KR101098147B1 - Torsion spring for a slide module - Google Patents

Abstract

According to the present invention, it is possible to better realize the slimming of a portable communication terminal operating by a slide movement method, and also by preserving the original elasticity or shape by the structural stability thereof, even if it is used for a long time, the sliding movement of the device is smooth. The spring for the slide module that can be assisted,

The present invention according to the above control the movement of the sliding module (M), the coil portion formed by including the first coil 111 and the second coil 113 having a connecting portion 115 and arranged in a stacked form between each other 110 and extending from the one end of the first coil 111 and the one end of the second coil 113 as opposed to each other as described above, the fixing ring (131, 151) is formed at each end A spring 100 having leg portions 130 and 150; For fastening the spring 100 to the sliding module (M), one side of the body 310 is provided with a fastening protrusion 311 so that the spring 100 can be fastened, the other side of the body 310 is a module ( A fastening hole 313 to be fastened to the hinge protrusion M-1 provided in M) is provided, and when the spring 100 is rotated, it rotates like the spring 100 starting from the hinge protrusion M-1. Characterized in that it comprises a fastening member 300 to be.

Slide module, spring, fastening member, communication terminal

Description

Spring for a slide module {Torsion spring for a slide module}

The present invention relates to a spring for a slide module, and more particularly, to a small terminal having a slide module such as a portable communication terminal operating by a slide movement method and allowing electrical wires such as data lines and power lines to pass inward. It is possible to realize the slimming of the terminal well, and also by preserving the original elasticity or shape by its structural stability of the spring for the slide module that can smoothly assist the sliding movement of the device even if used for a long time will be.

A mobile phone is a relatively small sized wireless communication device that allows a user to easily carry and talk on the phone. Such mobile phones can be classified into flip-type, folder-type, and sliding-type according to their appearance and operation method.

The slide-type mobile phone is provided with two sliding bodies overlapping each other, and the display unit and the key input unit are respectively installed in the same direction on the two sliding bodies. Accordingly, the slide-type mobile phone is configured to expose the key input unit provided in the sliding body at the rear by pushing the front sliding body upward, or, conversely, the rear sliding body is moved by moving the front sliding body having the key input unit downward. It is formed in a structure that exposes the display unit formed in the body.

In addition, the slide-type mobile phone is a slide module is installed between the two sliding bodies overlapping, up and down, wherein the slide module combines the two sliding bodies in a state capable of relative sliding. By this slide module, two slide bodies can be connected to each other and the slide movement can be assisted with each other.

1 and 3 are views showing the internal structure of a conventional slide-type mobile phone, as shown, the slide module spring 10 includes a spring body and a coupling member (14, 15).

The spring body is formed to include a coil portion 11 and a pair of legs (12, 13), wherein the two sides facing each other based on the cross-sectional shape is a linear material of the form parallel to each other and the coil portion (11) A pair of legs 12 and 13 are formed.

The coil part 11 includes a first coil 11-1 and a second coil 11-2 having a connection part 11-3 therebetween and arranged in a stacked form.

That is, the first coil 11-1 is disposed at the rear of the coil unit 11 relatively in a state of being connected to the leg portion 13 on one side, and the second coil 11-2 is disposed on the other leg portion ( 12 is relatively disposed in front of the coil part 11 in a state of being connected to the coil.

Accordingly, the first coil and the second coil have a surplus interval corresponding to the interval between the centers of the circles until they deform into a coincidence stacked state without disparity.

The pair of legs 12 and 13 are formed to extend in directions opposite to each other from one end of the first coil 11-1 and one end of the second coil 11-2 as described above. In other words, the pair of legs 12 and 13 are formed in directions opposite to each other about the coil portion 11.

The pair of legs 12 and 13 are rotatably coupled to the first body 62 and the second body 61, which perform relative sliding movements, respectively, so that the first body 62 and the second body ( The function of guiding the smooth slide movement while repeating the contraction and restoration according to the relative slide movement of 61).

The coupling members 14 and 15 are respectively coupled to the first body 620 and the second body 610 that perform relative sliding movement.

That is, the coupling members 14 and 15 have a function of coupling the leg portions 12 and 13 of the spring body to the first body 62 and the second body 61 in a relative sliding movement, respectively, in a rotatable state. In other words, the legs 12, 13 of the spring body is rotated to the first body 62 and the second body 61, respectively, the relative slide movement through the coupling member 14, 15, respectively. Combined as possible.

In addition, the coupling members 14 and 15 are provided with rotary hinges 14-1 and 15-1 that function as hinge shafts for rotation at one end of the coil unit 11 in a direction spaced from each other. 14-1) and 15-1 are coupled to the first body 62 and the second body 61 to form a shaft portion that functions as a rotating shaft, and one end of the shaft portion is formed with a diameter larger than that of the shaft portion. 62) and the second body 61 is formed in a shape including a head that is caught and supported by the coupling hole.

The coupling member 14 has a pair of bending protrusions 14-2 and 14-3 formed on one surface, and the pair of bending protrusions 14-2 and 14-3 are formed on the basis of the drawings. And are spaced apart from each other in the down and left and right directions. Then, the leg portions 12 are inserted through the up and down directions of the bending protrusions 14-2 and 14-3, and in this state, the leg protrusions 14-2 and 14-3 are attached to the leg portions. Press working so as to be bent in the direction of (12), whereby the bending portions 14-2a and 14-3a of the bending protrusions 14-2 and 14-3 grasp the leg 12. As such, the leg 12 is coupled to the coupling member 14.

Then, one end of the leg portion 12 is formed with a support protrusion 12-1 for being supported by the bending protrusions 14-2 and 14-3, coupled by such a support protrusion 12-1. The member 14 may be more firmly coupled to the leg 12.

The operation of guiding the slide movement is briefly described as the slide module spring 10 having the above-described configuration is installed in the slide-type portable terminal which performs the relative sliding movement.

The slide-type mobile phone 60 is formed to include a first body 62 having a keypad having a signal input function, and a second body 61 coupled to the first body 62 and having a liquid crystal display. . In addition, a sliding module is formed between the first body 61 and the first body 61, and the sliding module is formed of a guide part 61-1 coupled to an inner side surface of the first body 62. 2 is formed on the inner surface of the body 62 includes a rail portion 62-1 coupled to the guide portion 61-1 in a state in which relative sliding movement is possible.

As the first body 62 and the second body 61 of the slide-type mobile phone 60 shows the state before the relative slide movement, the slide-type mobile phone 60 in this state is usually supplied with power only, and calls or games This corresponds to a state in which the function of the slide-type mobile phone 60 is not used.

In this state, when the second body 61 is pushed up in the direction of the arrow of FIG. 16 for use of the slide-type mobile phone 60, the second body 61 of the slide-type mobile phone 60 is coupled to its inner surface. The rail part 62-1 is pushed upward while being guided along the guide part 61-1 of the first body 62.

Accordingly, the rotary hinge 14-1 of the one coupling member 14 is rotatably coupled to the first body 62 or the guide portion 61-1, and the other coupling member is coupled to the second body 61. The slide module spring 10 coupled to the rotational hinge 15-1 of the 15 in a rotatable state is narrowed with the legs 12 and 13 on both sides according to the sliding movement of the first body 62. At the same time as the contraction in the state is shown to rotate in an upward direction about the rotary hinge 14-1 coupled to the first body 62 or the guide portion 61-1.

Then, the slide module spring 10, which is contracted and rotated according to the sliding movement of the first body 62, is contracted in the state illustrated in FIG. The elasticity is applied to the second body 61 while being restored by its elasticity at the point where the second body 61 is shifted to be positioned relatively upward as the slide moves upward.

And, by the elasticity of the spring for the slide module 10 restored in this way, the second body 61 is moved in the upward direction even if the pushing force from the outside does not work.

In other words, when the second body 62 slides only to a predetermined height in a manual manner by an external force, the second body 62 is automatically moved to a final height in an automatic manner by the elasticity of the spring 10 for the slide module at the predetermined height.

However, at this time, when the support protrusion 12-1, which is formed by bending one end of the spring 10 which is fastened to the bodies 61 and 62 to the mobile phone, is driven along the bodies 61 and 62, the coupling member ( A problem arises in that it does not operate by leaving the banding protrusions 14-2 and 14-3 of 14).

That is, the support protrusion 12-1 bent in the process of moving the spring 10 along the bodies 61 and 62 when the bodies 61 and 62 are moved up and down wins the elasticity of the spring 10. It will be separated from the banding protrusions 14-2 and 14-3.

In addition, since the coupling member 14 coupled to the sliding module is rotated together during the operation of the spring 10, the sliding module portion to which the coupling member 14 is fastened is worn so that the coupling member 14 is detached and thus the coupling member ( 14) spring 10 that is fastened by the operation is also a problem that is separated.

In addition, in the above case, it is necessary to secure a space in which the coupling member 14 having a predetermined thickness is rotated, so that there is a problem in that the slimming of the terminal having the sliding module cannot be realized.

The present invention has been invented to solve the conventional problems as described above has the following object.

The present invention is applied to a small terminal having a slide module, such as a data communication line or a power line in an inward direction, such as a portable communication terminal operating by a slide movement method, so that the terminal can be made slimmer. In addition, it is an object of the present invention to provide a spring for the slide module that can smoothly assist the sliding movement of the device even if used for a long time by preserving the original elasticity or form by its structural stability.

The present invention for achieving the above object is implemented by an embodiment having the following configuration.

According to the first embodiment of the present invention, the spring for the slide module of the present invention

By controlling the movement of the sliding module (M), the coil portion 110 formed by including the first coil 111 and the second coil 113 having a connecting portion 115 and disposed in a stacked form, and the As shown in the drawing, the end portions of the first coil 111 and the second coil 113 extend in directions opposite to each other, respectively, and the leg portions 130 and 150 having the fixing rings 131 and 151 formed thereon, respectively. A spring 100;

For fastening the spring 100 to the sliding module (M), one side of the body 310 is provided with a fastening protrusion 311 so that the spring 100 can be fastened, the other side of the body 310 is a module ( A fastening hole 313 to be fastened to the hinge protrusion M-1 provided in M) is provided, and when the spring 100 is rotated, it rotates like the spring 100 starting from the hinge protrusion M-1. Characterized in that it comprises a fastening member 300 to be.

According to a second embodiment of the invention, the spring for the slide module of the present invention

The coil part and the leg part may be formed in the range of 0.4 to 1 mm in total width in the direction perpendicular to the thickness direction based on the cross-sectional shape in the thickness direction, and the thickness is formed in the range of 0.25 to 0.7 mm.

According to a third embodiment of the present invention, the spring for the slide module of the present invention

The fastening member 300 is fastened to the hinge protrusion (M-1), but inserted into the hinge protrusion (M-1) through the fastening hole (313) and then burring the end of the hinge protrusion (M-1) It is characterized in that fixed to the module (M).

According to the fourth embodiment of the present invention, the spring for the slide module of the present invention

The fastening member 300 is provided with a hinge protrusion 315 integrally at one end of the body 310, and then provided with a fastening hole (M-2) in the module (M) to fasten the hinge protrusion (315). It is characterized in that it is inserted into the (M-2) and fixed to the module (M).

The present invention has the following effects by the above configuration.

The spring for the slide module of the present invention is applied to a small terminal that has a slide module and passes an electric line such as a data line or a power line in an inward direction, such as a portable communication terminal operated by a slide movement method, thereby making the terminal slimmer. Has the effect of making it well implemented

In addition, by preserving the original elasticity or form by its structural stability, even if used for a long time has the effect that can smoothly assist the sliding movement of the device.

Applicants will now be described in detail the configuration of the present embodiments with reference to the accompanying drawings.

Detailed descriptions of well-known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention will be omitted.

Figure 4 is an exploded perspective view showing a spring according to the present invention, Figure 5 is a perspective view showing a spring according to the present invention, Figure 6 is a sectional view according to the present invention, Figures 7 and 8 are perspective views showing another example according to the present invention. .

The present invention is largely composed of a fastening member 300 for fastening the spring 100 and the spring 100 to the slitting module.

The spring 100 includes a coil part 110 and a pair of leg parts 130 and 150, wherein two sides facing each other based on a cross-sectional shape are formed of a linear material having a parallel shape with each other. 110 and a pair of legs 130, 150 are formed.

Legs 130 and 150 have a cross section of the side of the upper side and the side of the lower side, the side of the left side and the right side has a cross section of the form of a round in the direction opposite to each other.

In this case, the length of the line segment connecting the two sides parallel to each other in the shortest distance is formed to be shorter than the length of one of the two sides parallel to each other.

That is, the linear material forming the coil unit 110 and the pair of legs 130 and 150 is not a wire rod having a circular cross section (hereinafter, abbreviated as a circular wire rod) but has a flat cross section having a flat shape near a rectangle or a rectangle. In the form of

Here, the linear material having a rectangular cross section (hereinafter, abbreviated as a rectangular wire rod) has a strong elasticity in comparison with a circular wire rod due to its structural characteristics.

In other words, even if the rectangular wire is formed in a shape having a width and thickness of the same length as the diameter of the circular wire, the rectangular wire is a structure that further includes four corner portions that are not in the circular wire, so that the rectangular wire has a wide cross-sectional area Due to the characteristics of the torsion spring having a relatively large elasticity, the torsion spring formed of a circular wire has a relatively strong elasticity.

Accordingly, the spring body of the present embodiment can exhibit greater elasticity in the same installation space as compared with the conventional torsion springs of the circular wire rod, so that the spring body can be applied to the sliding module of the slide-type mobile phone and more smoothly without expanding the thickness of the slide-type mobile phone. Operation can be enabled. In addition, the spring body can perform a larger number of shrinkage and restoration operations than the torsion spring of the circular wire without generating an abnormal twist phenomenon due to the improved elasticity.

In addition, the rectangular wire is formed in the range of 0.4-1 mm in total width in the direction perpendicular to the thickness direction on the basis of the cross-sectional shape in the thickness direction and in the range of 0.25-0.7 mm in thickness.

If one leg 130 formed of a rectangular wire is described as an example, the width of one leg 130 is formed within the range of 0.4 ~ 1mm, the thickness is formed within the range of 0.25 ~ 0.7mm do.

In addition, the rectangular wire may be formed of any one of the spring wire, piano wire, SUS304, SUS631, SUS403, shape memory alloy or elastic oral cavity. In other words, the coil part and the leg part of the spring body are formed of any one of the spring wire, piano wire, US304, SUS631, SUS403, shape memory alloy or elastic tool steel.

Next, the coil part 110 and the pair of leg parts 130 and 130 of the spring body formed of the rectangular wire as described above will be described.

The spring 100 controls the movement of the sliding module M, and includes a pair of leg parts 130 and 150 extending from the coil part 110 and the coil part 110 of the spring 100. In this case, the coil unit 110 and the pair of legs 130 and 150 are formed in parallel to each other with two sides facing each other based on the cross-sectional shape.

The coil unit 110 is formed to include a first coil 111 and a second coil 113 having a connecting portion 115 and mutually arranged in a stacked form.

That is, the first coil 111 is relatively disposed in front of the coil unit 110 in a state of being connected to the leg portion 130 on one side, the second coil 113 is connected to the other leg portion 150 It is disposed relatively behind the coil unit 110.

Accordingly, the first coil and the second coil have an excess gap corresponding to the distance between the centers of the circles until they are deformed into a coincidence stacked state without misalignment.

The pair of legs 130 and 150 extend in directions opposite to each other from one end of the first coil 111 and one end of the second coil 113 as described above. In other words, the pair of leg parts The 130 and 150 are formed in directions opposite to each other with respect to the coil unit 110.

End portions of the leg portions 130 and 150 are fixed ring 131 and 151, respectively, are fastened to the hinge 300 to be described below.

The pair of legs 130 and 150 are rotatably coupled to the first body 620 and the second body 610 of the module for relative sliding movement, respectively, so that the first body 620 and the second body 610 are rotated. The function of guiding a smooth slide movement while repeating contraction and restoration according to relative slide movement of).

The fastening member 300 is for fixing the spring 100 to the sliding module (M), one side of the body 310 is provided with a fastening protrusion 311 to be fastened to the spring 100, the body ( The other side of the 310 is provided with a fastening hole 313 to be fastened to the hinge projection (M-1) provided in the module (M).

The fastening member 300 is for fastening the spring 100 to the module M. When the module M is slid and the spring 100 is rotated, the fastening member 300 is also rotated together.

That is, the fastening member 300 to which one end of the spring 100 is fastened is rotated together with the spring 100 based on the hinge protrusion M-1 when the module M is rotated.

The fastening member 300 is fastened to the hinge protrusion (M-1), but inserted into the hinge protrusion (M-1) through the fastening hole (313) and then burring the end of the hinge protrusion (M-1) The fastening member 300 is fixed.

Then, as shown in FIG. 8, the hinge protrusion 315 is integrally provided at one end of the body 310, and then the hinge protrusion 315 is provided by the fastening hole M-2 in the module M. The fastening member 300 may be fixed by being inserted into the fastening hole M-2.

Hereinafter, with reference to the accompanying drawings look at the fastening and action of the present invention.

9 is a flow chart showing a fastening state according to the present invention, Figure 10 is a plan view showing an operating state according to the present invention a is an initial state, b is an operating state.

Fastening the spring 100 to the module (M), the process is as follows.

First, the spring 100 is fastened to the fastening protrusion 311 of the fastening member 300, and then the fastening protrusion 311 is burked to fasten the spring 100.

Thereafter, the fastening member 300 is fastened to the hinge protrusion M-1 provided in the module M through the fastening hole 313 provided at one end of the body 310.

After fixing the fastening member 300 by burring the failure projection (M-1).

When the spring 100 is fastened to the module M as described above and then the second body 610 is pushed up for use of the slide-type mobile phone, the second body 610 of the slide-type mobile phone is coupled to the inner surface thereof. The rail part 621 is pushed upward while being guided along the guide part 611 of the first body 620.

At this time, the spring 100 is contracted in a state in which both legs 130 and 150 are narrowed according to the sliding movement of the first body 620, and the fastening member 300 to which the spring 100 is fastened is a hinge protrusion (M-). It is rotated like the spring 100 from 1).

In addition, the slide module spring 100 that contracts and rotates according to the sliding movement of the first body 620 is contracted, and one leg 130 of the second body 610 is located at a lower side of the second body 610. The elasticity is applied to the second body 610 while being restored by its elasticity at the point where it is shifted to be positioned relatively upward as the slide moves upward.

And, by the elasticity of the spring 100 to be restored in this way, the second body 610 is moved in the upward direction even if the pushing force from the outside does not work.

That is, when the second body 620 slides only to a predetermined height in a manual manner by an external force, the second body 620 is slid to a final height in an automatic manner by the elasticity of the spring 100 at the predetermined height.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and it is common in the art that various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

1 is a perspective view showing a conventional spring,

2 is a perspective view showing a state in which a conventional spring is fastened,

3 is a plan view showing a conventional spring operation state

a is the initial state b is the activated state

4 is an exploded perspective view showing a spring according to the present invention

5 is a perspective view showing a spring according to the present invention

6 is a cross-sectional view according to the present invention

7 and 8 are a perspective view showing another example according to the present invention

9 is a flow chart showing a state of being engaged in accordance with the present invention

10 is a plan view showing an operating state according to the present invention;

a is the initial state b is the activated state

Explanation of symbols on the main parts of the drawings

100: spring 131,151: fixed ring

300: fastening member 311: fastening protrusion

Claims (4)

By controlling the movement of the sliding module (M), the coil portion 110 formed by including the first coil 111 and the second coil 113 having a connecting portion 115 and disposed in a stacked form, and the As shown in the drawing, the end portions of the first coil 111 and the second coil 113 extend in directions opposite to each other, respectively, and the leg portions 130 and 150 having the fixing rings 131 and 151 formed thereon, respectively. A spring 100; For fastening the spring 100 to the sliding module (M), one side of the body 310 is provided with a fastening protrusion 311 so that the spring 100 can be fastened, the other side of the body 310 is a module ( A fastening hole 313 to be fastened to the hinge protrusion M-1 provided in M) is provided, and when the spring 100 is rotated, it rotates like the spring 100 starting from the hinge protrusion M-1. In the spring for the slide module, characterized in that it comprises a fastening member 300, The coil part and the leg part has a total width in a direction perpendicular to the thickness direction based on the cross-sectional shape in the thickness direction is formed in the range of 0.4 ~ 1mm, the thickness is a slide module spring, characterized in that formed in the range of 0.25 ~ 0.7mm . delete The method of claim 1, The fastening member 300 is fastened to the hinge protrusion (M-1), but inserted into the hinge protrusion (M-1) through the fastening hole (313) and then burring the end of the hinge protrusion (M-1) Spring for slide module, characterized in that fixed to the module (M) The method of claim 1, The fastening member 300 is provided with a hinge protrusion 315 integrally at one end of the body 310, and then provided with a fastening hole (M-2) in the module (M) to fasten the hinge protrusion (315). Slider spring for inserting (M-2), characterized in that fixed to the module (M).

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