KR102425137B1 - Torsion type hinge spring - Google Patents

Abstract

According to the present invention, provided is a hinge spring, which is coupled to a main body and a sliding body, respectively, and presses the sliding body in one direction or the other direction based on a neutral position and includes: a housing in which a first housing and a second housing are coupled; torsion springs arranged in two rows inside the housing while facing each other along the width direction of the housing; and a body fastening unit provided at both ends of the torsion spring exposed from the housing and fastened to the main body and the sliding body, respectively, wherein the torsion springs arranged in two rows include a first torsion spring and a second torsion spring which are wound in different directions. Therefore, sufficient elastic force can be generated while being installed in a narrow space where the main body and the slide body face each other.

Description

Torsion Type Hinge Spring

The present invention relates to a hinge spring used for a hinge of a portable terminal, and to a torsion-type hinge spring that generates a strong elastic force while the torsion spring is torsionally deformed.

1 shows the operation of the bending type hinge spring described in Korean Patent Registration No. 10-0941589, which is a prior art document.

The portable terminal 100 may include a main body 110 and a sliding body 120 that slide each other. At this time, the hinge spring 1 is mounted so that the sliding body 120 is elastically biased with respect to the main body 110, and may be divided into a bending type, a compression type, and a torsion type.

Referring to Figure 1, when the two bodies go from the overlapping (a) state to the mutually unfolded (c) state through the reference sign (b), which is the neutral position, the hinge spring 1 is in the maximum bending state at the reference sign (b). becomes

When going from the reference sign (a) to the neutral position (b), the hinge spring 1 is bent and elastically resists the movement of the two bodies, and when going from the reference sign (b) to (a), the hinge spring 1 is bent. As this unfolds, an elastic force is applied in the direction in which the two bodies are moving away from each other.

The user can feel the semi-automatic sliding sensitivity due to the hinge spring 1 .

However, according to the conventional hinge spring 1 shown in FIG. 1, the elastic rod guide for supporting several elastic rods in the transverse direction and the housing for supporting the elastic rods in the longitudinal direction are made of a single body. Therefore, when the overall length of the hinge spring 1 needs to be changed according to the type of the portable terminal 100 , there is a problem in that a mold for injection molding of the housing structure must be individually manufactured. This is a concept that does not fit into the era of small batch production of various types of terminals such as Hyundai.

In addition, although suitable for a lightweight design, there is a problem in that the hinge spring cannot exert more than a certain level of elasticity because it is dependent on bending deformation.

Korean Patent Registration No. 10-0941589 (Announcement Date: February 11, 2010)

The present invention is to solve the above-described problem, and the supporting parts supporting the torsion spring are of the same standard, and only the number of turns or wire diameter of the torsion spring can be changed to adjust the elastic force of the entire hinge spring. On the other hand, since the torsion spring is used, sufficient elasticity can be exerted compared to the bending type.

The solution means of the present invention are coupled to the main body and the sliding body, respectively, and press the sliding body in one direction or the other based on the neutral position,

a housing to which the first housing and the second housing are coupled; Torsion springs arranged in two rows facing each other along the width direction of the housing inside the housing; body coupling parts provided at both ends of the torsion spring exposed from the housing and respectively coupled to the main body and the sliding body; including,

The torsion springs arranged in two rows may be provided with a hinge spring including a first torsion spring and a second torsion spring wound in different directions, respectively.

The torsion-type hinge spring of the present invention can generate sufficient elastic force while being installed in a narrow space where the main body and the slide body face each other.

By adjusting the characteristics of the torsion spring that is wound in a coil form from the central part toward the outer part, the elastic force of the entire hinge spring can be adjusted while using the same supporting parts. The overall elastic force can be adjusted by adjusting the elastic modulus of the torsion spring or the thickness of the wire while using it in common without changing the specifications of the supporting parts.

A support member is provided inside the housing, and the overall elastic force can be increased by providing torsion springs of a two-row structure having torsion springs on both sides of the support member, respectively, and the torsion spring along the sliding movement direction in which the torsion force acts Since the length of one side of the cross-section is longer than the length of the other orthogonal side, stronger elastic force can be exerted, and accordingly, the sliding body can be moved more conveniently from the main body when used in a portable terminal.

In addition, the first torsion spring and the second torsion spring provided on both sides of the support member are provided in two or more layers, respectively, to provide improved elasticity and increase the number of sliding operations when mounted on a portable terminal to extend the life of the product There are advantages to doing.

If the properties of the torsion spring change, maintaining the dimensions of the first housing and the second housing can standardize these components. There is no need to change the dimensions of the supporting parts according to the elastic force. Even if the torsion spring is changed, standard products can be used for the first housing and the second housing.

As a result, the elasticity of the hinge spring can be adjusted by changing only the torsion spring after designing and manufacturing the first housing and the second housing as standard products. The elastic properties can be adjusted by changing the elastic modulus and wire diameter of the torsion spring.

On the other hand, the fixing part for fixing the torsion spring to the housing can be simply secured by the protruding part of the housing. There is an advantage in that the means for fixing the torsion spring to the housing becomes very simple.

In addition, since the assembly of the housing and the sub-housing is carried out by hook coupling, there is an advantage in that assembly is simple and disassembly is easy.

Therefore, it is possible to adapt to the era of small-volume production of various types, and there is an advantage in that it is possible to mass-produce hinge springs of various characteristics without a cost increase factor.

1 is a perspective view illustrating a state in which a conventional bending-type hinge spring is operated in a state employed in a sliding portable terminal.
Figure 2 is a front-coupled perspective view of the torsion-type hinge spring of the present invention.
Figure 3 is a rear coupled perspective view of the torsion-type hinge spring of the present invention.
4 is an exploded perspective view of FIG. 2 ;
5 is a rear exploded perspective view of FIG. 4 .
6 is a perspective view of a first housing of the present invention.
7 is a perspective view of a second housing of the present invention.
8 is a front view showing a state in which the torsion spring is provided in the second housing of the present invention.
9 is a longitudinal cut-away perspective view of the hinge spring of the present invention.
10 is a longitudinal cross-sectional view of the hinge spring of the present invention.
11 is a cross-sectional explanatory view of the torsion spring of the present invention.
Fig. 12 (a) is an explanatory view of a cross-section of torsion springs arranged in two rows of the present invention, and (b) is an explanatory view showing a cross-section of one row in which the cross-sections of torsion springs arranged in two rows are combined.
13 is a plan view schematically illustrating a torsion spring arrangement structure according to another embodiment of the present invention.
14 is a schematic diagram showing an operating state of a portable terminal equipped with a torsion spring of the present invention.

Figure 2 is a front coupled perspective view of the torsion-type hinge spring of the present invention, Figure 3 is a rear coupled perspective view of the torsion-type hinge spring of the present invention, Figure 4 is an exploded perspective view of Figure 2, Figure 5 is a rear exploded perspective view of Figure 4.

1 to 5 , in the torsion-type hinge spring of the present invention, for example, both ends of the torsion spring are fastened to the main body and the sliding body of the portable terminal, respectively, and the sliding body is moved in one direction or the other based on the neutral position. It may be a torsion-type hinge spring that presses with

The housing may form the basic outline of a torsion-type hinge spring. The housing includes the first housing 100 , and the second housing 200 may be simply and detachably fastened to the first housing 100 .

A support member 300 having a torsion spring 400 on both side surfaces may be provided between the first housing 100 and the second housing 200 .

All the assembly of the hinge spring can be completed only with the first housing 100 and the second housing 200 having the shape of two plates and the support member 300 provided therebetween and formed in a plate type, so that mass production is possible. This can be dramatically improved.

The torsion springs 400 and 500 provided on both sides of the support member 300 may be provided with a pair of torsion springs 410, 420, 510, and 520 whose winding directions are opposite to each other on each surface of the support member 300. .

The torsion springs 400 and 500 may be twistably assembled to the support member 300 , and if only the characteristics of the torsion springs 410 , 420 , 510 and 520 are adjusted, the total elastic force of the hinge spring may be adjusted. In this case, the same component may be used for the first housing 100 and the second housing 200 . Therefore, there is an advantage that the entire elastic force can be adjusted by using standardized parts of the same standard.

A pair of torsion springs 410 , 420 , 510 , 520 provided on both sides of the support member 300 , respectively, may be received and supported by the inner surfaces of the first housing 100 and the second housing 200 , respectively, and thus, the second The first housing 100 and the second housing 200 may have an elliptical shape. Accordingly, an elastic force can be applied to two points spaced apart from each other according to the extension length of the ends of the torsion springs 410, 420, 510, and 520. Since a plurality of torsion springs 410, 420, 510, and 520 can be arranged and mounted, the magnitude of the total elastic force can be much larger than that of a bending-type hinge spring, and furthermore, the torsion springs 410, 420, 510, and 520 on both sides of the support member 300 ) are arranged in the same way, a stronger elastic force can be applied compared to one torsion spring.

Referring to FIG. 6 , first openings 110 , 210 and second openings 112 and 212 , which are openings, may be formed on both sides of the first housing 100 and the second housing 200 , where The ends or body coupling parts 600 of the torsion springs 410, 420, 510, and 520 may be exposed through, and as shown in FIG. 14, the first housing 100 and the second housing assembled according to torsional deformation ( 200) itself can be rotationally moved.

The first housing 100 or the second housing 200 may move in parallel with respect to an imaginary line segment that linearly connects the body coupling parts 600 provided at both ends of the torsion springs 410, 420, 510, and 520. Accordingly, it is possible to implement a hinge spring that draws a parallel movement trajectory in a state where the movement of the portable terminal is limited.

In the torsion-type hinge spring, if the area of the first housing 100 and the second housing 200 is increased, the number of windings of the torsion springs 410, 420, 510, and 520 can be increased or decreased in a wide range, so that the total elastic force is small to large. It can be manufactured in a wide range as standard products, and it can exhibit sufficient elasticity.

The torsion-type hinge spring of the present invention may include a first housing 100 , a second housing 200 , a support member 300 , and a body coupling part 600 , and the support member 300 has a second housing on both sides thereof. The first torsion springs 410 and 510 and the second torsion springs 420 and 520 may be seated therein. The body fastening part 600 includes ends of the first torsion springs 410 and 510 and the second torsion springs 420 and 520 exposed from both sides of the assembled first housing 100 and the second housing 200 . can be connected to

The body fastening part 600 is fastened to the main body and the sliding body of the portable terminal, respectively, and may be an action point at which an elastic force acts.

The first housing 100 and the second housing 200 may cover both sides of the support member 300 to prevent separation of the torsion springs 400 and 500 .

A pair of first torsion springs 410, 510 and second torsion springs 420 and 520 constituting the torsion springs 400 and 500 are wound in opposite directions and are provided on both sides of the support member 300, respectively. Accordingly, the first torsion springs 410 and 510 are wound in a forward direction, and the second torsion springs 420 and 520 are wound in a reverse direction opposite to the winding direction of the first torsion springs 410 and 510. Since it can be wound, a torsion spring can be implemented.

The center of each torsion spring 410, 420, 510, 520 is fixed inside the first housing 100 and the second housing 200, and the ends of each torsion spring 410, 420, 510, 520 are exposed in opposite directions. can of the first openings 110 and 210 and the second torsion springs 420 and 520 of the first housing 100 and the second housing 200 to which the ends of the first torsion springs 410 and 510 are exposed. The second openings 112 and 212 of the first housing 100 and the second housing 200, whose ends are exposed, may face opposite directions.

Therefore, referring to FIG. 8 , in order to produce a torsion effect by the ends of each torsion spring 410 , 420 , 510 , 520 , it may be desirable to wind each torsion spring 410 , 420 , 510 , 520 in the opposite direction.
In the hinge spring according to the present invention, the first torsion spring 410 and the second torsion spring 510 provided on one surface of the support member 300 and the first torsion spring 510 provided on the other surface of the support member 300 . The torsion spring 420 and the second torsion spring 520 may be arranged in the same structure, respectively.

Referring to FIG. 6 , the first housing 100 may include a first flat plate portion 120 , a first fixing portion 130 , and a first wall portion 140 , and the first fixing portion 130 may include a first It may have a structure protruding from the first flat plate part 120, and the first fixing part 130 is formed as a pair at intervals so that the central ends of the first torsion spring 410 and the second torsion spring 420 are fitted and fixed. may be formed, and the first wall portion 140 may be formed at each opposite edge of the first flat plate portion 120 to form a pair.

The central portion of the first torsion spring 410 may be sandwiched between the gaps of the first fixing part 140 having a predetermined length, thereby limiting torsional deformation and fixing the position. The central portion of the second torsion spring 420 is also sandwiched between the gaps of the other first fixing part 140 , so that torsional deformation is limited and the position can be fixed.

That is, two first fixing units 140 may be provided at intervals to support the central portion of the first torsion spring 410 and the central portion of the second torsion spring 420 to be fixed in position.

Referring to FIG. 7 , the second housing 200 may include, like the first housing 100 , a second flat plate part 220 , a second fixing part 230 , and a second wall part 240 , The second fixing part 230 may have a structure that protrudes from the second flat plate part 220 , and the second fixing part 230 has central ends of the first torsion spring 510 and the second torsion spring 520 . It may be formed as a pair at an interval so as to be fitted and fixed, and the second wall part 240 may be formed at each opposite edge of the second flat plate part 220 to form a pair.

The central portion of the first torsion spring 510 may be sandwiched between the gaps of the second fixing part 230 having a predetermined length, thereby limiting torsional deformation and fixing the position. The central portion of the second torsion spring 520 is also sandwiched between the gaps of the other first fixing part 230 , so that torsional deformation is limited and the position can be fixed.

The first wall portion 140 may protrude together with the second wall portion 240 to couple the first housing 100 and the second housing 200 . The first wall portion 140 and the second wall portion 240 may protrude to prevent separation of the torsion springs 410 and 420 , 510 and 520 . The coupling of the first wall portion 140 and the second wall portion 240 may restrict the outer portions of the torsion springs 410 , 420 , 510 , and 520 not to deviate far from the first housing 100 and the second housing 200 . .

In order to improve productivity, it may be preferable to manufacture the first housing 100 and the second housing 200 by injection molding or press molding. To this end, it may be preferable that the first housing 100 and the second housing 200 have flat portions 120 and 220, wall portions 140 and 240 and fixing portions 130 and 230 protruding therefrom, respectively. Each of the wall parts 140 and 240 and the fixing parts 130 and 230 protrude toward each other, and it may be preferable that the first housing 100 and the second housing 200 are fastened by their mutual fastening.

A plurality of hook protrusions 142 may be formed on the first wall portion 140 provided on the upper and lower portions of the first flat portion 120 constituting the first housing 100 .

A plurality of hook protrusions 142 of the plurality of first housings 100 are inserted into the second wall portions 240 provided on the upper and lower portions of the second flat portion 220 constituting the second housing 200 to be hooked. of the locking hole 242 may be formed.

9 and 10 , when the first housing 100 and the second housing 200 are assembled so that the support member 300 is embedded, the first wall portion 140 of the first housing 100 is formed by the second It may be inserted inside the second wall portion 240 of the housing 200 . Accordingly, the plurality of hook protrusions 142 formed on the first wall portion 140 may be inserted into the plurality of locking holes 242 formed on the second wall portion 240 to be engaged.

The present invention is not limited to the structure of the first wall portion 140 and the second wall portion 240 . In order to increase the coupling force between the first wall portion 140 and the second wall portion 240 , an auxiliary protrusion 244 may be formed on an end side of the second wall portion 240 as shown in FIG. 7 . Since the auxiliary protrusion 244 may be wrapped while elastically supporting the first housing 100, coupling force may be increased.

Meanwhile, in order to improve the mass productivity of the first fixing part 130 and the second fixing part 230 , a mold extraction hole may be provided during injection molding. Since the protrusion extends in a direction perpendicular to the flat plate portions 120 and 220 , the separation direction between the upper mold and the lower mold may be perpendicular to the flat plate portions 120 and 220 . Accordingly, it is possible to suppress fatigue fracture by forming a round treatment, chamfering treatment, or a soft curved portion at the point where the first fixing portion 130 and the second fixing portion 230 and the flat plate portions 120 and 220 meet. To this end, the peripheral portion of the first fixing portion 130 of the first flat portion 120 of the first housing 100 or the second fixing portion 230 of the second flat portion 220 of the second housing 200 . A mold extraction hole may be formed in the peripheral portion of the . The first fixing part 130 and the second fixing part 230 around the mold extraction hole may form a curved part and remove a right angle surface, thereby strengthening the ability to respond to fatigue failure.

When the fixing parts 130 and 230 are formed by taking the first flat plate part 120 using a press mold without being limited to injection molding, the flat plate parts 120 and 220 are cut using the mold extraction hole, and the cut flat plate part ( The fixing parts 130 and 230 may be formed by bending 120 and 220 . Even at this time, the mold extraction hole may be formed.

A first coupling hole 122 that is a plurality of coupling holes is formed in the first flat plate part 120 of the first housing 100 , and a plurality of coupling holes are formed in the second flat plate part 220 of the second housing 200 . Two coupling holes 222 may be formed, and the first coupling holes coupled to the first coupling holes 122 and the second coupling holes 222 are formed on both sides of the support member 300 provided with the torsion springs 400 and 500 , respectively. A protrusion 310 and a second coupling protrusion 320 may be formed.

The first coupling protrusion 310 and the second coupling protrusion 320 may each have a double protrusion structure. That is, the first coupling protrusion 310 and the second coupling protrusion 320 are the support pieces 312 and 322, respectively, and the coupling pieces 314 with a small diameter protruding from the ends of the support pieces 312 and 322. (324). In other words, the support pieces 312 and 322 may each have a space maintaining function such that the first housing 100 and the second housing 200 are maintained at a predetermined distance from the support member 300 , respectively.

Accordingly, the first housing 100 and the second housing 200 are coupled by the first wall portion 140 and the second wall portion 240 , and a first coupling formed on both sides of the support member 300 positioned inside. The coupling holes 122 and 222 of the first flat plate part 120 of the first housing 100 and the second flat plate part 220 of the second housing 200 through the protrusion 310 and the second coupling protrusion 320, respectively. It can be coupled to and fixed. The first coupling protrusion 310 and the second coupling protrusion 320 are protrusions of a double structure having different diameters, respectively, and the support pieces 312 and 322 having relatively large diameters include the first housing 100 and the second coupling protrusion. Each of the coupling holes 122 and 222 of the housing 200 are supported to face each other, and the coupling pieces 314 and 324 may be inserted into the coupling holes 122 and 222 to maintain a coupled state. Therefore, it is possible to maintain a more rigid assembly state.

The protrusion height of the support pieces 312 and 322 may be a height at which a space for accommodating the torsion springs 400 and 500 is secured when the first housing 100 and the second housing 200 are assembled. Accordingly, the internal space created by assembling the first housing 100 and the second housing 200 may be more reliably maintained.

Here, the torsion spring of the present invention may include torsion springs 400 and 500 disposed on both sides of the support member 300 inside the housing. That is, by having a structure in which the torsion springs are arranged in two rows along the width direction of the housing, a higher elastic force may be provided.

Referring to FIG. 11 , the torsion springs 400 and 500 of the present invention may form a quadrangle in cross-section, and when a first length (b) in a horizontal direction and a second length (h) in a vertical direction are given in the drawing, the second moment of cross-section is (I) can be expressed as in Equation 1 below.

For example, in the case of a first cross-section with b = 1 mm and h = 2 mm, and a second cross-section with b = 2 mm and h = 1 mm, the second cross-sectional moment (I) of the first cross-section is 1×2 ³ / 12 = 8/12, the second cross-sectional moment of the second cross-section is 2×1 ³ /12 = 2/12, so naturally, when the second length h is larger than the first length b, the cross-section second It can be seen that the moment increases. Since the second length (h) of the cross-section is proportional to the cube of the second length (h), the second length (h) may increase as the second length (h) increases compared to the first length (b). An increase in the cross-sectional second moment value may mean an increase in the bending force of the member.

On the other hand, referring to FIG. 12 , the torsion springs 400 and 500 of the present invention are a first cross-section 402 and a second cross-section 502 having the same cross-sectional size, and two torsion springs 400 and 500 having the same cross-section. , and the cross-sectional second moment (I1) can be obtained by the following Equation (2).

On the other hand, assuming that the torsion springs 400 and 500 have the same size of the area of the first cross-section 402 and the second cross-section 502 having the same size, the cross-sectional second moment I2 is calculated by the following equation 3 can be expressed as

Accordingly, the cross-sectional secondary moment I1 by the two torsion spring cross-sections may be greater than the cross-sectional secondary moment I2 value of the torsion spring having one combined cross-section.

By substituting the numbers, the calculation is as follows.

For example, when the first length (b) of the torsion spring 400,500 is 1 mm and the second length (h) is 2 mm, I1=(2×(1mm×2mm ³ ))/12=16/12mm ⁴ , and I2=(2×1mm×2mm ³ ))/12=16/12mm ⁴ is calculated, and accordingly, the secondary sectional moment value (I1) of the two torsion springs 400,500 and one It can be seen that the cross-sectional second moment (I2) of the torsion spring becomes the same.

However, since the torsion springs 400 and 500 of the present invention are provided on both sides of the support member 300 and are prepared by winding a plurality of times, the number of windings should be multiplied.

Therefore, assuming that the number of turns of each of the two divided torsion springs 400,500 is 5, the cross-sectional secondary moment I1 of the two divided torsion springs 400,500 should be multiplied by 10 times, 5 times each, Since the cross-sectional secondary moment I2 of the torsion spring having one combined cross-section needs to be multiplied only by five times, the elastic force of the two torsion springs 400 and 500 of the present invention is higher than the elastic force of the torsion spring having one combined cross-sectional area. can be doubled.

According to this principle, the torsion springs 400 and 500 of the present invention have a second length (h) parallel to the direction in which the torsion force acts is longer than the first length (b) in the direction perpendicular to the direction in which the bending force acts, so that the cross section It can have a large secondary moment, and, moreover, in the case of providing two torsion springs 400 and 500 having cross-sections of the same size, the number of turns is doubled compared to the case of providing one torsion spring having the area of the two cross-sections combined. Therefore, the two torsion springs 400 and 500 may have an increased elastic force compared to one torsion spring due to the increased cross-sectional secondary moment.

In addition, as shown in FIG. 13 , the present invention may have a structure in which torsion springs 400 and 500 provided on both sides of the support member 300 are provided in two or more layers, respectively, as another embodiment. In this case, it may be formed by adjusting the protrusion lengths of the fixing portions of the first housing 100 and the second housing 200 according to the thickness of the plurality of torsion springs 400 and 500 . In addition, the plurality of torsion springs 400 and 500 provided on both sides of the support member 300 may be formed and arranged to have the same size (the length in the width direction and the length in the orthogonal direction of the housing).

When the first torsion springs 410, 510 and the second torsion springs 420 and 520 provided on each side of the support member 300 are provided in two or more layers, respectively, it is more improved when mounted on a portable terminal. There is an advantage in that elasticity can be exerted and the number of repetitions of the sliding motion can be increased.

Referring to FIG. 14 , it is a view showing a torsion-type hinge spring mounted on a portable terminal, and it can be seen that the torsion operation of the hinge spring is implemented by sliding the sliding body S from the main body M.

100... first housing 110,210... first opening
112,212... Second opening 120... First flat plate part
122... First coupling hole 130... First fixing part
140... First wall part 142... Hook projection
200... Second housing 220... Second flat plate
222... second coupling hole 230... second fixing part
240... 2nd wall part 242... Hanging hole
244... auxiliary protrusion 300... support member
310... first engaging protrusion 320... second engaging protrusion
312,322... support piece 314,324... join piece
400,500... torsion spring 410,510... first torsion spring
420,520... 2nd torsion spring 600... Body fastening part
M... Main body S... Sliding body

Claims (9)

It is coupled to the main body and the sliding body, respectively, and presses the sliding body in one direction or the other based on the neutral position,
a housing to which the first housing and the second housing are coupled;
Torsion springs arranged in two rows facing each other along the width direction of the housing inside the housing;
body coupling parts provided at both ends of the torsion spring exposed from the housing and respectively coupled to the main body and the sliding body; including,
The torsion springs arranged in two rows consist of a first torsion spring and a second torsion spring wound in different directions, respectively,
A support member for arranging the torsion springs in two rows is provided inside the housing,
A first torsion spring and a second torsion spring constituting the torsion spring are respectively wound on both sides of the support member with a predetermined number of windings and are provided,
The first torsion spring and the second torsion spring provided on one side of the support member and the first torsion spring and the second torsion spring provided on the other side of the support member are respectively arranged in the same structure.
delete The method of claim 1,
A hinge spring for adjusting the elastic force of the torsion spring provided by adjusting the number of turns of the first torsion spring and the second torsion spring.
The method of claim 1,
The first housing and the second housing,
Flat parts for supporting torsion springs respectively provided on both sides of the support member,
Hinge spring including a fixing part to which the centers of the first torsion spring and the second torsion spring constituting the torsion spring are coupled and fixed
5. The method of claim 4,
The fixing portion of the first housing and the second housing,
A hinge spring formed to protrude toward both sides of the support member at a plurality of intervals so that the centers of the first torsion spring and the second torsion spring are fitted.
The method of claim 1,
The first housing and the second housing include a flat plate portion supporting the torsion spring, and at least one coupling hole formed in the flat plate portion,
A hinge spring having coupling protrusions coupled to the coupling holes protrude from both sides of the support member.
7. The method of claim 6,
The bonding protrusion is a double structure,
A hinge spring comprising a support piece for supporting the flat portion of the first housing and the second housing so as to maintain a distance therebetween, and a fitting piece smaller than the diameter of the support piece and fitted into the fitting hole formed in the flat portion.
The method of claim 1,
The cross section of the torsion spring is a rectangular cross section, and when defining the lengths of sides in mutually orthogonal directions constituting the rectangular cross section as a first length and a second length, respectively,
The second length in the direction in which the bending force acts is a hinge spring having a rectangular cross section formed to be larger than the first length.
The method of claim 1,
The first torsion spring and the second torsion spring provided on each side of the support member are each provided in two or more hinge springs.

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