CN219871978U - Glasses with glasses - Google Patents

Abstract

The embodiment of the disclosure discloses glasses, which are specifically implemented by: the eyeglass comprises a frame and a temple assembly. The glasses leg component is connected with the glasses frame and comprises an ear hook and at least two strip-shaped bodies, the strip-shaped bodies are movably connected with the ear hook, and the superposition length of each strip-shaped body and the ear hook is respectively controlled through the movement of the ear hook along the strip-shaped bodies, so that the relative positions of the ear hook and the glasses frame are adjusted.

Description

Glasses with glasses

Technical Field

The disclosure relates to the technical field of wearing, in particular to glasses.

Background

The horizontal distance between the eyes and ears of different users is often different, requiring eyeglasses to be able to adjust the distance that the frame and temple overlap. There is also a general difference in the longitudinal distance between the eyes and ears of different users, requiring eyeglasses while being able to adjust the longitudinal distance between the frame and the temple ear. So just can guarantee that the user can adjust glasses to suitable wearing according to self needs.

Disclosure of Invention

The embodiment of the disclosure provides a pair of glasses, in order to achieve the above purpose, the disclosure provides the following technical scheme:

the present disclosure provides an eyeglass comprising: the glasses leg assembly is connected with the glasses frame and comprises an ear hook and at least two strip-shaped bodies, the strip-shaped bodies are movably connected with the ear hook, and the superposition length of each strip-shaped body and the ear hook is respectively controlled through the movement of the ear hook along the strip-shaped bodies, so that the relative positions of the ear hook and the glasses frame are adjusted.

The technical scheme of the present disclosure is described in further detail below through the accompanying drawings and examples.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the disclosure and together with the description, serve to explain the principles of the disclosure.

The disclosure may be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings in which:

FIG. 1 shows a schematic side view of glasses provided by an embodiment of the present utility model;

fig. 2 shows a schematic view of adjusting the height of the ear hook on the basis of fig. 1;

fig. 3 shows a perspective view of glasses provided by an embodiment of the present utility model;

fig. 4 is a schematic diagram showing a fitting structure of a strip-shaped body of glasses and a seat body of an ear hook according to an embodiment of the present utility model;

FIG. 5 shows a schematic view of an ear-hook height being raised based on the state shown in FIG. 4;

FIG. 6 shows a schematic view of lowering the height of the earhook based on the state shown in FIG. 4;

fig. 7 is a state diagram showing that the glasses provided by the embodiment of the utility model move the ear-hook to the side of the glasses frame based on the state shown in fig. 4.

In the figure, 1, a mirror frame; 11. a rotating assembly; 2. a temple assembly; 21. ear-hanging; 211 a base; 2111 a first seat; 2112. a second seat body; a. a first mounting portion; b. a second mounting portion; 22. a strip-shaped body; 221. an anti-falling part; 222. and a limiting part.

It should be noted that these drawings and the written description are not intended to limit the scope of the inventive concept in any way, but to illustrate the inventive concept to those skilled in the art by referring to the specific embodiments.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions in the embodiments will be clearly and completely described with reference to the accompanying drawings in the embodiments of the present utility model, and the following embodiments are used to illustrate the present utility model, but are not intended to limit the scope of the present utility model.

In the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "upper", "lower", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted", "connected" and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art. Fig. 1 and 2 illustrate some embodiments of glasses provided in connection with the present disclosure, the glasses comprising: a mirror frame 1 and a mirror leg assembly 2. The glasses leg assembly 2 is connected with the glasses frame 1, the glasses leg assembly 2 comprises an ear hook 21 and a strip-shaped body 22, the strip-shaped body 22 is movably connected with the ear hook 21, and the superposition length of each strip-shaped body 22 and the ear hook 21 is respectively controlled through the movement of the ear hook 21 along the strip-shaped body 22, so that the relative positions of the ear hook 21 and the glasses frame 1 are adjusted. The glasses generally include two temple assemblies 2, and the two temple assemblies 2 are respectively disposed at two sides of the glasses frame 1 along the length direction. When the user wears the glasses, the ear-hooks 21 of the temple assemblies 2 on both sides of the glasses are respectively overlapped on both ears of the wearer.

An ear hook 21 is provided at the end of the temple assembly 2. The ear hook 21 is adapted to directly overlap the wearer's ear when the user wears the glasses. The ear hook 21 can be provided with an arc-shaped structure, and is matched with the shape of the auricle part of the human ear, so that wearing comfort is improved. To further enhance wearing comfort, the ear may be redesigned. For example, the ear hook 21 may be provided in a flat structure, and the ear hook 21 is provided with a closed hollow structure, so that the weight of the ear hook 21 is reduced, and the structural strength of the ear hook 21 is not greatly affected.

The ear hook 21 may be elongated, and the length of the ear hook 21 extending substantially along the length of the strip 22, and the overlapping length of the strip 22 and the ear hook 21 may be understood as the length of the projection of the strip 22 to the side of the ear hook 21. The greater the overlap length of the strip 22 and the ear-hook 21, the shorter the distance between the ear-hook 21 and the frame 1, otherwise the longer the distance between the ear-hook 21 and the frame 1.

Each temple assembly 2 may include two, three or more bars 22. Taking two strip-shaped bodies 22 as an example, the ear hooks 21 are respectively connected to one ends of the two strip-shaped bodies 22, which are away from the glasses frame 1. In the naturally open state of the temple assembly 2, the movement of the ear hook 21 along the bar 22 can adjust the ear hook 21 to approach or depart from the frame 1. Taking the ear hook 21 as a reference, the process of moving the ear hook 21 can also be regarded as a process of moving the two bar-shaped bodies 22 along the ear hook 21. As shown in fig. 4 and 7, when the two bar-shaped bodies 22 move synchronously along the ear hook 21, the relative angular position of the ear hook 21 and the mirror frame 1 is approximately unchanged, and the overlapping length of the bar-shaped bodies 22 and the ear hook 21 is mainly adjusted, namely the length of the mirror leg assembly 2 is adjusted. As shown in fig. 2, continuing to use the ear hook 21 as a reference, when the two bar bodies 22 move asynchronously relative to the ear hook 21, the difference in positions of the two bar bodies 22 relative to the ear hook 21 brings about a change in the height of the ear hook 21 relative to the frame 1. Stated another way, when the two bar-shaped bodies 22 move asynchronously relative to the ear-hook 21, the shape formed between the frame 1, the ear-hook 21 and the two bar-shaped bodies 22 is deformed, and the height of the ear-hook 21 is changed, so that the purpose of adjusting the height of the ear-hook 21 relative to the frame 1 is achieved. It can be seen that the horizontal distance and the longitudinal distance of the glasses frame 1 opposite to the ear-hook 21 can be adjusted by operating the ear-hook 21 to move along the glasses legs, so that the glasses satisfy the wearing requirements of users with different facial forms.

It will be appreciated that the material from which the body 22 is made may have certain properties of stiffness, strength, hardness and toughness. The strip 22 of material is resistant to deformation and breakage under external forces. For example, the strip 22 may be made of plastic, metal, or other materials. Alternatively, the strip 22 may be made of a titanium-containing material, such as metallic titanium or a titanium alloy, or the like. The titanium material has good mechanical properties, is convenient for the inward folding of the glasses leg component 2, and is favorable for glasses storage. The strip 22 of titanium-containing material has high structural strength, light weight, and good durability.

Fig. 3 shows a schematic perspective view of glasses provided in connection with the present disclosure. The ear hook 21 may be provided with a first mounting portion a and a second mounting portion b, the first ends of the respective bar-shaped bodies 22 are connected to the frame 1, the distance between the first ends of the two bar-shaped bodies 22 is greater than the distance between the first mounting portion a and the second mounting portion b, the first mounting portion a is connected to one bar-shaped body 22, the second mounting portion b is connected to the other bar-shaped body 22, and the first mounting portion a and the second mounting portion b can be moved to fixed positions along the respective bar-shaped bodies 22, respectively, to adjust the relative positions of the ear hook 21 and the frame 1.

The mirror frame 1, the ear hook 21 and the two strip-shaped bodies 22 form a roughly triangular structure, and the structural stability of the mirror leg assembly 2 is good. The strip-shaped bodies 22 are not connected, hollow areas are arranged between the adjacent strip-shaped bodies 22, and the whole glasses leg assembly 2 is high in stability, simple in structure and lighter in weight.

The mounting portion may be a hole, a clamping structure, or a combination of the two. Several alternative embodiments of the mounting portion are provided below.

In an alternative embodiment, the mounting portion may be a clamping structure (not shown) which may be clampingly secured to the strip 22 in different positions to effect adjustment of the position of the fixed ear-hook 21. The specific structure of the clamping structure is not limited. Any structure that is convenient to disassemble and to clamp to the strip 22 may be suitable for use with the mounting portion of the disclosed embodiments.

In another alternative embodiment, the mounting portion may be a hole provided in the ear hook 21, into which hole the end of the strip 22 may be inserted. The hole has a certain extension length, and the depth of the insertion hole of the strip-shaped body 22 can be adjusted, so that the aim of adjusting the superposition length of the strip-shaped body 22 and the ear hook 21 is fulfilled. The hole may be a blind hole or a through hole, which is not limited in the present utility model.

In yet another alternative embodiment, the first mounting portion a may be a hole and the second mounting portion b may be a clamping structure, one of the two strips 22 being inserted into the hole and the other being in clamping connection with the clamping structure. The aim of adjusting the relative positions of the ear hook 21 and the mirror frame 1 can be achieved by adjusting the fit positions of the two strip-shaped bodies 22 with the holes and the clamping structures respectively.

In some alternative embodiments, the earhook 21 may include a strip-shaped body and a seat 211. Wherein the strip-shaped body is sheet-shaped, and the seat 211 is disposed on one side surface of the strip-shaped body in the thickness direction, as shown in fig. 3. The base 211 protrudes from the surface of the strip-shaped body. The seat 211 extends and protrudes in the thickness direction of the strip-shaped body. The first and second mounting portions a and a may be through holes provided in the base 211. The two bar-shaped bodies 22 may be provided to penetrate the two penetration holes, respectively.

In some alternative embodiments, the housing 211 may include a first housing 2111 and a second housing 2112. The first and second housings 2111 and 2112 are sequentially spaced apart along the length of the ear hook 21, as shown in fig. 3, and the first and second housings 2111 and 2112 each have a first mounting portion a and a second mounting portion b. The distance between the first mounting portion a and the second mounting portion b of the first housing 2111 is greater than the distance between the first mounting portion a and the second mounting portion b of the second housing 2112, one of the bar-shaped bodies 22 is connected to the first mounting portion a on the first housing 2111 and the second housing 2112, respectively, and the other bar-shaped body 22 is connected to the second mounting portion b on the first housing 2111 and the second housing 2112, respectively, as shown in fig. 3.

By providing two housings 211, more first mounting portions a and second mounting portions b can be provided, improving the stability of the connection structure of the ear hook 21 and the strip-shaped body 22. After the ear hook 21 and the strip-shaped body 22 are fixed, the ear hook is more easily in a stable state, and the two are not easy to generate relative movement. The distance between the first mounting portion a and the second mounting portion b of the first seat 2111 is greater than the distance between the first mounting portion a and the second mounting portion b of the second seat 2112, so that the ends of the two strips 22 near the frame 1 are relatively separated, and the ends near the ear hanger 21 are relatively close. A trapezoid structure can be formed among the first seat 2111, the second seat 2112 and the two strip-shaped bodies 22, so that the stability of the fixing structure of the strip-shaped bodies 22 and the ear hook 21 is enhanced.

In some alternative embodiments, as shown in fig. 3, the second end of the strip 22 is provided with a drop-preventing portion 221, and the second seat 2112 is located on a side of the first seat 2111 away from the frame 1, and in a state where the ear hook 21 moves along the strip 22 to the end of the strip 22, the second seat 2112 abuts against the drop-preventing portion 221.

The anti-falling portion 221 is located at the end of the bar 22, and can limit the position of the second seat 2112, preventing the second seat 2112 from sliding out of the bar 22. The drop-off prevention portion 221 may extend radially along the cross section of the strip 22. For example, the drop-preventing portion 221 may extend in the width direction of the ear hook 21, and the strip-shaped body does not block the drop-preventing portion. When the mounting portion is a through hole, the bar 22 is disposed through the through hole, and the lens frame 1 and the anti-release portion 221 are located on both sides of the base, respectively, so that the ear hook 21 cannot be separated from the bar 22. And the size of the escape prevention part 221 is larger than that of the penetration hole.

In some alternative embodiments, the glasses may further comprise a limiting structure (not shown) for limiting the relative movement of the ear-hook 21 and the strip 22 in a steady state of the glasses. The limiting structure can limit and fix the ear hook 21 to the appointed position of the strip-shaped body 22, and the ear hook 21 and the strip-shaped body 22 cannot move relatively until the external force is larger than the threshold value. This limit structure can prevent that the ear-hook 21 from moving along the bar 22 when the user wears glasses, has changed the relative position of ear-hook 21 and picture frame 1 to improve the stability of glasses.

In some alternative embodiments, each bar 22 is disposed in correspondence with a limit structure. In a state where the ear hook 21 and the strip-shaped body 22 are connected, a limit structure corresponding to one strip-shaped body 22 is used for limiting the sliding of the base 211 in the first direction, and a limit structure corresponding to the other strip-shaped body 22 is used for limiting the movement of the base 211 in the second direction. The first direction and the second direction may be substantially opposite in direction, or the first direction and the second direction may have an included angle. For example, the first direction may be a direction along which one bar is directed toward the ear hook 21, and the second direction may be a direction along which the other bar is directed toward the frame 1. Under the action of the two limiting structures and the mounting parts, the ear hook 21 receives forces in different directions and is finally in a stress balance state, and the ear hook 21 can be stabilized on the strip-shaped body 22 and cannot easily move along the strip-shaped body 22.

It should be noted that the limiting structure may be disposed on the strip 22, the seat 211, or the ear hook 21, which is not limited in the embodiment of the disclosure. The limit structure can adopt a plurality of different setting schemes. Several alternative embodiments are provided below:

in an alternative embodiment, referring to fig. 7, the limiting structure is a plurality of limiting portions 222 disposed on the strip 22, and the limiting portions 222 are sequentially disposed at intervals along the length direction of the strip 22. Therefore, the ear hook 21 can move along the strip 22 under the action of external force, and can be limited and fixed by the limiting part 222 at the corresponding position on the strip 22.

The limiting parts 222 can protrude from the surface of the strip-shaped body 22, two limiting parts 222 are respectively arranged on two sides of the strip-shaped body 22, which are positioned on the ear hook 21, in a state that the ear hook 21 is connected with the strip-shaped body 22, one limiting part 222 limits the sliding of the seat body 211 towards the mirror frame 1, and the other limiting leg part limits the movement of the seat body 211 towards a direction away from the mirror frame 1, so that the position of the ear hook 21 is limited. The limiting portion 222 may have a smooth outer convex surface, so that the ear hook 21 overcomes the resistance of the limiting portion 222 and smoothly passes through the limiting portion 222 under the action of external force. When the ear hook 21 is located between the two limiting portions 222, if the external force applied to the ear hook 21 is insufficient, the ear hook 21 cannot move along the bar 22 due to the resistance of the limiting portions 222.

In another alternative embodiment, the limiting structure may be a plurality of limiting portions 222 disposed on the strip 22, where each of the limiting portions 222 is sequentially disposed at intervals along the length direction of the strip 22, and each of the limiting portions 222 may include an elastic member. In the process that the ear hook 21 moves along the strip-shaped body 22 and passes through the elastic piece, the elastic piece is in an elastic compression state, and in the state that the elastic piece is separated from the base 211, the elastic piece is restored to be deformed, and two adjacent elastic pieces are limited on two sides of the ear hook 21. The distance between the two elastic members is matched with the thickness of the base 211, so that the ear-hook 21 is prevented from having a small free movement space along the strip-shaped body 22. The elastic member may be a rubber protrusion, a silicone protrusion or other structures provided on the bar 22. The elastic member may also be a spring, for example, the elastic member may be a metal spring. The middle part of the metal spring plate protrudes outwards, and guide inclined planes are respectively arranged on two sides of the metal spring plate along the length direction of the strip-shaped body 22, so that the ear hook 21 can conveniently and smoothly pass through the metal spring plate under the action of external force.

In yet another alternative embodiment, the limiting structure may be a damping portion (not shown) provided on the seat 211 and/or the strip 22. A damping member is provided between the seat 211 and the strip 22 to define the relative position therebetween. Only when enough external force is applied to the ear hook 21, the position of the ear hook 21 can be adjusted against the resistance of the damping part, otherwise, under the action of the damping part, the ear hook 21 and the strip-shaped body 22 are connected into an integral structure, and relative movement between the two cannot occur.

In the case where the damper is provided in the seat body 211, the ear hook 21 has a first through hole and a second through hole, and the damper is provided in the inner walls of the first through hole and the second through hole. In a state where the strip 22 penetrates the first through hole and the second through hole, the damping member and the strip 22 are in close contact with each other, and the movement resistance of the ear hook 21 is increased. In the case where the damping portion is provided on the strip 22, the damping portion may be provided on the surface of the strip 22. For example, the damping portion may be provided to cover the strip 22. In a state that the strip-shaped body 22 penetrates through the through hole of the ear hook 21, the damping part is in close contact with the ear hook 21, so that the movement resistance of the ear hook 21 is increased, the ear hook 21 can move along the strip-shaped body 22 only when the external force is large enough, otherwise, the ear hook 21 and the strip-shaped body 22 are in limit fit, and no relative movement exists between the two parts.

The specific structure of the damping portion is not limited, and for example, the damping portion may be an elastic ring body, sleeved on the strip-shaped body 22 or embedded on the inner wall of the through hole. In a state where the strip-shaped body 22 penetrates the penetration hole in the base body, the damping portion is in a compressed state, and resistance against relative sliding of the strip-shaped body 22 and the ear hook 21 is increased.

It should be noted that the damping portion may be a single piece, and the damping portion may be detachably mounted on the strip 22 or the ear hook 21. The damping portion may be integrally formed with the strip 22, and both may be manufactured as an integral structure using an injection molding process. The damping part and the ear hook 21 can be integrally formed, and the two parts can be made into an integral structure by adopting an injection molding process.

Fig. 4 to 7 show some embodiments of spectacles in which the bar 22 is rotatably connected to the frame 1, the axis of rotation of the bar 22 being parallel to the length direction of the frame 1, the bar 22 being rotatable about the axis of rotation to adjust the height of the ear-hook 21 relative to the frame 1 to suit the face shape of different users. The two bar-shaped bodies 22 of each temple assembly 2 are respectively rotatably connected to both sides of the frame 1 in the width direction. During rotation of the temple assembly 2, the shape formed between the two strips 22 is changed, and the two strips 22 can adaptively move the adjusting position along the corresponding through grooves, so that the ear hook 21 and the two strips 22 reach a natural fixed state.

As shown in fig. 4 and 5, when the bar 22 is rotated counterclockwise relative to the frame 1, the angle between the bar 22 and the frame 1 increases gradually, so that the height of the ear hook 21 increases gradually. As can be seen from fig. 4 to 5, the angle formed by the strip 22 with the frame 1 becomes greater, so that the height of the ear hook 21 with respect to the frame 2 becomes greater. As shown in fig. 4 and 6, when the bar 22 is rotated clockwise relative to the frame 1, the angle between the bar 22 and the frame 1 gradually decreases, so that the height of the ear hook 21 can be gradually reduced. As can be seen by comparing fig. 4 and 6, the angle formed by the strip 22 with the frame 1 becomes smaller, so that the height of the ear hook 21 with respect to the frame 2 becomes smaller. When the ear height is adjusted, the magnitude and direction of the pressure of the frame 1 on the face are also affected, thereby changing the wearing comfort. Therefore, under different use scenes, the user can also change the pressure and direction of the glasses to the face of the user by adjusting the angle between the strip-shaped body 22 and the glasses frame 1, so that the user experience is improved. In some alternative embodiments, the strip 22 is connected to the frame 1 by the rotating assembly 11, and the rotating assembly 11 may be arranged in any of the following ways:

the first setting mode is as follows: the rotating assembly 11 has a plurality of gears, when the bar 22 rotates to different gears, the included angles between the bar 22 and the mirror frame 1 are different, and after the bar 22 moves to the corresponding gear, the bar 22 can hover at the corresponding angle. Only if a sufficient external force is applied to the bar 22, the bar 22 is moved out of the current gear to another gear.

The second setting mode is as follows: the rotating assembly 11 has damping means, the bar 22 being rotatable within a set angular range with respect to the frame 1. The bar 22 can be fixed at any angle within a set angle range by the damping member. The specific structure of the rotating assembly 11 is not limited in the embodiment of the present disclosure, and the rotating assembly 11 may adopt an existing mature structure.

The rotating assembly 11 can enable the strip-shaped body 22 and the glasses frame 1 to stably hover at a specific angle, so that the stability of wearing the glasses by a user can be further improved. It will be appreciated that the rotating assembly may be a common shaft, and the limiting structure may also ensure the stability of hovering of the bar 22 and the frame 1.

In some alternative embodiments, the bar 22 can be rotated about an axis parallel to the height direction of the frame 1 to adjust the opening angle of the temple assembly 2. For example, the strip 22 may be made of a titanium material. The titanium material has good mechanical properties, is convenient for the inward folding of the glasses leg component 2, and is favorable for glasses storage. The height direction of the lens frame 1 is understood to mean the direction in which the legs of the lens are perpendicular to the plane in which the lens frame is formed.

In some alternative embodiments, the glasses may further include a connection base (not shown) hinged to the frame 1 such that a rotation axis of the connection base with respect to the frame 1 is parallel to a height direction of the frame 1, the bar 22 is rotatably connected to the connection base, a rotation axis of the bar 22 with respect to the connection base is perpendicular to the rotation axis of the connection base with respect to the frame 1, and the bar 22 is rotatable about the rotation axis of the connection base with respect to the frame 1 to adjust the opening angle of the temple assembly 2. When the bar 22 and the connection base are rotated together about the rotation axis parallel to the height direction of the lens frame 1, the adjustable temple assembly 2 is folded inside the lens frame 1 or the temple assembly 2 is unfolded to adjust the opening angle of the temple assembly 2. When the strip 22 rotates relative to the connecting seat around the rotation axis parallel to the height direction of the glasses frame (1), the height of the ear-hook 21 relative to the glasses frame (1) can be adjusted.

The foregoing description has been presented for purposes of illustration and description. Furthermore, this description is not intended to limit the embodiments of the disclosure to the form disclosed herein. Although a number of example aspects and embodiments have been discussed above, a person of ordinary skill in the art will recognize certain variations, modifications, alterations, additions, and subcombinations thereof.

Claims (6)

1. An eyeglass, comprising:

a frame;

the glasses leg assembly is connected with the glasses frame and comprises an ear hook and at least two strip-shaped bodies, wherein the strip-shaped bodies are movably connected with the ear hook, and the relative positions of the ear hook and the glasses frame are adjusted by respectively controlling the superposition length of each strip-shaped body and the ear hook through the movement of the ear hook along the strip-shaped body.

2. The pair of glasses according to claim 1, wherein the ear-hook has a first seat and a second seat, the first seat and the second seat are sequentially spaced along the length direction of the ear-hook, the second seat is located at a side of the first seat away from the glasses frame, and the first seat and the second seat each have a first mounting portion and a second mounting portion;

the first ends of the strip-shaped bodies are connected to the mirror frame, the second ends of the strip-shaped bodies are provided with anti-falling parts, and the distance between the first ends of the two strip-shaped bodies is larger than the distance between the first installation parts and the second installation parts;

the distance between the first installation part and the second installation part of the first seat body is larger than the distance between the first installation part and the second installation part of the second seat body;

one strip-shaped body is respectively connected with the first installation parts on the first seat body and the second seat body, and the other strip-shaped body is respectively connected with the second installation parts on the first seat body and the second seat body;

the first mounting part and the second mounting part can respectively move to fixed positions along the corresponding strip-shaped bodies so as to adjust the relative positions of the ear hook and the glasses frame;

wherein, in the state that the ear hook moves to the tail end of the strip-shaped body along the strip-shaped body, the second seat body is propped against the anti-drop part.

3. The eyeglass of claim 1, wherein the earhook comprises a base, the strip being movably coupled to the base, the eyeglass further comprising a spacing structure for spacing the earhook to a designated location of the strip;

each strip-shaped body is correspondingly arranged with the limiting structure, and in the state that the ear hook is connected with the strip-shaped body, the limiting structure corresponding to one strip-shaped body is used for limiting the sliding of the seat body in a first direction, and the limiting structure corresponding to the other strip-shaped body is used for limiting the movement of the seat body in a second direction;

the limiting structure adopts any one of the following setting modes:

the limiting structure is a plurality of limiting parts arranged on the strip-shaped body, the limiting parts are sequentially arranged at intervals along the length direction of the strip-shaped body, and the seat body can move along the strip-shaped body and can be limited and fixed by the limiting parts at corresponding parts on the strip-shaped body;

the limiting structure is a plurality of limiting parts arranged on the strip-shaped body, the limiting parts comprise elastic sheets, the elastic sheets are in an elastic compression state in the process that the base body moves along the strip-shaped body and passes through the elastic sheets, and the elastic sheets recover to deform in the state that the elastic sheets are separated from the base body;

the limiting structure is a damping part arranged on at least one of the base body and the strip-shaped body, the base body is provided with a first through hole and a second through hole, and the damping part is arranged on the inner walls of the first through hole and the second through hole under the condition that the damping part is arranged on the base body; the damping portion is provided on the surface of the strip-shaped body in the case where the damping portion is provided on the strip-shaped body.

4. A pair of spectacles according to any of claims 1 to 3, wherein the bar is rotatably connected to the frame by a rotation assembly, the axis of rotation of the bar being parallel to the length of the frame, the bar being rotatable about the axis of rotation to adjust the height of the ear hook;

the rotating assembly adopts any one of the following setting modes:

the rotating assembly is provided with a plurality of gears, and when the strip-shaped body rotates to different gears, the included angles between the strip-shaped body and the glasses frame are different;

the rotating assembly is provided with a damping component, the strip-shaped body can rotate in a set angle range relative to the mirror frame, and the strip-shaped body can be fixed at any angle in the set angle range under the action of the damping component.

5. A pair of spectacles according to any of claims 1 to 3, wherein the bar is rotatable about an axis parallel to the height of the frame to adjust the opening angle of the temple assembly.

6. A pair of spectacles according to any of claims 1 to 3, wherein the spectacles comprise a connection mount hinged to the frame such that the axis of rotation of the connection mount relative to the frame is parallel to the height of the frame;

the strip-shaped body is rotatably connected with the connecting seat, and the rotating axis of the strip-shaped body relative to the connecting seat is perpendicular to the rotating axis of the connecting seat relative to the mirror frame;

the strip body can rotate around the connecting seat relative to the rotating axis of the mirror frame so as to adjust the opening angle of the mirror leg assembly.