KR20090082953A - Slide type opening and closing module using super elastic material - Google Patents

Abstract

The present invention relates to a technical concept of applying an elastic body using a superelastic material to a slide type opening and closing module for a mobile communication terminal. It is also simplified in size, has the advantages of cost reduction and mechanical design.

Description

Opening Module using Ultra-elastic Material for Sliding Hand-held Device}

The present invention relates to a slide type opening and closing module, and more particularly, to a technical concept of applying an elastic body using a superelastic material to a slide type opening and closing module for a mobile communication terminal.

Slide-type opening and closing module is a structure that is composed of the upper and lower nutrient chain body portion and the front portion overlapping each other and the front and rear part is opened and closed based on the body portion by an elastic body (spring module) interposed therebetween.

In this case, the elastic body used uses a micro-processed spring by minimizing its diameter so that it can be applied to a small device such as a mobile communication terminal. However, the elastic body can be further reduced in order to serve as an elastic body in the spring field, the number of turns, and the outer diameter. As there is no limit, it is an obstacle to miniaturization and slimming of the terminal.

The conventional elastic body has a structure in which one elastic body increases the elastic limit by forming a turn in the thickness direction, as shown in FIG. 1, and one side of both ends of the elastic body 11 has a lower portion of the front part 12. Attached to and the other side of both ends is attached to the upper portion of the body portion 13 to connect the nutrients to provide an elastic force to perform the sliding operation.

However, the elastic body has a problem of increasing the thickness of the terminal by multiplying the wire diameter and the number of turns while forming turns in the thickness direction of the terminal.

Accordingly, as shown in FIG. 2, a module using a single-layer spring 21 having a torsion formed on the same plane in the width direction has been proposed, which is effective in reducing the thickness of the terminal, but increases the length of the deployment field to increase the spring force. Because of this decrease, since two or more springs must be used, there is a problem that an area occupied by the elastic body and a driving area increase.

In addition, the conventional elastic body as described above has a weak elastic limit of 200 ~ 300gf and the degree of elastic deformation does not exceed 1% of the original shape, the spring may be deformed or worn when repeated motion or an external force greater than the elastic limit is applied. The possibility of disconnection also exists and there was a problem that application of a product requiring more deformation in a more limited space is very difficult.

In addition, recently, models that require long strokes of 4-50 mm or more have been released. However, in order to prevent inconvenience in using long strokes, the product must be used under the same use conditions. Excitation-type opening and closing module should be provided, and for this purpose, the deformation amount of the elastic body (spring module) and the dead point forming position are key.

In the slide-type opening and closing module, it is an object of the present invention to provide a slide-type opening and closing module that can minimize the area occupied by the elastic body to simplify the structure while increasing the amount of deformation to increase the degree of freedom in forming the operating force and dead point.

The present invention includes a main body portion and a front portion coupled to allow the sliding movement on the main body portion, and an elastic body is interposed between the main body portion and the front portion to provide an elastic force to the slide movement on the main body portion. In the slide type opening and closing module, the elastic body is a super-elastic material, bent in a semi-circular arc, both ends are coupled to the upper surface of the body portion and the lower surface of the front portion, the dead point of the elastic body in accordance with the required stroke It provides a slide-type opening and closing module, characterized in that the position of the end coupled to the upper surface of the main body portion can be changed to a point in the longitudinal direction of the main body portion to change the.

According to another feature of the invention, the lower portion includes a main body portion and a front portion coupled to enable the sliding movement on the main body portion, an elastic body is interposed between the main body portion and the front portion so that the front portion slides on the main body portion In the slide-type opening and closing module configured to provide an elastic force to the movement, the elastic body is a superelastic alloy material, is bent in a semicircular arc, both ends are coupled to each of the upper body and the lower surface of the front coupling portion Wherein, the coupling portion is a structure that can correspond to the coupling portion on the body portion and the front portion provides a slide-type opening and closing module, characterized in that formed integrally by heat fusion or insert injection when forming the elastic body.

According to another feature of the invention, the lower portion includes a main body portion and a front portion coupled to enable the sliding movement on the main body portion, an elastic body is interposed between the main body portion and the front portion so that the front portion slides on the main body portion In the slide-type opening and closing module configured to provide an elastic force to the movement, the elastic body is a super-elastic alloy material, bent in a semicircular arc, both ends are coupled to the upper surface of the body portion and the lower surface of the front portion, respectively. Provided is a slide-type opening and closing module, characterized in that formed in a structure corresponding to the shape of the coupling portion on the body portion and the front portion.

According to the present invention, not only to provide a stronger spring force by using a wide elastic limit peculiar to the superelastic material, the opening and closing operation of the slide-type opening and closing module is stable and free dead point change is possible, but also excellent durability and structurally simple Due to the miniaturization, there are advantages of cost reduction and mechanical design.

Hereinafter, the technical spirit of the present invention will be described in detail with reference to the accompanying drawings. However, the same configuration that does not change even if the embodiment is different will be described using the same reference numerals.

3 is a slide-type opening and closing module for a mobile device according to the present invention, having a front portion 31 and a body portion 32 capable of performing slide-type opening and closing, and the front portion 31 includes a guide portion 33. Accordingly, the upper and lower slides are operated without departing from the main body 32.

Here, the front portion 31 and the main body portion 32 are connected by the elastic body 34 to provide an elastic force during the slide operation and the movement range during the slide is limited.

Both ends of the elastic body is fixed to an appropriate position of the upper end of the main body portion 32, the other end of the lower end of the front portion 31 by using a coupling member (34a) such as rivets.

The guide part 33 allows the front part 31 to be fixed on the main body part 32 so that the vertical sliding operation can be performed. As shown, the guide part 33 is bent at both sides of the front part 31 and the main body part 32 is shown. ) And a buffer member 33a, such as a POM material, is inserted into the bent side surfaces of the front part 31 to prevent direct contact between the nutrient bodies and to allow the sliding operation to be performed more smoothly. desirable.

Since the elastic body 34 has a very simple shape as an arch shape bent in a semicircular arc shape, the elastic body 34 is completed by only bending the superelastic alloy once and performing heat treatment to simplify the manufacturing process.

In order for the elastic body to be heat-treated in an arc shape, the material is made of nickel and titanium as the main shape memory alloy, but provides superelastic effect without abnormal operation between -30 ° C and 100 ° C and fatigue characteristics, compared to general shape memory alloy. It should be a superelastic alloy that is an alloy material with improved acid and salt spray properties.

In addition, the superelastic alloy applied to the present invention can be deformed up to 8% in the case of commercially available products, but the spring is designed as a product having an elastic deformation range of 3 to 5% to enable stable product durability. .

The elastic deformation amount is a property that determines how much the elastic body can repeatedly move on the same trajectory without being deformed. The elastic deformation amount may be used as a measure of inducing load distribution by uniformly distributing deformation in the product through bending of the product.

The elastic body required in the present invention is a super-elastic material that can have a stable durability without breaking the elastic deformation amount in the 3 ~ 5% as described above, it was designed depending on the elastic force within the elastic limit within 0.2 ~ 0.5% of ordinary metal Unlike conventional elastomers, the phase change temperature of martensite and austenite is realized between -30 ° C and 100 ° C while having the basic properties of shape memory alloy, and exhibits superelastic properties at room temperature. The addition of heat treatment, coating treatment, etc., mechanical and thermal properties were adjusted to fit the mobile elastomer.

Therefore, in the present invention, when the elastic body made of the superelastic alloy material is used, it uses a characteristic of high bending force rather than shape memory characteristics, and it is most used in IT devices as compared with tension and compression force of general coil springs or shape memory alloys. On the basis of the same wire diameter of 0.3 ~ 1 mm used, it is possible to realize the extremely high bending force of 3 to 4 times more by adjusting the extension length and free height, so that only one elastic body can perform the desired function.

This means that the elastic body can perform its function even in a single curved shape or an arc shape in which no turns in different directions are formed, thereby providing many advantages in the design of a portable device.

One end of the elastic body is fixed to the front portion 31, the other end is fixed to the main body portion 32 to provide an elastic force when sliding, a separate coupling structure by a method of coupling both ends of the elastic body and the front portion and the main body portion. There are cases in which these elastic bodies are formed at both ends (see FIG. 4) and the elastic body itself is used as it is (see FIGS. 3 and 5).

In the case of adopting a separate coupling structure, as shown in Figure 4, the front portion 31 and the body portion 32 is formed with grooves or through-holes (311, 321) and the coupling structure 341 that can be fitted to the two ends of the elastic body Can be coupled to.

In order to couple the coupling structure 341 to both ends of the elastic body, it is desirable to enable a firm coupling while simplifying the manufacturing process through insert injection when forming the elastic body.

In the case of using the elastic body as it is, as shown in Figure 3, the front portion and the main body portion may be provided with a rivet structure (34a), and both ends of the elastic body can be bent to the elastic end to be coupled to the rivet.

In addition, as shown in Figure 5, the front portion 31 and the main body portion 32 is provided with a through hole (A), both ends of the elastic body is inserted into the through hole (A) and then bent in an appropriate direction to be rotatably coupled can do.

Operation of the slide-type opening and closing module according to the present invention as shown in Figure 6, the slide-type opening and closing module according to the present invention can provide an arc-shaped elastic body of a superelastic alloy material, unlike Figure 2 can be implemented with only one Therefore, the movement space of the elastic body is minimized when the opening and closing operation is performed as in <-> (b) <-> (c). In addition, because of the arched shape, the sliding force can be provided to almost uniform level at any point during the sliding operation, and the sliding is strong at both ends to solve the conventional problem of impacting the device. give.

The elastic body of the present invention can realize a sufficient bending force even if the wire diameter of the spring is reduced to allow a thinner mechanism design. When the single-layer spring is used, the present invention has a plane trajectory area of 0.7 times as long as it uses high bending force. It can be reduced below to provide a variety of mechanism design, and has a deformation rate in the range of 3 to 5%, thus providing 100,000 reciprocating drive reliability.

In addition, since the elastic body is formed in an arc shape, the spring used in the prior art has been reduced by one to two, and the total length of the spring is greatly shortened, thereby reducing the overall cost of materials by 10 to 20%.

Recently, a mobile communication terminal that requires a long stroke when slides has been released due to an increase in the vertical length of the device. When the dead center is implemented at the center line as shown in FIG.

Therefore, the dead point needs to be changed. As shown in FIG. 7, the dead point of the elastic body can be changed by setting the position B of the coupling part located in the longitudinal direction on the main body corresponding to the central rotation axis as a downwardly adjusted point. have. In this case, the overall length of the elastic body 34 may be increased.

If the dead point is changed, the long stroke can be realized even if the front part is moved with the same or less force as used in the conventional equipment, and the same slide type opening / closing module can be implemented without any additional components or structural changes. It can be applied to.

However, as described above, if the dead point is changed, the conventional spring module is rapidly reduced in durability due to the increased deformation, and thus it is impossible to apply to an actual product. The dead point change for implementing such a long stroke is according to the present invention. It is a function that only an elastic body of a material having superelastic properties can provide.

As shown in FIG. 8, the arcuate elastic body according to the present invention may be deformed to increase the number of strands or to include the bent portion as in the embodiments of (b) and (c), while maintaining the arcuate of (a) as a whole.

In the embodiment of (b), the elastic body 44 is composed of two strands, and in general, it is possible to form a smaller wire diameter than in the case of (a), which is a single strand while maintaining the arc-like bending as a whole. Since it is necessary to satisfy the required amount of elastic deformation, the range of superelastic alloy selection is expanded.

In addition, the bent portion 45 is distributed evenly along the arch shape, such a bend is more evenly distributed than the simple arch shape, the sliding is more evenly distributed and can be permanently deformed by the force that the center portion relatively concentrated when the elastic body is deformed Consider the point.

Therefore, it is advantageous to extend the life of the product by forming a bent portion of any number of strands elasticity, and the overall elastic deformation degree can be increased, thereby reducing the material cost.

(C) is a case where two or more bent parts 55 are provided in the four elastic body 54, and it is possible to form a wire diameter smaller than the case of (B).

Therefore, by adjusting the number of strands and bends according to the type of superelastic alloy material to maintain the amount of elastic deformation required in the present invention by the force, the elastic body is one of the main objects of the present invention to reduce the space occupied and moved by the elastic body Is formed of one strand is the best embodiment for the purpose, even if the number of strands is bound to follow the limit.

It is preferable that the elastic body of the present invention is subjected to mechanical polishing, electropolishing, shot peening, ultraviolet (UV) coating or teflon coating to enhance durability. .

In addition, synergistic effects may be achieved by applying the above treatment in combination, and after performing mechanical polishing, electropolishing or shot peening, an ultraviolet (UV) coating treatment or Teflon coating treatment is preferred.

The shot peening treatment is a cold forging method obtained by colliding a small spherical metal particle with a metal surface at a considerably high speed. The shot particle has an kinetic energy of E = 1/2 mV² and serves as a small HAMMER to form a metal surface. Instantly swipe and polish.

When the present invention is applied to a mobile communication terminal, the material cost per cell phone seems to be reduced by about 200 won, which is about 2 billion won when considering the production of 10 million units as of 2006. Moreover, considering the cost reduction in terms of durability and completeness of the product and the aspect of the market being further formed by the advantages of the device design, the economic effect obtained by applying the present invention is estimated to reach 4 billion won annually.

1 is an exemplary view of a conventional elastic body in which the turn of the elastic body is formed in the thickness direction

Figure 2 is an illustration of a conventional elastic body formed by turning the elastic body in the width direction

3 is a block diagram of the opening and closing module according to the present invention

Figure 4 is an illustration of the coupling of the opening and closing module according to the present invention

5 is an illustration of the coupling of the opening and closing module according to the present invention

6 is an operation example of the opening and closing module according to the present invention

7 is a view illustrating the operation after changing the dead point of the opening and closing module according to the present invention

8 is a modified embodiment of the elastic body according to the present invention

<Description of Major Reference Marks>

31: front part 32: main body part

33: guide portion 34, 44, 54: elastic body

       45, 55 bends

Claims (13)

A slide having a main body portion and a front portion coupled to allow sliding movement on the main body portion, wherein an elastic body is interposed between the main body portion and the front portion so that the front portion provides an elastic force to the slide movement on the main body portion. In the type opening and closing module, the elastic body is a super-elastic material, bent in a semicircular arc, both ends are coupled to the upper surface of the body portion and the lower surface of the front portion, the dead point of the elastic body can be changed according to the required stroke. Sliding opening and closing module, characterized in that the position of the end coupled to the upper surface of the main body portion can be changed to a point in the main body length direction. A slide having a main body portion and a front portion coupled to allow sliding movement on the main body portion, wherein an elastic body is interposed between the main body portion and the front portion so that the front portion provides an elastic force to the slide movement on the main body portion. In the opening and closing module, the elastic body is a super-elastic alloy material, bent in a semi-circular arc, both ends have a coupling portion that can be coupled to the upper surface of the body portion and the lower surface of the front portion, respectively, the coupling portion is the body portion And a structure that can correspond to the coupling portion on the front portion and is formed by insert injection molding when the elastic body is formed. A slide having a main body portion and a front portion coupled to allow sliding movement on the main body portion, wherein an elastic body is interposed between the main body portion and the front portion so that the front portion provides an elastic force to the slide movement on the main body portion. In the type opening and closing module, the elastic body is a superelastic alloy material, bent in a semicircular arc, both ends of the coupling portion on the body portion and the front portion so as to be coupled to the upper surface of the body portion and the lower surface of the front portion, respectively. Slide-type opening and closing module, characterized in that formed in a structure corresponding to the shape. The slide type opening and closing module according to any one of claims 1 to 3, wherein the elastic body has a deformation amount of 3 to 5% of the superelastic material having an elastic limit of about 8%. The slide type opening and closing module according to any one of claims 1 to 3, wherein the elastic body is a superelastic alloy exhibiting a superelastic effect without abnormal operation in a temperature range of -30 ° C to 100 ° C. 4. The sliding type opening and closing module according to claim 3, wherein the coupling part on the main body part and the front part is a through hole, and both ends of the elastic body are inserted into the through hole and bent. 4. The sliding type opening and closing module according to claim 3, wherein the coupling portion on the main body portion and the front portion is a rivet, and both ends of the elastic body are bent in the same plane to be coupled to the rivet. The method of claim 1, wherein the elastic body is mechanical polished, electro polished, shot peening, ultraviolet (UV) coated or teflon coated. Slide type opening and closing module, characterized in that the treated super-elastic alloy. The method according to claim 1, wherein the elastic body is UV coated or Teflon coated after mechanical polishing, electro polishing or shot peening. Slide type opening and closing module, characterized in that the treated super-elastic alloy. The sliding type opening and closing module according to any one of claims 1 to 3, wherein the elastic body is formed of one strand. The slide type opening and closing module according to any one of claims 1 to 3, wherein the elastic body is formed of 2 to 4 strands. The slide type opening and closing module according to any one of claims 1 to 3, wherein the elastic body has an arc shape having two or more bent portions. A mobile communication terminal equipped with a slide type opening and closing module according to any one of claims 1 to 3.

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