KR20070106480A - Slide hinge module and elastic member applied thereof - Google Patents

Abstract

A slide hinge module and an elastic body applied to the same are provided to offer enough pressure, to reduce an overall manufacturing cost, and to make a device thinner by applying constant force spring with one W type to the slide hinge module. A slide hinge module comprises a guide plate(10), a rail plate(20), and an elastic body(30). The guide plate(10) is installed at one between the first body and the second body. The rail plate(20), installed at the other between the first body and the second body, guides the guide plate(10). The elastic body(30), installed between the first body and the second body, puts pressure to the guide plate(10) in mutually contrary directions on the basis of an inflection point. The elastic body(30) includes one end fixed at the guide plate(10), the other end fixed at the rail plate(20), and at least three coil portions. The coil portions store elastic force and use a constant force spring which is extended in a zig-zag type and has a regular gap.

Description

SLIDE HINGE MODULE AND ELASTIC MEMBER APPLIED THEREOF

The present invention relates to a device including a first body and a second body that performs a sliding operation by a predetermined length in the longitudinal direction in the first body, in particular interposed between the first body and the second body of the target body A slide hinge module for providing a pressing force in a direction to be opened or closed based on a predetermined inflection point and an elastic body applied thereto.

In recent years, various electronic devices have been released to have a sliding structure having a target body in a single bar type by riding on a user's preference. In particular, as portable terminals become more widely available, terminals having various functions and designs are being released to meet user needs. The terminals have been developed from general bar type terminals to flip type terminals, flip-up type terminals, folder type terminals, and the like. Type terminals are mainstream. This is because the folder type terminal has enough space to adopt the wide LCD module as the display device, and because it is folded in half and portable, the portability is superior to other terminals.

On the other hand, there is a display device having a wide LCD module having a size similar to the folder-type terminal described above, and at the same time a terminal of the type that can contribute to the miniaturization of the terminal has emerged. This is a slide type terminal in which a sub body (hereinafter referred to as a 'slide body') is opened by sliding a predetermined length in a length direction of a terminal on a predetermined main body. It has the advantage to meet.

The slide type terminal may be configured in a state in which the slide body is slid to the lower side or the upper side to open about 1/2 of the length of the main body when opened based on the main body. Limited to 1/2, but may be more open), generally 3x4 keypad assembly can be installed on the main body, the display device can be installed on the front of the slide body.

The slide hinge module described above is provided with a predetermined plate on the contact surface of the main body and the slide body, respectively, and operated by the guide operation in the longitudinal direction of the terminal between the plates, the slide in the direction of opening or closing based on a predetermined inflection point And pressing means for continuously pressing the body.

Between the plates described above, a predetermined elastic means is applied to provide the aforementioned pressing force. Conventionally, a pair of torsion springs are interposed for operation stability, and one end of each torsion spring is provided to the first body and the other end to the second body, thereby providing a pressing force.

However, the above-mentioned elastic means are generally installed in pairs, that is, two, so that not only the overall manufacturing cost of the device increases, but also the installation space for applying two springs to a device that is gradually becoming smaller and lighter.

In order to solve the problems as described above, an object of the present invention is to provide a slide hinge module and an elastic body that is configured to have a sufficient pressing force even if one elastic member is applied.

It is another object of the present invention to provide a slide hinge module and an elastic body applied thereto to implement a single elastic body to reduce the overall manufacturing cost of the device.

It is still another object of the present invention to provide a slide hinge module and an elastic body applied thereto while providing operational stability and providing ease of installation.

In order to solve the above object, the present invention provides a slide hinge module of a device comprising a first body and a second body that performs a sliding operation in the longitudinal direction in the first body, the first A guide plate installed on the body of any one of the body or the second body, a rail plate installed on the remaining body and guided by the guide plate, and installed between the guide plate and the rail plate, and the guide plate based on a predetermined inflection point. It includes an elastic body for pressing in opposite directions to each other, wherein the elastic body is fixed to the guide plate, the other end is fixed to the rail plate, at least three coils are stored in a zigzag form at a predetermined interval in the elastic force is integral Tuck spring is used to form It is done.

Since the slide hinge module according to the present invention applies one W-type static spring, sufficient pressing force is provided, and the overall manufacturing cost of the device is reduced, which contributes to slimming of the device.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, if it is determined that the gist of the present invention may be unnecessarily obscured, the detailed description thereof will be omitted.

In describing the present invention, the slide type portable terminal is illustrated and the slide hinge module applied thereto is described, but the present invention may be applied to various slide type devices to which the slide hinge module including the technical idea of the present invention can be applied. .

1 is a perspective view of a slide type portable terminal 100 to which a slide hinge module and an elastic body are applied according to the present invention, and the main body 110 and the longitudinal direction of the terminal 100 in the main body 110 (see FIG. 1). A slide body 120 slidable in the direction of the arrow).

A plurality of key buttons 111, which are data input means, may be installed on a surface of the main body 110 when the slide body 120 is opened. The microphone device 112 is installed below the key button 111.

The display device 121 is installed on the slide body 120 over the front surface, and a speaker device 122 is installed above the display device.

On the other hand, the slide body 120 performs a sliding operation in the longitudinal direction of the terminal 100 in the main body 110, the slide body 120 at a position of approximately 1/2 of the total flow distance The pressing force changes in the direction of opening or closing. This changing pressing force is due to the slide hinge module according to the present invention interposed between the main body 110 and the slide body 120.

2 is a configuration diagram of a slide hinge module to which the elastic body according to the present invention is applied, the guide plate 10 and the rail plate 20 for performing a sliding operation on the rail plate 20 and the rail plate 20 and It includes an elastic body 30 interposed between the guide plate 10. Referring to FIG. 1, the rail plate 20 may be fixed to the rear surface of the slide body 120, and the guide plate 10 may be installed on a surface in contact with the slide body 120 of the main body 110. Can be.

In addition, although not shown, the rail plate 20 and the guide plate 10 may be guided by known guide means. For example, guide ribs may be formed on both sides of one of the plates, and guide slits may be formed by inserting the guide ribs into the remaining plates.

As the elastic body 30, a tension spring according to the present invention having a W shape is used. The tuck spring will be described in more detail below.

Predetermined rotary bushings 40 are fixed to both ends of the vibrating spring 30 so as to enable self-rotation respectively in the bushing fixing holes 11 and 12 formed in the guide plate 10 and the rail plate 10. It is fixed. More specifically, the rotary bushing 40 fixed to one end of the energizing spring 30 will be fixed to the bushing fixing hole 11 of the guide plate 10, and the rotary bushing fixed to the other end of the energizing spring 30. The bushing 40 may be fixed to the bushing fixing hole 12 formed in the rail plate 20.

Figure 3 is a view showing the structure of the elastic body according to the present invention, the energizing spring 30 used as the elastic body according to the present invention, as shown in (a) a plurality of coils have a W shape in a zigzag form. The spring 30 may be formed of SUS material. Both ends of the tension spring 30 is formed of a first fixed end 34 and a second fixed end 37. The rotary bushing 40 is fixed to each of the fixed ends 34 and 37. The first coil part 31 sequentially wound in one direction from the first fixing end 34 extends, and the second coil part 32 is formed through the first connection part 35 having a predetermined length. The third coil part 33 is sequentially formed after the second connection part 36. The first fixing end 34, the first coil part 31, the first connector part 35, the second coil part 32, the second connector part 36, the third coil part 33, and the second fixing part 34. The stage 37 is integrally formed to extend.

Furthermore, each of the coil parts 31, 32, and 33 has a winding direction in which the coils are wound with other neighboring coil parts in opposite directions to provide even elastic force. In addition, as shown in (b), the winding start portion of each coil portion 31, 32, 33 is to start in the opposite direction to the neighboring coil portion, and has a plurality of windings so as to have concentric circles and different diameters This prevents an increase in the overall thickness of the energizing spring.

4 is a view illustrating a rotary bushing 40 for fixing an elastic body according to the present invention, wherein a circular shaft portion 41 and a fixing portion 42 extending to be larger than a diameter of the shaft portion 41 are formed. It includes. In the present invention, the metal spring 30 and the plastic rotary bushing 40 do not have an insert molding requiring a separate process. A hollow fixing hole 44 is formed in the rotary bushing 40 so that the bent portion of the fixing ends 34 and 37 of the tuck spring 30 is fixed to the fixing hole 44 in an interference fit manner. . Furthermore, by forming the inlet 43 into the lower side of the shaft portion 41 to the fixing hole 44, even if the fixing end (34, 37) of the tension spring (30) is fixed to the rotary bushing (40) The end was not protruded.

5 is an operation of the slide hinge module 1 according to the present invention, (a) is a view of the moment when the guide plate 10 is located at the inflection point on the rail plate 20, (b) is a guide plate 10 ) Shows a state in which the rail plate 20 is completely opened or closed in one direction.

In the case of (a), the bushing fixing hole 11 of the guide plate 10 and the bushing fixing hole 12 of the rail plate 20 have the shortest distance, and the energizing spring 30 has the maximum elastic force. It is getting smaller while saving. In this state, when the guide plate 10 is lowered in the direction of the arrow in (b), the vibrating spring 30 presses the guide plate 10 in the direction to be lowered on the rail plate 20 at the stored pressure. Will be. In addition, even when the guide plate 10 is completely lowered, the vibrating spring 30 is installed in a state in which one end of the elastic force is stored, so that the guide plate 10 does not flow to maintain the lowered state. Will be.

6 is a perspective view of an elastic unit 3 applied to a slide hinge module according to another embodiment of the present invention, Figure 7 is an internal configuration of the elastic unit of FIG. It consisted of one elastic unit without being applied between the guide plate and the rail plate.

 The elastic unit 3 according to the present invention includes a base 50 on which the energizing spring 30 is loaded, and a first link 61 and a first link 61 installed to be inserted into the base at both ends of the base 50. Two links 62. At least one locking piece 612, 622 is formed at each end of the first link 61 and the second link 62 in the direction in which the first link 61 and the second link 62 are inserted into the base 50. The catching portions 51 to which the pieces 612 and 622 are caught are formed so that the first and second links 61 and 62 are not completely separated from the inside of the base 50.

In addition, both ends of the energizing spring 30 is installed in a state in which each of the links (61, 62) is pressed out of the base (50). Accordingly, each of the links 612 and 622 is maintained to protrude out of the base 50 as much as usual. In addition, a first bushing 611 and a second bushing 621 are formed at ends of the links 61 and 62 so that the bushing fixing hole 11 of the guide plate 10 and the bushing of the rail plate 20 are respectively formed. It can be installed rotatably in the fixing hole (12).

Preferably, the ends of both fixed ends of the energizing spring (10) is formed to be curled, so as to smoothly press the ends of the respective links.

FIG. 8 is an operation view of the slide hinge module 2 to which the elastic unit 3 of FIG. 6 is applied, in which (a) is a state where the guide plate 10 is positioned on the rail plate 20 at the top, and (b) Is a view of the instant located at the inflection point, (c) shows a state where the guide plate 10 is located at the lowest end in the rail plate (20).

In the case of (b), the bushing fixing hole 11 of the guide plate 10 and the bushing fixing hole 12 of the rail plate 20 are in a state where the distance is shortest, and the energizing spring 30 has the maximum elastic force. It is getting smaller while saving. Therefore, the first and second links 61 and 62 are also inserted into the base 50 as much as possible. In this state, when the guide plate 10 is raised or lowered in the direction of the arrow of (a) or (b), the vibrating spring 30 presses each of the links 61 and 62 with the stored pressing force. The pressing force of the links 61 and 62 to protrude is to press the guide plate 10 in a direction to raise or lower. In addition, even when the guide plate 10 is fully raised or lowered, the vibrating spring 30 is installed in a state in which one end of the elastic force is stored, so that the guide plate 10 is raised or lowered without flowing. The state will be maintained.

Apparently, there are many different ways to modify these embodiments while remaining within the scope of the claims. In other words, there may be many other ways in which the invention may be practiced without departing from the scope of the following claims.

1 is a perspective view of a slide type portable terminal to which a slide hinge module and an elastic body according to the present invention are applied;

2 is a block diagram of a slide hinge module to which the elastic body according to the present invention is applied;

3 is a view showing the structure of an elastic body according to the present invention;

4 shows a rotary bushing for fixing an elastic body according to the invention;

5 is an operation of the slide hinge module according to the present invention;

6 is a perspective view of an elastic unit applied to a slide hinge module according to another embodiment of the present invention.

7 is an internal configuration diagram of the elastic unit of FIG. 6; And

8 is an operation of the slide hinge module to which the elastic unit of Figure 6 is applied.

Claims (16)

In the slide hinge module of the device including a first body and a second body for performing a sliding operation in the longitudinal direction from the first body, A guide plate installed on the body of any one of the first body and the second body; A rail plate installed on the remaining body to guide the guide plate; And Is installed between the guide plate and the rail plate includes an elastic body for pressing the guide plate in the opposite direction relative to a predetermined inflection point, The elastic body, One end is fixed to the guide plate, the other end is fixed to the rail plate, the slide hinge module, characterized in that at least three coils for storing the elastic force using a static spring is formed integrally at regular intervals in a zigzag form. The method of claim 1, The tuck spring is a slide hinge module, characterized in that the three coil portion is formed extending at a predetermined interval. The method of claim 2, Each coil unit is wound in a circular number of times, the slide hinge module, characterized in that the winding direction with the neighboring coil unit in the opposite direction. The method of claim 3, wherein Each coil unit is wound in a circular number of times, the slide hinge module, characterized in that formed in a spiral manner having concentric circles and different diameters. The method of claim 4, wherein The coil hinge module, characterized in that the position in which the first winding is started in the opposite direction to the neighboring coil unit. The method of claim 5, Cylindrical rotary bushings are fixed to both ends of the vibrating spring, and a bushing fixing hole is formed in each of the plates so that the rotary bushing is partially inserted to enable self-rotation. The method of claim 6, The rotating bushing is a hollow fixing hole is formed, the end portion of the tuck spring is bent so that the bent portion is fixed to the fixing hole in the slide hinge module, characterized in that. In the slide hinge module of the device including a first body and a second body for performing a sliding operation in the longitudinal direction from the first body, A guide plate installed on the body of any one of the first body and the second body; A rail plate installed on the remaining body to guide the guide plate; And It is installed between the guide plate and the rail plate includes an elastic unit for pressing the guide plate in the opposite direction relative to a predetermined inflection point, The elastic unit, A rectangular base having an inner space; An elastic body installed inside the base; And It is inserted into both ends of the base and guided and intermittently prevented from being separated from the outside, and includes a pair of links installed to be pressed outward by the elastic body, the one end of the link is capable of self-rotating the guide plate And the other link end is fixed to the rail plate so as to be self-rotating. The method of claim 8, The elastic body, One end is fixed to the guide plate, the other end is fixed to the rail plate, the slide hinge module, characterized in that the three coil parts for storing the elastic force is used in a zigzag form with a fixed spring is formed integrally. The method of claim 9, Each coil unit is wound in a circular number of times, the slide hinge module, characterized in that the winding direction with the neighboring coil unit in the opposite direction. The method of claim 10, Each coil unit is wound in a circular number of times, the slide hinge module, characterized in that formed in a spiral manner having concentric circles and different diameters. The method of claim 11, The coil hinge module, characterized in that the position in which the first winding is started in the opposite direction to the neighboring coil unit. In the elastic body applied to the slite type device comprising a rail plate installed on the first body and a guide plate installed on the second body guides the rail plate, The elastic body, One end is fixed to the guide plate, and the other end is fixed to the rail plate, and the three coil parts for storing the elastic force are fixed in a zigzag form by using an energizing spring that is formed integrally and the guide plate is in an inflection position. Elastic material, characterized in that it provides a constant pressing force in the direction in which it is pressurized. The method of claim 13, The coil portion is wound in a circular number of times, the elastic body, characterized in that the winding direction with the neighboring coil portion in the opposite direction. The method of claim 14, The coil portion is wound in a circular number of times, the elastic body, characterized in that formed in a spiral manner having concentric circles and different diameters. The method of claim 15, Wherein each of the coil parts is in a direction opposite to the neighboring coil parts at a position where the initial winding is started.

Images