WO2005106569A1 - Spectacles - Google Patents

Abstract

Spectacles (1) enabling the restriction of the positions of temples by a simple structure. The spectacles comprise the temples (3) each of which is formed of two arms (3a) and (3b) on the front side and hinges (5) each two of which connect the two arms (3a) and (3b) arranged at the upper and lower positions to each other by using a rotating axis bisecting a horizontal angle between the positions of the temples (3) in an expanded state (i) and a stored state (iv). Each of the temples (3) is rotated between the expanded state (i) and the stored state (iv) about the rotating axis while facing the inner surface side thereof toward the rotating axis. A difference in strength is provided to the two arms (3a) and (3b) of each of the temples (3).

Description

 Specification

 Glasses

 Technical field

 The present invention relates to spectacles, and more particularly, to a technique relating to temple connection.

 Background art

 [0002] The temples of the glasses are rotatably provided via hinges, and when the glasses are stored in the case, the temples can be folded to be stored.

[0003] Recently, as a temple folding structure, as shown in Patent Document 1, the temple draws a conical rotating surface around a rotation axis that bisects the horizontal angle between the unfolded state and the stored state of the temple. A rotating type has also appeared.

[0004] In the structure of Patent Document 1, the restoring force of the temple itself is used as an urging force.

, Was able to restrain the temple.

 Patent Document 1: Japanese Patent Application Laid-Open No. 2003-322828

 Disclosure of the invention

 Problems to be solved by the invention

[0005] However, the structure of Patent Document 1 does not limit the rotation range when changing from the unfolded state to the stored state, and turns the temple upward to draw a semicircle and rotate the temple. It was possible to freely rotate to draw a semicircle by turning it downward. For this reason, some users may feel uncomfortable.

[0006] Further, in the structure of Patent Document 1, positioning is performed only by the restoring force of the temple, and the temple position cannot be fixed in the unfolded state when violently moving or receiving any impact. Has caused a positional shift, which has caused the glasses to shift or fall off.

[0007] The present invention has been made in view of the above circumstances, and an object of the present invention is to provide eyeglasses capable of regulating a temple position with a simple structure.

 Means for solving the problem

[0008] In order to achieve the above object, the present invention employs the following configuration.

[0009] That is, a temple having two arms on the front side, A hinge that bisects the horizontal angle between the respective temple positions in the unfolded state and the stowed state, and that connects the two arms individually one above the other using a pivot axis located in the middle;

 Has,

 Eyeglasses in which the temple rotates between a deployed state and a stored state with the temple facing its inner surface side toward the rotation axis about the rotation axis,

 A pair of glasses having a difference in strength between two arms of the temple.

[0010] Also, a front having a front curve,

 The front has two arms, a temple that forms a curve that is continuous with the front when deployed,

 On the back of the front, the two arms are individually arranged vertically and connected by using a rotation axis located at an intermediate position which bisects the horizontal angle between the respective temple positions in the unfolded state and the stored state. Hinges,

 Has,

 The temple rotates between the unfolded state and the stored state around the rotation axis while directing the concave curve on the inner surface side toward the rotation axis. A pair of eyeglasses that form a curve overlapping the front curve, and the eyeglasses are arcuate;

 A strength difference is provided between the two arms of the temple, and the stronger arm of the two arms of the temple bears the frame rigidity of the glasses, and the weaker arm deforms radially during rotation to reduce the restoring force. It is glasses that are characterized by exerting.

 The invention's effect

 According to the present invention, the restoring force of the temple itself can be used as a biasing force on the temple, and the rotation position of the temple can be restricted by the temple to restrict the temple position.

 Brief Description of Drawings

 FIG. 1 is a top view of the glasses according to the first embodiment as viewed from above.

FIG. 2 shows the eyeglasses according to the first embodiment in an angular force parallel to the rotation axis of the temple. It is a perspective view.

 FIG. 3 is a perspective view showing a stored state of the glasses according to the first embodiment.

FIG. 4 is a view schematically showing the operation of the temple of the spectacles according to the first embodiment.

FIG. 5 is a diagram schematically showing an operation around a front hinge of the glasses according to the first embodiment, where (a) is in an expanded state and (b) is in a rotated state. , (C) is in the stored state.

 FIG. 6 is a diagram showing a configuration of a hinge of the eyeglasses according to the first embodiment, (a) is a cross-sectional view, and (b) is a perspective view.

 FIG. 7 is a perspective view showing spectacles according to a second embodiment in an angular force parallel to a rotation axis of a temple.

 FIG. 8 is a plan view showing another example of eyeglasses according to the second embodiment, focusing on temples.

 FIG. 9 is a plan view showing another example of eyeglasses according to the second embodiment, focusing on temples.

Explanation of symbols

1 glasses

2 Lens

3 Tempnore

3a Upper arm

3b Lower arm

3b 1 Bevel

3c modern

4 Front

4a Upper end

4b Lower edge

5 hinge

6 Fixing piece

30 Temple tip 40 washers

 50 Connecting pin

 60 Shaft hole

 70 screws

 A pivot point

 B Rotation fulcrum

 C regulatory point

 D Midpoint

 BEST MODE FOR CARRYING OUT THE INVENTION

 (First Embodiment)

 In this specification, directions such as front, rear, up, down, vertical, horizontal, horizontal, and vertical are used based on the orientation of the glasses when the glasses are worn in a standing position.

 [0015] In the present specification, the "deployed state" refers to a state that the temple should take when the spectacles are worn, and refers to a state in which the temple forms a horizontal angle of about 90 ° with respect to the front of the spectacles. The “storage state” refers to a state in which the temple is folded when the glasses are not used, such as when the glasses are stored in a case, a state in which the front of the glasses and the temple substantially overlap with each other.

 [0016] In this specification, "front side member" refers to a member of the front part of the spectacles, which is connected to the temple via a hinge, and includes, for example, a rim "mayu". “Toshi” provided on an eyeglass frame member such as a blow bar, a lens, a filter, or the like corresponds to this. In the case of a structure in which a temple is directly connected to a lens or a filter, it corresponds to the “lens” or “filter” force S front side member.

 First, an overall configuration of the glasses according to the first embodiment of the present invention will be described with reference to FIGS.

FIG. 1 is a top view of the glasses viewed from substantially above. FIG. 2 is a perspective view showing FIG. 1 also showing an angular force parallel to the rotation axis of the temple. In the figure, (i) shows the temple in the unfolded state, (ii) and (m) shows the temple in the rotating state, and (iv) shows the temple in the stowed state. Is shown. FIG. 3 is a perspective view showing that the glasses are in an arcuate shape with both temples stored. As shown in these figures, the spectacles 1 of the present embodiment include lenses 2 and 2, temples 3 and 3 provided respectively on the left and right of the spectacles, and front-side members to which the temples 3 are connected. Front 4 and hinges 5 and 5 for rotatably connecting the temple 3 to the front 4. In the present embodiment, a spectacle frame having a structure in which the lens 2 is held by the metal front 4 is configured.

 The temple 3 has a front side connected to the front 4 branched into two arms 3a and 3b. The temple 3 includes an upper arm 3a disposed on the upper side and a lower arm 3b disposed on the lower side. Have.

 The upper arm 3a and the lower arm 3b are provided with a difference in strength. The upper arm 3a bears the rigidity of the frame of the spectacles 1, which has high strength, and is hardly deformed. The lower arm 3b is weak in strength and has an appropriate flexibility, and exhibits a restoring force by being deformed radially during rotation. The radius deformation of the lower arm 3b is a direction in which the curve of the lower arm 3b is further curved. After the deformation, the curve is returned to the original curve by the restoring force.

 [0022] The upper arm 3a and the lower arm 3b are connected on the rear side (the temple end side), and relative movement in the forward and rearward directions is restricted to each other. In Temple 3, the rear side where the upper arm 3a and the lower arm 3b are connected is a single modern 3c.

 [0023] Further, the respective ends of the upper arm 3a and the lower arm 3b reach the hinge 5, and are connected to the front 4 by the hinge 5 so as to be individually rotatable.

 As shown by the broken line in FIG. 1, the rotation axis of each of the upper arm 3a and the lower arm 3b is between the unfolded state (the position of the temple 3 of 0 and the position of the temple 3 of the stored state (iv)). The upper arm 3a and the lower arm 3b are individually connected to each other, so that their rotation axes are arranged substantially vertically in parallel with each other. .

 [0025] In such a configuration, when a force in the turning direction is applied to the temple 3 in the unfolded state (i), while the upper arm 3a and the lower arm 3b are individually turned, the temple 3 remains as a whole. Then, it turns (ii) → (iii) while turning the concave curve on the inner surface side toward the rotation axis, and reaches the storage state (iv) when it turns about 180 °.

[0026] Since the tips of the upper arm 3a and the lower arm 3b are individually connected, the lower arm 3b slightly deforms and intersects the upper arm 3a in the vicinity of the storage state (iv). Become. Note that the rotation range is restricted to the downward rotation in the figure, and it is not possible to rotate the same upward. The temple 3 has a shape in which the outer surface is convex and the inner surface is concave so as to bulge outward in accordance with the shape of the temporal region of the spectacle user. On the other hand, the front 4 of the spectacles 1 also has a front curve that bulges outward so as to conform to the shape of the front face of the spectacle user's face. Therefore, as described above, in the configuration in which Temple 3 rotates while turning the concave curve on the inner surface side toward the rotation axis, in the unfolded state (i) and the stored state (iv), the curve of Temple 3 and the front curve of Front 4 are different. The directions are aligned. In the unfolded state (i), the temple 3 curves continuously from the front 4 of the glasses 1. In addition, the glasses 1 in the housed state (iv) are extremely compact, as shown in FIG.

 [0028] The eyeglasses 1 of the present embodiment exhibit the following characteristic functions and functions based on the above configuration.

 FIG. 4 is a diagram schematically showing the operation of the temple 3 of the glasses 1 of the present embodiment. In FIG. 4, for simplicity of description, only two arms 3a and 3b are shown, and a temple 3 in which the upper arm 3a and the lower arm 3b are symmetrical is used. Here, the curves that the arms 3a and 3b have in their natural state are eliminated, and only the curved portions are drawn with the curves.

 As shown in FIG. 4, the front side of the temple 3 of the present embodiment includes an upper arm 3a and a lower arm 3b. The tip of the upper arm 3a is connected rotatably about a rotation fulcrum A, and the tip of the lower arm 3b is connected rotatably about a rotation fulcrum B. Further, the rear end of the upper arm 3a and the rear end of the lower arm 3b are connected at a restriction point C, and relative movement in the extending direction is restricted to each other.

 [0031] According to this configuration, when the temple 3 is rotated, the distal ends of the upper arm 3a and the lower arm 3b try to rotate so as to draw different rotation trajectories due to the constraint on the hinge 5. You. On the other hand, at the rear ends of the upper arm 3a and the lower arm 3b, a force acts on the relative movement of the arms 3a and 3b in the extending direction.

[0032] As a result of opposing forces acting on the distal end side and the rear end side of the upper arm 3a and the lower arm 3b, the strength of the upper arm 3a is strong and the upper arm 3a is not deformed. A radius deformation occurs in the arm 3b, which bends the curve that is in the natural state further deeply. That is, the temple 3 is rotated by the lower arm 3b performing its own radius deformation and the position change of the rotation fulcrum B with respect to the rotation locus of the upper arm 3a. The restoring force of the lower arm 3b for radial deformation acts in the direction of a straight line (shown by a broken line) connecting the rotation fulcrum B and the regulation point C. In this restoring force, a direction parallel to a plane orthogonal to a straight line (virtual center line of temple 3; shown by a dashed line) connecting the midpoint D of the rotation fulcrums A and B and the regulation point C. This component acts as a force for rotating the temple 3 spontaneously (rotational component force).

 Hereinafter, the turning operation of the temple 3 from the deployed state (i) to the stored state (iv) will be described in order.

[0035] In the deployed state (i), the lower arm 3b does not deform radially and no restoring force is generated, so that the rotational component is zero.

 The unfolded state (i) When the force temple 3 is turned counterclockwise (downward), the distance between the regulation point C and the lower turning fulcrum B becomes closer, and thus the state shown in the state (ii) As a result, the lower arm 3b is deformed radially, and the pivot point B moves so as to move away from the control point C force. At this time, the restoring force of the lower arm 3b acts in a linear direction connecting the rotation fulcrum B and the regulation point C, as indicated by the black arrow. Then, the rotation component acts in the direction of returning the temple 3 to the deployed state (to 0), as shown by the outline arrow.

 [0037] Therefore, the rotation component causes the temple 3 to rotate toward the unfolded state (i) in the vicinity of the unfolded state (i) (a range of less than 90 ° around the unfolded state (i)). Acts in the direction.

 [0038] Although not shown, in the unfolded state (i), when the temple 3 is rotated clockwise, the upper arm 3a does not deform with high strength and the lower arm 3b is bent. Since it cannot be extended even if it can be pulled, it cannot be rotated clockwise, the rotation range is restricted, and the temple 3 is restricted to the deployed state (i).

 When the temple 3 is rotated downward from the unfolded state (i) to a position of 90 °, the direction of action of the restoring force overlaps (is parallel to) the virtual center line of the temple 3 and is thus rotated. Component force is the key.

When the temple 3 is further rotated beyond this state, an angle is created between the acting direction of the restoring force and the imaginary center line of the temple 3 as shown in a state (m). Component force acts. However, since the sign of the angle is reversed from that in the state (ii), the acting direction of the rotational component is reversed. In other words, a rotating component force acts in the direction to propel the rotation of Temple 3. [0041] Then, when the temple 3 is in the deployed state (i) when the force is also substantially rotated by 180 °, even if the upper arm 3a does not bend with strong strength and the lower arm 3b can bend, Since it cannot be extended, the rotation range is limited so that the temple 3 does not rotate any further even when a rotation component of the lower arm 3b is generated. That is, in this state, although the component of the restoring force of the lower arm 3b acting in the direction of rotating the temple 3 is generated in the lower arm 3b, further rotation is restricted. The position of temple 3 calms down. This state is the stored state (iv).

 Here, when the temple 3 is rotated clockwise in the retracted state (iv), the force is returned in the direction of returning the temple 3 to the retracted state (iv) by the pivotal component of the lower arm 3b. work.

 [0043] Therefore, the rotation component force rotates the temple 3 toward the storage state (iv) in the vicinity of the storage state (iv) (in a range of approximately less than 90 ° around the storage state (iv)). Acts in the direction.

 In this way, as shown in FIG. 4, the rotation of the temple 3 moves the temple 3 downward so that the lower arm 3b having low strength can be deformed radially between the deployed state and the stored state. Turn 3 is restricted to the area where the lower half of the circle is drawn. Therefore, the user can use it satisfactorily without feeling uncomfortable. In addition, even in the case of intense exercise or any impact, the rotation of Temple 3 in the unfolded state (i) is limited and the position of Temple 3 can be fixed firmly, preventing the glasses 1 from slipping or falling off. it can.

 The component of the restoring force acting in the direction of rotating the temple 3 is directed to the direction of rotating the temple 3 to the deployed state (i) in the vicinity of the deployed state (i), and the stored state (iv ) In the vicinity, it faces the direction to rotate the temple 3 to the stowed state (iv). Therefore, the temple 3 itself can be restrained by using the restoring force of the temple 3 itself as an urging force.

 As described above, according to the configuration of the present embodiment, the rotation range is regulated by the difference in strength between the arms 3a and 3b, and the arms 3a and 3b are stabilized in the deployed state (i) and the stored state (iv). Then, the temple 3 in the rotating state is rotated by the restoring force of the lower arm 3b toward the deployed state (i) and the stowed state (iv).

[0047] Therefore, the unfolding operation and the storing operation of the temple 3 can be easily performed, and the position of the temple 3 in the unfolded state (0 and the stored state (iv) is regulated, and the rotation of the temple 3 is stopped. This makes it possible to improve handling and stability.

 [0048] Further, since these effects are exerted by the difference in strength between the arms 3a and 3b of the temple 3, the radius and the restoring force, it is not necessary to add a detent component, a panel component and other components. The structure can be simplified, the number of parts can be reduced, design can be simplified, and costs can be reduced.

 Here, in order to make the rotation of the temple 3 smoother, the lateral side of the front 4 is vertically moved between the rotation fulcrum A and the rotation fulcrum B as shown in FIG. It is divided and a pivot point A is provided at the upper end, and a pivot point B is provided at the lower end. As a result, as shown in FIG. 4, the amount of change in the position of the rotation fulcrum B, which cannot be cut due to the radial deformation of the lower arm 3b, is reduced by the upper end 4a and the lower end. The relative position of the portion 4b is absorbed by shifting it back and forth.

 [0050] Specifically, as shown in Figs. 5 (a) and 5 (c), the unfolded state (i) and the stowed state (in that case, the upper side of the front 4 where the amount of radial deformation of the lower arm 3b is small) The front and rear ends of the lower and upper ends are approximately the same, however, as shown in Fig. 5 (b), in the case of state (ii) or state (iii), the radius of the lower arm 3b is reduced. Since the amount of deformation increases, the lower end 4b having the fulcrum B is shifted forward from the upper end 4a, so that the fulcrum B is displaced and the amount of radial deformation is reduced. Smooth rotation of Temple 3!

 [0051] The configuration in which the lateral side of the front 4 shown in Fig. 5 is vertically divided is merely a configuration for realizing the smooth rotation of the temple 3, and the amount of radial deformation of the lower arm 3b is reduced. The front 4 that makes the pivot point B fixed together with the pivot point A by increasing the diameter of the pivot 4 is divided!

 Next, the hinge 5 of the temple 3 will be described in detail with reference to FIG.

 FIG. 6 (a) is a cross-sectional top view showing the hinge 5 of the temple 3 in an enlarged manner, and shows a connecting portion by a cross section. FIG. 6B is an enlarged perspective view of the hinge 5 of the temple 3.

As shown in FIG. 6, two hinges 5 are provided vertically apart so as to connect the two arms 3a and 3b, respectively. The fixing piece 6 fixed to the front 4 is provided with a shaft hole 60 for supporting the temple 3. 135 ° water at the side edge of front 4 Because of the flat angle, the axis of the shaft hole 60 is arranged at an inclination of approximately 45 ° with respect to the front surface of the spectacles 1 (note that the front surface is an imaginary line perpendicular to the front and rear lines of the spectacles 1). Plane). The axis directions of the two hinges 5, 5 are substantially parallel to each other.

 [0055] On the other hand, the upper arm 3a and the lower arm 3b of the temple 3 are vertically separated away from each other so that the front side becomes substantially the same width as the separation width of the shaft holes 60, 60 so that the hinges 5 and 5 are formed. Has reached. Further, the temple 3 has a curve in a natural state, and has a shape such that the direction of the temple tip 30 is exactly overlapped with the axis of the shaft hole 60 when the temple 3 is in the unfolded state.

 In the present embodiment, the temple 3 is attached to the fixed piece 6 using the connecting pin 50. The connecting pin 50 is a metal rod-shaped member, and has a head part having a diameter sufficiently larger than the shaft hole 60, a body part having a diameter slightly smaller than the shaft hole 60, and a through hole having a diameter slightly larger than the shaft hole 60. Consists of a stop.

 At the time of attachment, first, the connecting pin 50 is inserted into the shaft hole 60, the hole at the temple tip 30, and the washer 40. Thereafter, a retaining portion for the connecting pin 50 is formed, and the retaining portion is barred to prevent the connecting pin 50 from coming off. As a result, the hinge 5 is formed.

 Next, the fixing piece 6 is fixed to the upper end 4a and the lower end 4b of the front 4 by screws 70. Although not shown, a concave portion is formed on the back surface of the front 4 in the shape of the fixing piece 6, and the fixing piece 6 is fitted into this concave portion and screwed.

 [0059] With such a hinge 5, the tips of the upper arm 3a and the lower arm 3b of the temple 3 are individually and rotatably connected to the front 4 respectively. At this time, the rotation axis of the temple 3 is located at an intermediate position between the horizontal position of the temple 3 in the unfolded state (i) and the horizontal position of the temple 3 in the stored state (iv). In other words, it is inclined at an angle of 45 ° from the front and is almost horizontal.

 [0060] The hinge 5 for rotatably connecting the temple 3 is not limited to the one exemplified here, and various modifications are possible.

[0061] Further, the configuration of the temple 3 is not limited to the example illustrated here, and various modifications are possible. As long as there are two arms 3a and 3b on the front side, it may be connected to the temple end side (rear side) to the end.

[0062] Further, the member connecting the temple 3 via the hinge 5 may be configured to be connected to a front-side member such as a general lens, filter, and the like that can be connected only with the front 4. (Second Embodiment)

 According to the configuration of the first embodiment, the temple 3 is regulated so as to rotate the temple 3 downward in a range where a lower half semicircle is drawn. However, the user may force the operation of turning the template 3 upward from the unfolded state (i), and the glasses 1 may be damaged. Therefore, in the present embodiment, a configuration is provided in which the rotation preventing member is provided to completely prevent the temple 3 from being turned upward in the deployed state (i).

 In the glasses 1 shown in FIG. 7, a pin 7 is provided on the hinge 5 for the upper arm 3a at the upper end 4a of the front 4, as having a function of preventing rotation. In this configuration, when the temple 3 is deployed, (i) when the force is also turned upward, the upper arm 3a hits the pin 7 and hinders the rotation of the upper arm 3a. Is made. The shape and the like of the protruding portion are not limited as long as the protruding portion protrudes such that the upper arm 3a hitting only with the pin 7 hits and the rotation is hindered.

 In the glasses 1 shown in FIGS. 8 and 9, the upper arm 3a is arranged inside with a large width, and the lower arm 3b is arranged so as to be thin and overlap with the outside of the upper arm 3a. . That is, in the spectacles 1 shown in FIGS. 8 and 9, the arrangement of the arms 3a and 3b is actually superimposed on the inside and outside instead of being distributed vertically. However, in order to facilitate the description in the present embodiment, description will be made using the same names as in the first embodiment. In FIGS. 8 and 9, the periphery of the hinge 5 for both arms 3a and 3b is hidden by the front 4 and cannot be seen, so the periphery of the hinge 5 is shown by a broken line.

Note that the relationship of the strength and the like of both arms 3a, 3b is the same as in the first embodiment. In the glasses 1 shown in FIG. 8, for both arms 3a and 3b, resin of cellulose-based plastic such as nylon, celluloid, or acetate is similarly used for both arms 3a and 3b. However, the strength difference between the arms 3a and 3b is provided by changing the thickness of the arms 3a and 3b. Further, in the glasses 1 shown in FIG. 9, the upper arm 3a is made of cellulose resin such as nylon, celluloid, or acetate. For the lower arm 3b, for example, a metal having a panel characteristic such as stainless steel or a titanium alloy is used. Since the lower arm 3b is made of metal, the glasses 1 shown in FIG. 9 are formed in a thin wire shape and exhibit the function of the lower arm 3b. In the glasses 1 shown in FIGS. 8 and 9, the lower arm 3b is provided with a slanted portion 3b that extends obliquely upward toward the rear end side as having a function of preventing rotation. Has one. The lower arm 3b rearward from the inclined portion 3bl extends straight and horizontally. In this configuration, when the temple 3 is deployed (i) when the force is also turned upward, the inclined portion 3bl of the lower arm 3b hits the hinge 5 of the upper arm 3a and hinders the rotation of the lower arm 3b. As a result, the rotation of the temple 3 is stopped. The lower arm 3b is not limited to the inclined portion 3b 1 but may be a restricting portion formed on the lower arm 3b to impede the hinge 5 of the upper arm 3a and hinder the rotation of the lower arm 3b. Around the hinge 5 of the upper arm 3a, and behind it, only the bent portion that is inclined diagonally downward toward the rear end, or around the hinge 5 of the upper arm 3a. The shape, etc., of the control piece is not limited.

 As described above, in the present embodiment, by providing the rotation stop, it is possible to prevent the user from forcibly turning the temple 3 from the unfolded state (i) to the upper side, whereby the glasses 1 are damaged. It is possible to realize further improvement in handling and stability, which can be done without any problems.

Claims

The scope of the claims

 [1] A temple with two arms on the front side,

 A hinge that bisects the horizontal angle between the respective temple positions in the unfolded state and the stowed state, and that connects the two arms individually one above the other using a pivot axis located in the middle;

 Has,

 Eyeglasses in which the temple rotates between a deployed state and a stored state with the temple facing its inner surface side toward the rotation axis about the rotation axis,

 Eyeglasses, wherein a strength difference is provided between two arms of the temple.

[2] The strong arm of the two arms of the temple bears the frame rigidity of the glasses, and the weak arm deforms radially during rotation to exhibit restoring force. The glasses described in 1.

 [3] The rotation of the temple is restricted between a deployed state and a stowed state within a range where the strength is low and a semicircle capable of radially deforming the arm is drawn. The glasses described in 2.

 [4] The component of the restoring force acting in the direction of rotating the temple is directed in the direction of rotating the temple to the deployed state near the deployed state, and is turned to the retracted state near the stored state. 3. The glasses according to claim 2, wherein the glasses are oriented in a direction in which the glasses are moved.

 [5] The front member to which the hinge is attached is vertically divided between the two rotation axes, and the relative position of the divided part is shifted forward and backward according to the position of the temple. The eyeglasses according to claim 1, wherein:

 6. The glasses according to claim 1, further comprising a detent for restricting rotation of the temple.

 [7] A projection is provided on the front member to which the hinge is attached,

 7. The glasses according to claim 6, wherein the detent is performed by bringing the arm into contact with the protrusion.

[8] One of the two arms is provided with a restricting portion capable of contacting the hinge for the other arm, 7. The spectacles according to claim 6, wherein the detent is performed by bringing the restricting portion into contact with the hinge.

 A front with a front curve,

 The front has two arms, a temple that forms a curve that is continuous with the front when deployed,

 On the back of the front, the two arms are individually arranged vertically and connected by using a rotation axis located at an intermediate position which bisects the horizontal angle between the respective temple positions in the unfolded state and the stored state. Hinges,

Has,

 The temple rotates between the unfolded state and the stored state around the rotation axis while directing the concave curve on the inner surface side toward the rotation axis. A pair of eyeglasses that form a curve overlapping the front curve, and the eyeglasses are arcuate;

 A strength difference is provided between the two arms of the temple, and the stronger arm of the two arms of the temple bears the frame rigidity of the glasses, and the weaker arm deforms radially during rotation to reduce the restoring force. Eyeglasses characterized by exerting.