at a predetermined obtuse angle. In this state, when an external force is applied to each of the slide member and the guide rail member in opposite directions, the two arms coupled to the slide members of the first and second torsion springs rotate while the first and second torsion springs respectively rotate. Is folded at an acute angle. If the external force continues to be applied to a size that can overcome the torsional elasticity of the first and second torsion springs, the first and second torsion springs have a rotational angle of at least 90 degrees to 180 degrees based on the initial state. As it is elastic, it will be fully unfolded at an obtuse angle again. Thereby, the slide member is moved to the lowest point or the highest point. That is, when an external force is applied to overcome the elastic force of the first and second torsion springs, the slide member moves from the highest point to the lowest point or vice versa according to the direction of the external force.

In particular, the position of each point where the first torsion spring and the second torsion spring engages with the slide member is a position beyond the width center line of the guide rail member when viewed from the end of one arm coupled near the edge of the guide rail member. Therefore, the first torsion spring and the second torsion spring are pivoted by utilizing the width of the guide rail member as wide as possible. As a result, the moving distance of the slide member, that is, the distance between the uppermost point and the lowermost point, may move a relatively long distance relative to the width of the slide member. This has the advantage of being used as a sliding drive mechanism of the sliding type mobile phone to make the mobile phone short and thin.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

A sliding device 100 according to a first embodiment of the invention is shown in FIG. 1. The sliding device 100 includes a slide member 110, a first torsion spring 120, a second torsion spring 130, and a guide rail member 140.

The guide rail member 140 extends along the first and second guide rails 144a and 144b having a predetermined width and height along both parallel parallel edges of the rectangular plate 142. The outer side surfaces of the first guide rail 144a and the second guide rail 144b are formed with long first and second guide rail grooves 146a and 146b in the longitudinal direction, respectively. The V-shaped groove 149a is formed near the center point of the first guide rail 144a, and the coupling hole 148a is formed at the vertex of the groove 149a. Similarly, the V-shaped groove 149b and the coupling hole 148b are formed in the second guide rail 144b. However, the positions of the two coupling holes 148a and 148b are deformed a predetermined length. Forming the V-shaped grooves 149a and 149b in front of the coupling holes 148a and 148b is a consideration for preventing the rotation of the first and second torsion springs 120 and 130. The back of the guide rail member 140 is formed with a coupling hole for fixing with the lower body (not shown) of the mobile phone, for example, a plurality of coupling holes (not shown, see the coupling hole 245 formed in 240 of Figure 3b) is formed have.

The slide member 110 is engaged to slide in the linear direction to the guide rail member 140. In the structure of the slide member 110 for this purpose, protruding first and second rails 114a and 114b are formed along opposite parallel edges of the rectangular plate member 112, and the first rail ( 114a) and the second rail 114b are slidably engaged with the first guide rail groove 146a and the second guide rail groove 146b of the guide rail member 140, respectively. Two coupling holes 118a and 118b are formed at two points of the central portion of the rectangular plate 112 of the slide member 110. The two coupling holes 118a and 118b are hermetically spaced apart from the center line CL by dividing the width of the slide member in half. A plurality of coupling holes 116a to 116d are formed on the rear surface of the slide member 110 to fix the upper body (not shown) of the mobile phone.

The first torsion spring 120 includes a first coil 122 wound in a substantially circular shape, and two arms 124a and 124b extending a predetermined length from both ends of the first coil 122. The ends of the two arms 124a and 124b are bent at approximately right angles. The first torsion spring 120 is disposed in a space formed between the slide member 110 and the guide rail member 140 engaged with each other. The end of one arm 124a of the first torsion spring 120 is pivotally inserted into the coupling hole 148a of the guide rail member 140, and the end of the other arm 124b is a slide member ( It is rotatably inserted into the coupling hole 118b of the 110.

The second torsion spring 130 is also substantially the same shape as the first torsion spring 120, and consists of two arms 134a and 134b extending a predetermined length with the second coil 132 as the center, and the two arms 134a. 134b) is also bent. The end of one arm 134a of the second torsion spring 130 is pivotally inserted into the coupling hole 148b of the guide rail member 140, and the end of the other arm 134b is slide member 110. Is rotatably inserted into the coupling hole 118a.

It is preferable that the angle between the two arms 124a and 124b is as large as possible in the first torsion spring 120 without an external force applied thereto. The same applies to the second torsion spring 130. This is because the greater the distance between the two arms of the torsion spring, the longer the moving distance of the slide member 120 is.

After assembling the sliding device 110 of FIG. 1 as described above, and screwing the upper body and the lower body of the mobile phone to the guide rail member 140 and the slide member 110, respectively, the slide-type mobile phone (not shown) Can be completed.

2A to 2D show a state of movement of the sliding device 100 according to the first embodiment. In the state that no external force is applied, the two torsion springs 120 and 130 will try to maintain their unfolded state as much as possible. Therefore, when no external force is applied, the slide member 110 is pushed farthest in the upward direction of the guide rail member 140 as shown in FIG. 2A (hereinafter referred to as 'top state') and FIG. 2D. As shown, the slide member 110 is in only one of two states in a state in which it is pushed farthest in the downward direction of the guide rail member 140 (hereinafter referred to as 'lowest state').

For example, when the user exerts an external force on the upper body and the lower body of the mobile phone in the opposite direction to each other in the top state of Figure 2a, the force is transmitted to the slide member 110 and the guide rail member 140, the slide member 110 Direction and the guide rail member 140 moves upward. In the process, the first torsion spring 120 and the second torsion spring 130 are folded at an acute angle in an unfolded angle, and the coils 122 and 132 of the two torsion springs 120 and 130 are guide rail members 140. You will experience the state shown in Figure 2b, which is a state located in the lower half of the region. When the external force is continuously applied, the slide member 110 moves further downward. As a result, the coils 122 and 132 of the two torsion springs 120 and 130 are located in the upper half region of the guide rail member 140. This leads to the state shown in Fig. 2C. After the coils 122 and 132 of the two torsion springs 120 and 130 enter the upper half region of the guide rail member 140, even if no external force is applied thereto, the elastic restoring force of the two torsion springs 120 and 130 is applied. The slide member 110 is further moved to the position of the lowest state shown in Figure 2d by the force to be unfolded by the obtuse angle.

Through this process, the slide member 110 is moved from the highest state to the lowest state. The positional movement from the lowest state to the highest state is made by changing the sequence from FIG. 2D to FIG. 2A.

In the highest state or the lowest state, the two torsion springs 120 and 130 also act as latch functions since their elastic force pushes the slide member 110 to be biased upward or downward.

It is particularly noteworthy that consideration for increasing the maximum moving distance L of the slide member 110 with respect to the width W of the guide rail member 140 is considered in the design of the slide device 100. In order to lengthen the maximum moving distance L of the slide member 110, it is necessary to utilize the gap in the width direction of the guide rail member 140 as much as possible. As a method for enabling this, the present invention takes special consideration of the coupling position of the slide member 110 and the guide rail member 140 of the two torsion springs (120, 130). Specifically, when the end of one arm 124a of the first torsion spring 120 is located near the right edge of the guide rail member 140, the end of the other arm 124b is the slide member 110 It is located within the left half of the region (the area below the center line CL in FIG. 2A). Similarly, the arm 134b of the second torsion spring 130 coupled with the slide member 110 is positioned in the right half region of the slide member 110.

Unlike the above method (hereinafter referred to as 'first method'), the arm 124b of the first torsion spring 120 coupled with the slide member 110 is located in the right half region of the slide member 110 and the slide member ( When the arm 134b of the second torsion spring 130 coupled to 110 is positioned within the left half region of the slide member 110 (hereinafter referred to as 'second method'), the maximum moving distance L of the slide member 110 is achieved. ) Is significantly reduced compared to the above. This is because the space in the width (W) direction of the guide rail member 140 may not be utilized to the maximum.

There is a correlation between the maximum moving distance (L) of the slide member 110 and the width (W) of the guide rail member 140. If the width W is narrowed, a constraint is placed on increasing the maximum travel distance L. According to the first method, the width W of the guide rail member 140 may be smaller than that according to the second method to obtain the same maximum moving distance L. FIG. The first method is because the two torsion springs 120 and 130 make the most of the width (W) direction spacing when the compression-extension while rotating.

Mobile phones are required to be designed with short and thin structures. The first method is more advantageous in order to obtain the required maximum moving distance L while reducing the width W of the slide member 110 and the guide rail member 140. Therefore, in mobile phone design, it means that the first method can better accommodate short and thin design requirements than the second method.

Meanwhile, FIGS. 3A and 3B show planes and rear surfaces of the assembled state of the sliding device 200 according to the second embodiment of the present invention, respectively. The difference from the first embodiment is the structure and coupling method of the slide member 210 and the guide rail member 240.

The guide rail member 240 has first and second guide bars 244a and 244b extending along opposite parallel sides of the rectangular plate member 242, and approximately near the center near both edges of the plate member 242. Where the positions are slightly combed each other, coupling holes 248a and 248b are formed at the vertices of the V-shaped grooves, respectively. One arm 224a of the first torsion spring 220 and one arm 234a of the second torsion spring 230 are pivotally inserted into the two coupling holes 248a and 248b.

The slide member 210 is formed with sliding coupling hands 214a and 214b for slidingly interpolating the first and second guide bars 244a and 244b at opposite parallel edges of the rectangular plate 212, respectively. Has a structure. In addition, the coupling member 218a to which the other arm 224b of the first torsion spring 220 is coupled to the plate member of the slide member 210 is coupled to the other arm 234b of the second torsion spring 230. Coupling holes 218b are formed respectively.

Positions of the two coupling holes 248a and 248b of the guide rail member 240 and positions of the two coupling holes 218a and 218b of the slide member 210 are the same as described in the first embodiment. In addition, a plurality of coupling holes 245 and 214b used to engage the upper body and the lower body of the mobile phone are formed on the back of the guide rail member 240 and the back of the slide member 210, respectively. Same as Furthermore, since the content of the exercise of the sliding device 200 of the second embodiment is also the same as the first embodiment, a description thereof will be omitted.

In addition, in the above-described first embodiment, the widthwise gap between the first coupling hole 118a of the slide member 110 and the second coupling hole 148b of the guide rail member 140 is a slide member ( Preferably, the widthwise interval between the second coupling hole 118b of the 110 and the first coupling hole 148a of the guide rail member 140 is the same. If the two width direction gaps do not match, the slide member 110 is biased in the left and right directions to interfere with the smooth sliding operation. This point applies equally to the second embodiment.

In the above, the description has been made by taking a case where the sliding device of the present invention is applied to a mobile phone, but this does not mean that the sliding device of the present invention can be applied only to a mobile phone. The sliding device of the present invention can be widely applied to an application requiring the opening and closing of a device consisting of two bodies in a sliding manner.

According to the present invention as described above, the desired maximum sliding movement distance (L) can be obtained even if the width (W) of the mobile phone is relatively small, so that it is possible to satisfactorily satisfy the recent mobile phone design conditions for short and thin.

In addition, when the user wants to move the upper body of the mobile phone from the lowermost state to the uppermost state or vice versa, the user can move the upper body to the end of the position of the uppermost state (or the lowest state) without pushing up (pushing) the approximate maximum travel distance ( Even if only half of L) is pushed, the remaining distance is automatically moved to the opposite position by the elastic force of the torsion spring, so there is convenience in use.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art various modifications and changes to the present invention without departing from the spirit and scope of the invention described in the claims below You can. Accordingly, all changes that come within the meaning or range of equivalency of the claims are to be embraced within their scope.

Claims (5)

Guide rail members; A slide member coupled to the guide rail member to enable a sliding motion in a linear direction; A first coil wound in a circular shape and two arms extending a predetermined length from both ends of the first coil, the first coil being disposed in a space between the slide member and the guide rail member, and one end of the arm A first torsion spring coupled to a first point near the left edge and having an end of the other arm coupled to a second point in the right half region of the slide member; And A second coil wound in a circle and two arms extending a predetermined length from both ends of the second coil, the second coil being disposed in a space between the slide member and the guide rail member, and one end of the arm A second torsion spring coupled to a third point near the right edge and having an end of the other arm coupled to a fourth point in the left half region of the slide member; The guide rail member has first and second guide bars extending along opposite parallel sides of the first rectangular plate, and the first point and the third point positioned at both edges of the first rectangular plate. A coupling hole and a second coupling hole are respectively formed; The slide member is formed with a sliding engaging hand for slidably holding the first and second guide bars on opposite parallel edges of the second rectangular plate, and at the second and fourth points of the second rectangular plate. Sliding device for a mobile phone type slide characterized in that it has a structure in which the third and fourth coupling holes that can be inserted bent ends of the first and second torsion springs are formed, respectively. The sliding device of claim 1, wherein a distance between the first point and the second point is equal to a distance between the third point and the fourth point. The guide rail member of claim 1, wherein the first and second guide rails having predetermined widths and heights extend along both opposite parallel edges of the first rectangular plate, and the first and second guide rails. The outer side of the first and second guide rail grooves are formed long in the longitudinal direction, the first coupling hole and the second coupling hole in the first point of the first guide rail and the third point of the second guide rail Each has a formed structure, The slide member has protruding first and second rails formed along opposite parallel edges of the second rectangular plate, and the first and second rails slide in the first and second guide rail grooves, respectively. It is possible to engage, and the second and fourth points of the second rectangular plate has a structure in which the third and fourth coupling holes are formed, respectively, into which the bent ends of the first and second torsion springs can be inserted. Sliding device for mobile phone slide system. delete The sliding type mobile phone sliding according to any one of claims 1 to 3, wherein a plurality of screw grooves are formed on outer surfaces of the slide member and the guide rail member, respectively, for screwing the components of the mobile phone. Device.

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