BUCKLE ARRANGEMENT

The buckle arrangement addresses the safety and usability issues of conventional buckle assemblies by incorporating an inconspicuous actuating component with elastic deformation and magnetic structures for secure and easy release, ensuring safe and efficient operation.

DE102020118928B4Active Publication Date: 2026-06-11WONDERLAND SWITZERLAND AG

Patent Information

Authority / Receiving Office
DE · DE
Patent Type
Patents
Current Assignee / Owner
WONDERLAND SWITZERLAND AG
Filing Date
2020-07-17
Publication Date
2026-06-11

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Abstract

A buckle arrangement (100, 100') characterized in that the buckle arrangement (100, 100') comprises: a first buckle component (1) comprising a locked section (5); a second buckle component (2, 2') comprising a locking section (4, 4') designed to interact with the locked section (5), wherein the locking section (4, 4') engages with the locked section (5) along a lateral direction of the buckle assembly (100, 100') when the second buckle component (2, 2') is joined with the first buckle component (1) along an assembly direction; and an actuating component (3) which is partially embedded in the second buckle component (2, 2') and partially exposed from the second buckle component (2, 2'), wherein the actuating component (3) is configured to interact with the locking section (4, 4') and to be displaceable relative to the second buckle component (2, 2') along the lateral direction, wherein the actuating component (3) drives the locking section (4, 4') such that during a displacement movement of the actuating component (3) relative to the second buckle component (2, 2') the locking section (4, 4') moves away from the locked section (5) so that the locking section (4, 4') releases from the locked section (5).
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Description

Field of invention

[0001] The present invention relates to a buckle arrangement. Background of the invention

[0002] With economic development and technological advancements, the market offers an increasing number of consumer goods that bring convenience to people's lives. Child transport devices are one such consumer goods.

[0003] It is known that straps are indispensable for child transport devices, and buckle arrangements are usually provided on the straps for fastening and releasing the straps.

[0004] Currently, a conventional buckle assembly comprises a male buckle, a female buckle that engages with the male buckle, and a release button. The male and female buckles can be separated by the release button. The release button is usually located on the front or back of either the male or female buckle to provide the user with easy access to operate it. However, because the release button is located in such a conspicuous position, it is easy for a child in a child carrier to see that it is present, creating a potential hazard caused by the child unintentionally releasing the buckle assembly through unconscious contact.When the release button of a conventional buckle assembly is actuated, a considerable force must be applied, making release difficult. Furthermore, the placement of the release button on the front or back of the male or female buckle increases the likelihood of it being struck by other objects, adding to the potential hazard of unintentional release. Therefore, even if a buckle assembly is equipped with an inconspicuous release button, it still has a complex structure and is difficult to operate.

[0005] DE 11 2012 007 255 B4 discloses a buckle with a male component and a female component that are connectable and separable from each other, each having a fastening area for attachment to another element, wherein the male component is designed with an engaging area projecting from a main body area having the fastening area, wherein the female component is designed with an elastic pressure part having an engagement area, which is designed for coupling with the engaging area, and a receiving main body with a receiving space equipped for receiving the elastic pressure part, wherein the receiving main body is designed with an opening area connected to the receiving space, which is designed to insert the engaging area through it.and wherein the elastic pressing element is formed integrally with the following: a pair of pressing areas projecting from the receiving space of the receiving main body; an elastic body area connecting the pair of pressing areas and elastically supporting the pressing areas to enable elastic movement of the pressing areas into the receiving main body; and the engagement area elastically held on the elastic body area, wherein the engagement area is designed such that it is movable by pressing the pressing areas in a direction intersecting the pressing direction of the pair of pressing areas.

[0006] Therefore, it is necessary to offer an improved buckle arrangement to solve the problems mentioned above. Summary of the invention

[0007] In this sense, the present invention is aimed at providing a buckle arrangement with an inconspicuous actuating component and simple operation.

[0008] This is achieved by a buckle arrangement according to claim 1. The dependent claims relate to corresponding further developments and improvements.

[0009] As can be seen more clearly from the following detailed description, the claimed buckle assembly comprises a first buckle component, a second buckle component, and an actuating component. The first buckle component comprises a locking section. The second buckle component comprises a locking section configured to interact with the locking section. The locking section engages with the locking section along a lateral direction of the buckle assembly when the second buckle component is joined with the first buckle component along an assembly direction. The actuating component is partially embedded in the second buckle component and partially exposed from the second buckle component.The actuating component is designed to interact with the locking section and to be displaceable relative to the second buckle component along the lateral direction. The actuating component drives the locking section such that, during a displacement movement of the actuating component relative to the second buckle component, the locking section moves away from the locked section, thus releasing the locking section from the locked section.

[0010] According to one embodiment of the present invention, the locked section is arranged on a front surface of the first buckle component.

[0011] According to one embodiment of the present invention, the locking section is an elastic structure, and the actuating component elastically deforms the locking section in order to release the locking section from the locked section during the displacement movement of the actuating component relative to the second buckle component.

[0012] According to one embodiment of the present invention, the locking section comprises an elastic arm and a locking head connected to the elastic arm. The elastic arm is configured to interact with the actuating component. The locking head is configured to engage with the locked section. The elastic arm is biased to engage the locking head with the locked section, and the actuating component elastically deforms the elastic arm to release the locking head from the locked section during the sliding movement of the actuating component relative to the second buckle component.

[0013] According to one embodiment of the present invention, the actuating component is displaceable relative to the second buckle component along the lateral direction. An adjacent section projects from the actuating component along the lateral direction. A cooperating section is formed at a free end of the elastic arm and is configured to interact with the adjacent section. The actuating component rests against the cooperating section through the adjacent section in order to elastically deform the elastic arm, so that the locking head releases from the locked section during the displacement movement of the actuating component relative to the second buckle component.

[0014] According to one embodiment of the present invention, the cooperating section is aligned with the adjacent section along the lateral direction.

[0015] According to one embodiment of the present invention, the locking head projects from an inner wall of the elastic arm along the lateral direction, and the interacting section is adjacent to the locking head.

[0016] According to one embodiment of the present invention, the locking head and the cooperating section are arranged sequentially along a direction from a fastening end of the elastic arm to the free end of the elastic arm.

[0017] According to one embodiment of the present invention, the locking section is detachably connected to the second buckle component.

[0018] According to one embodiment of the present invention, the locking section further comprises an engagement clamp which is fixedly connected to a fastening end of the elastic arm. An engagement structure is formed on the second buckle component and is configured for releasable engagement with the engagement clamp, and the engagement clamp is releasably embedded in the engagement structure.

[0019] According to one embodiment of the present invention, the engagement structure comprises at least two spaced-apart engagement rods. The engagement clamp is embedded between the at least two engagement rods. Each of the at least two engagement rods comprises an upper retention section and a lower retention section. The upper retention section and the lower retention section are configured to prevent movement of the engagement clamp, and the engagement clamp is arranged between the upper retention section and the lower retention section when the engagement clamp is releasably embedded in the engagement structure.

[0020] According to one embodiment of the present invention, the engagement clamp comprises a step-shaped structure which engages with the lower retention section when the engagement clamp is detachably embedded in the engagement structure.

[0021] According to one embodiment of the present invention, a clearance space is formed between the at least two engagement rods, allowing the elastic arm to move.

[0022] According to one embodiment of the present invention, the locked section comprises an adjacent structure and a locked structure. The adjacent structure rests against the locking head to elastically deform the elastic arm during an assembly process of the first buckle component and the second buckle component. The locked structure is configured to engage with the locking head, and the actuating component elastically deforms the elastic arm to release the locking head from the locked structure during the displacement movement of the actuating component relative to the second buckle component.

[0023] According to one embodiment of the present invention, an end section of the abutting structure comprises a first inclined section that is inclined relative to the assembly direction. The locking head comprises a second inclined section for interacting with the first inclined section, and the abutting structure elastically deforms the elastic arm through the contact of the first inclined section and the second inclined section in order to pass the locking head, so that the locked structure engages with the locking head during the assembly process of the first buckle component and the second buckle component.

[0024] According to one embodiment of the present invention, the locked structure is an undercut and the locking head is configured to engage with the undercut.

[0025] According to one embodiment of the present invention, the locking section comprises a first locking section and a second locking section. The first locking section and the second locking section are arranged on two opposite sides of the locked section and clamp the locked section along the lateral direction. The confirmation component comprises a first confirmation component and a second confirmation component. The first confirmation component and the first locking section are arranged on the same side. The second confirmation component and the second locking section are arranged on the same other side. The first confirmation component is configured to interact with the second locking section.The second confirmation component is configured to interact with the first locking section, and the first confirmation component and the second confirmation component each deform the second locking section and the first locking section to release the first locking section and the second locking section from the locked section during the displacement movement of the confirmation component relative to the second buckle component.

[0026] According to one embodiment of the present invention, the first locking section comprises a first elastic arm and a first locking head connected to the first elastic arm. The first elastic arm is configured to interact with the second actuating component. The first locking head is configured to engage with the locked section. The first elastic arm is biased to engage the first locking head with the locked section. The second actuating component is configured to elastically deform the first elastic arm to release the first locking head from the locked section. The second locking section comprises a second elastic arm and a second locking head connected to the second elastic arm. The second elastic arm is configured to interact with the first actuating component.The second locking head is configured to engage with the locked section. The second elastic arm is pre-tensioned to engage the second locking head with the locked section, and the first actuating component is configured to elastically deform the second elastic arm, thus releasing the second locking head from the locked section.

[0027] According to one embodiment of the present invention, the first actuating component is displaceable relative to the second buckle component along the lateral direction. A first contact section projects from the first actuating component along the lateral direction. A second cooperating section is formed at a free end of the second elastic arm and is configured to interact with the first contact section. The first actuating component contacts the second cooperating section via the first contact section in order to elastically deform the second elastic arm, so that the second locking head releases from the locked section during a displacement movement of the first actuating component relative to the second buckle component. The second actuating component is displaceable relative to the second buckle component along the lateral direction.A second adjacent section projects from the second actuating component along the lateral direction. A first cooperating section is formed at a free end of the first elastic arm and is configured to cooperate with the second adjacent section. The second actuating component rests against the first cooperating section through the second adjacent section in order to elastically deform the first elastic arm during a displacement movement of the second actuating component relative to the second buckle component, so that the first locking head releases from the locked section.

[0028] According to one embodiment of the present invention, the first cooperating section is aligned with the second adjacent section along the lateral direction, and the second cooperating section is aligned with the first adjacent section along the lateral direction.

[0029] According to one embodiment of the present invention, the first locking head projects from an inner wall of the first elastic arm along the lateral direction. The first interacting section is adjacent to the first locking head. The second locking head projects from an inner wall of the second elastic arm along the lateral direction, and the second interacting section is adjacent to the first locking head.

[0030] According to one embodiment of the present invention, the first locking head and the first cooperating section are arranged sequentially along a direction from a fastening end of the first elastic arm to the free end of the first elastic arm, and the second locking head and the second cooperating section are arranged sequentially along a direction from a fastening end of the second elastic arm to the free end of the second elastic arm.

[0031] According to one embodiment of the present invention, the first cooperating section and the second cooperating section are arranged at different heights along an up-down direction of the buckle arrangement, and the first abutting section and the second abutting section are arranged at different heights along the up-down direction.

[0032] According to one embodiment of the present invention, the first cooperating section is aligned offset to the second cooperating section along the lateral direction, and the first adjacent section is aligned offset to the second adjacent section along the lateral direction.

[0033] According to one embodiment of the present invention, the buckle assembly further comprises a first magnetic structure and a second magnetic structure. The first magnetic structure is arranged on the first buckle component. The second magnetic structure is arranged on the second buckle component, and the first magnetic structure magnetically attracts or repels the second magnetic structure during the assembly process of the first buckle component and the second buckle component.

[0034] According to one embodiment of the present invention, a first embedding chamber is formed on the first buckle component. A second embedding chamber is formed on the second buckle component. The first magnetic structure is embedded in the first embedding chamber, and the second magnetic structure is embedded in the second embedding chamber.

[0035] According to one embodiment of the present invention, the first embedding chamber is aligned with the second embedding chamber along the joining direction.

[0036] According to one embodiment of the present invention, an assembly hole is formed on the second buckle component and arranged so that the locked section can pass through the assembly hole.

[0037] According to one embodiment of the present invention, the buckle arrangement further comprises an elastic component which is arranged between the actuating component and the second buckle arrangement and is configured to pre-tension the actuating component to displace it away from the locking section.

[0038] According to one embodiment of the present invention, a C-shaped structure is formed on the second buckle component and is designed to receive the elastic component.

[0039] According to one embodiment of the present invention, a retaining projection projects from the actuating component. The second buckle component comprises a retaining block that interacts with the retaining projection, and the second buckle component, by virtue of the retention block and the retaining projection, blocks the actuating component, thus preventing the actuating component and the second buckle component from releasing.

[0040] According to one embodiment of the present invention, one element, namely the first buckle component or the second buckle component, is a male buckle and another of the two elements (second element) is a female buckle.

[0041] According to one embodiment of the present invention, the locking section comprises a rotary arm, a locking head, and a return component. The rotary arm is pivotably connected to the second buckle component. The locking head is connected to the rotary arm and configured to engage with the locked section. The actuating component is configured to drive the rotary arm to rotate in order to release the locking head from the locked section, and the return component is arranged between the rotary arm and the second buckle component and is configured to bias the rotary arm to rotate in order to engage the locking head with the locked section.

[0042] According to one embodiment of the present invention, the actuating component is displaceable relative to the second buckle component along the lateral direction. An adjacent section projects from the actuating component along the lateral direction. A cooperating section is formed on the pivot arm and configured to interact with the adjacent section. The cooperating section is aligned with the adjacent section along the lateral direction, and during the displacement movement of the actuating component relative to the second buckle component, the adjacent section and the cooperating section cause the pivot arm to rotate, thus releasing the locking head from the locked section.

[0043] According to one embodiment of the present invention, the actuating component is displaceable relative to the second buckle component along a direction of extension perpendicular to the lateral direction and the assembly direction. An adjacent section projects from the actuating component along the direction of extension. A cooperating section is formed on the pivot arm and configured to interact with the adjacent section. The cooperating section is aligned with the adjacent section along the assembly direction, and during the displacement movement of the actuating component, the adjacent section and the cooperating section cause the pivot arm to rotate, thus releasing the locking head from the locked section.

[0044] According to one embodiment of the present invention, the actuating component is displaceable relative to the second buckle component along the assembly direction. An adjacent section projects from the actuating component along the assembly direction. A cooperating section is formed on the pivot arm and configured to interact with the adjacent section. The cooperating section is aligned with the adjacent section along the assembly direction, and during the displacement movement of the actuating component, the adjacent section and the cooperating section cause the pivot arm to rotate, thus releasing the locking head from the locked section.

[0045] According to one embodiment of the present invention, the locking section comprises a first locking section and a second locking section. The first locking section and the second locking section are arranged on two opposite sides of the locked section and clamp the locked section along the lateral direction. The first locking section comprises a first pivot arm, a first locking head, and a first return component. The first pivot arm is pivotably connected to the second buckle component. The first locking head is connected to the first pivot arm and configured to engage with the locked section. The first locking head projects from an inner wall of the first pivot arm along the lateral direction.The first return component is located between the first pivot arm and the second buckle component and is configured to pre-tension the first pivot arm to rotate and engage the first locking head with the locked section. The second locking section comprises a second pivot arm, a second locking head, and a second return component. The second pivot arm is pivotally connected to the second buckle component. The second locking head is connected to the second pivot arm and configured to engage the locked section. The second locking head projects laterally from an inner wall of the second pivot arm, and the second return component is located between the second pivot arm and the second buckle component and is configured to pre-tension the second pivot arm to rotate and engage the second locking head with the locked section.

[0046] According to one embodiment of the present invention, the actuating component comprises a first actuating component and a second actuating component. The first actuating component and the first locking section are arranged on the same side. The second actuating component and the second locking section are arranged on the other side of the same body. The first actuating component and the second actuating component are displaceable relative to the second buckle component along the lateral direction. A first adjacent section projects from the first actuating component along the lateral direction. A second cooperating section is formed on the second pivot arm and configured to interact with the first adjacent section. The second cooperating section is aligned with the first adjacent section along the lateral direction.During a sliding movement of the first actuating component, the first actuating component, through the contact of the first contact section and the second cooperating section, drives the second rotary arm to rotate, thus releasing the second locking head from the locked section. A second contact section projects laterally from the second actuating component. A first cooperating section is formed on the first rotary arm and configured to interact with the second contact section. The first cooperating section is aligned laterally with the second contact section.During a sliding movement of the second actuating component, the second actuating component, through the contact of the second contacting section and the first cooperating section, drives the first rotary arm to rotate, thus releasing the first locking head from the locked section. The first cooperating section and the second cooperating section are arranged at different heights along an up-down direction of the buckle assembly. The first cooperating section is oriented offset laterally to the second cooperating section. The first contacting section and the second contacting section are arranged at different heights along the up-down direction of the buckle assembly, and the first contacting section is oriented offset laterally to the second contacting section.

[0047] According to one embodiment of the present invention, the actuating component is displaceable relative to the second buckle component along a direction of extension perpendicular to the lateral direction and the assembly direction. A first adjacent section and a second adjacent section project from the actuating component along the direction of extension. A second cooperating section is formed on the second pivot arm and configured to interact with the first adjacent section. The second cooperating section is aligned with the first adjacent section along the direction of extension. A first cooperating section is formed on the first pivot arm and configured to interact with the second adjacent section.The first cooperating section is aligned with the second adjacent section along the extension direction, and the actuating component, during the displacement movement of the actuating component, drives the first rotary arm and the second rotary arm to rotate through the contact of the second adjacent section and the first cooperating section and the contact of the first adjacent section and the second cooperating section, so that the first locking head and the second locking head release from the locked section.

[0048] According to one embodiment of the present invention, the actuating component is displaceable relative to the second buckle component along the joining direction. A first adjacent section and a second adjacent section project from the actuating component along the joining direction. A second interacting section is formed on the second pivot arm and configured to interact with the first adjacent section. The second interacting section is aligned with the first adjacent section along the joining direction. A first interacting section is formed on the first pivot arm and configured to interact with the second adjacent section.The first cooperating section is aligned with the second adjacent section along the merging direction, and the actuating component, during the displacement movement of the actuating component, drives the first rotary arm and the second rotary arm to rotate through the contact of the second adjacent section and the first cooperating section and the contact of the first adjacent section and the second cooperating section, so that the first locking head and the second locking head release from the locked section.

[0049] In summary, according to the present invention, the actuating component is arranged on the second buckle component, which includes the locking section that interacts with the locked section of the first buckle component. The actuating component drives the locking section to release it from the locked section when the actuating component is actuated. Therefore, the present invention offers the advantages of a simple structure and ease of use.

[0050] These and other objectives of the present invention will undoubtedly become clear to the person skilled in the art after reading the following detailed description of the preferred embodiment shown in the various drawings and illustrations. Brief descriptions of the drawings

[0051] The invention is further illustrated below by examples with reference to the accompanying drawings. Fig. Figure 1 shows a schematic view of a buckle arrangement according to a first embodiment of the present invention, Fig. Figure 2 shows a view of a second buckle component of the buckle arrangement according to the first embodiment of the present invention. Fig. 3 and Fig. Figure 4 shows exploded views of the buckle arrangement according to the first embodiment of the present invention. Fig. Figure 5 shows a partial view of the buckle arrangement according to the first embodiment of the present invention, Fig. Figure 6 shows a sectional view of the buckle arrangement according to the first embodiment of the present invention, Fig. Figure 7 shows a schematic view of a buckle arrangement according to a second embodiment of the present invention, Fig. Figure 8 shows an exploded view of the buckle arrangement according to the second embodiment of the present invention, Fig. 9 and Fig. Figure 10 shows views of the buckle arrangement in various states according to the second embodiment of the present invention. Fig. Figure 11 shows a schematic view of a buckle arrangement according to a third embodiment of the present invention, Fig. 12 shows a partial view of the buckle arrangement according to the third embodiment of the present invention, Fig. Figure 13 shows an exploded view of the buckle arrangement according to the third embodiment of the present invention, Fig. 14 and Fig. Figure 15 shows views of the buckle arrangement in various states according to the third embodiment of the present invention. Fig. Figure 16 shows a schematic view of a buckle arrangement according to a fourth embodiment of the present invention, Fig. 17 shows a partial view of the buckle arrangement according to the fourth embodiment of the present invention, Fig. Figure 18 shows an exploded view of the buckle arrangement according to the fourth embodiment of the present invention, and Fig. 19 and Fig. Figure 20 shows views of the buckle arrangement in different states according to the fourth embodiment of the present invention. Detailed description

[0052] To illustrate the technical specifications and structural features as well as the purposes and effects achieved by the present invention, relevant embodiments and drawings are described as follows.

[0053] It will be on Fig. 1, Fig. 2, Fig. 3, Fig. 4, Fig. 5 to Fig. 6. Referenced. Fig. Figure 1 shows a schematic view of a buckle arrangement 100 according to a first embodiment of the present invention. Fig. Figure 2 shows a view of a second buckle component 2 of the buckle arrangement 100 according to the first embodiment of the present invention. Fig. 3 and Fig. Figure 4 shows exploded views of the buckle arrangement 100 according to the first embodiment of the present invention. Fig. Figure 5 shows a partial view of the buckle arrangement 100 according to the first embodiment of the present invention. Fig. Figure 6 shows a sectional view of the buckle arrangement 100 according to the first embodiment of the present invention. As in Fig. 1, Fig. 2, Fig. 3, Fig. 4, Fig. 5 to Fig. As shown in Figure 6, the buckle assembly 100 comprises a first buckle component 1, a second buckle component 2, an actuating component 3, and two elastic components 6. The second buckle component 2 includes a locking section 4. The first buckle component 1 includes a locking section 5 configured to interact with the locking section 4. The locking section 4 engages with the locking section 5 along a lateral direction when the first buckle component 1 is joined with the second buckle component 2 along an assembly direction that is Fig. The direction of arrow P shown in Figure 6 can be [unclear]. According to this embodiment, the first buckle component 1 can be a male buckle and the second buckle component 2 can be a female buckle. However, it is not limited to this embodiment. According to another embodiment, the first buckle component can be a female buckle and the second buckle component can be a male buckle.

[0054] The actuating component 3 is partially embedded in the second buckle component 2 and partially exposed from a side wall of the second buckle component 2. The actuating component 3 is configured to interact with the locking section 4 and is displaceable relative to the second buckle component 2 along the lateral direction. It should be noted that, according to the embodiment, the lateral direction can be an arrow direction M1 or M2, which points in Fig. Figure 5 shows that the actuating component 3 drives the locking section 4 to move away from the locked section 5 during a displacement movement of the actuating component 3 relative to the second buckle component 2 along the lateral direction, in order to release the locking section 4 from the locked section 5. The displacement direction of the actuating component 3 can be the same as or opposite to the direction of movement of the locking section 4, so that a force acting on the actuating component 3 and applied by a user along the displacement direction can be fully transmitted to the locking section 4 to release the locking section 4 from the locked section 5, thus preventing a distribution of the force in different directions and enabling easy and user-friendly release of the buckle assembly 100.

[0055] The locked section 5 is arranged on a front surface of the first buckle component 1. An assembly hole 21 is formed on the second buckle component 2, so that the locked section 5 can pass through the assembly hole 21, and the assembly direction, which is defined in Fig. The arrow direction P shown in 6 intersects the direction of movement of the actuating component 3, which is shown in Fig. The arrow direction shown in Figure 5 can be M1 or M2. Consequently, such an arrangement can reduce the thickness of the buckle assembly 100 along the joining direction and enable efficient use of the interior space of the buckle assembly 100.

[0056] In particular, as in Fig. 3, Fig. 4, Fig. 5 to Fig. As shown in Figure 6, the locking section 4 is an elastic structure. During the displacement movement of the actuating component 3 relative to the second buckle component 2, the actuating component 3 elastically deforms the locking section 4 along the lateral direction to release the locking section 4 from the locked section 5. Furthermore, the locking section 4 comprises a first locking section 4a and a second locking section 4b. The first locking section 4a and the second locking section 4b are arranged on two opposite sides of the locked section 5 and clamp the locked section 5 along the lateral direction. The actuating component 3 comprises a first actuating component 3a and a second actuating component 3b. The first actuating component 3a and the first locking section 4a are arranged on the same side.The second actuating component 3b and the second locking section 4b are arranged on the same opposite side. The first actuating component 3a is configured to interact with the second locking section 4b. The second actuating component 3b is configured to interact with the first locking section 4a. During the displacement movement of the actuating component 3 relative to the second buckle component 2, the first actuating component 3a and the second actuating component 3b each deform the second locking section 4b and the first locking section 4a away from the locked section 5, in order to release the first locking section 4a and the second locking section 4b from the locked section 5.The interaction of the first actuating component 3a and the second locking section 4b, and the interaction of the second actuating component 3b and the first locking section 4a, results in more reliable engagement and release actuation of the buckle assembly 100. However, the structures of the actuating component and the locking section are not limited to this embodiment. According to another embodiment, for example, the actuating component can comprise one, three, or four actuating components, and the locking section can accordingly comprise one, three, or four locking sections.

[0057] As in Fig. 3, Fig. 4, Fig. 5 to Fig. As shown in Figure 6, the first locking section 4a comprises a first elastic arm 41a and a first locking head 42a connected to the first elastic arm 41a. The first elastic arm 41a is configured to interact with the second actuating component 3b. The first locking head 42a is configured to engage with the locked section 5. The first elastic arm 41a is biased to engage the first locking head 42a with the locked section 5. During a displacement movement of the second actuating component 3b relative to the second buckle component 2, the second actuating component 3b elastically deforms the first elastic arm 41a away from the locked section 5 to release the first locking head 42a from the locked section 5.The second locking section 4b comprises a second elastic arm 41b and a second locking head 42b connected to the second elastic arm 41b. The second elastic arm 41b is configured to interact with the first actuating component 3a. The second locking head 42b is configured to engage with the locked section 5. The second elastic arm 41b is biased to engage the second locking head 42b with the locked section 5. During a displacement movement of the first actuating component 3a relative to the second buckle component 2, the first actuating component 3a elastically deforms the second elastic arm 41b away from the locked section 5 to release the second locking head 42b from the locked section 5.

[0058] Preferably, according to this embodiment, the second actuating component 3b can be configured to push the first elastic arm 41a away from the locked section 5, so that the first elastic arm 41a is elastically deformed, and the first actuating component 3a can be configured to push the second elastic arm 41b away from the locked section 5, so that the second elastic arm 41b is elastically deformed; that is, the force acting on the actuating component 3 and applied by the user can be a thrust force. However, it is not limited to this embodiment. According to another embodiment, for example,The first actuating component can be configured to pull the first elastic arm away from the locked section, thus elastically deforming the first elastic arm. The second actuating component can be configured to pull the second elastic arm away from the locked section, thus elastically deforming the second elastic arm. That is, the force acting on the actuating component and applied by the user can be a tensile force. Therefore, it is understandable that the user can push or pull the actuating component away from the locked section to elastically deform the first and second elastic arms.

[0059] As in Fig. 3, Fig. 4, Fig. 5 to Fig. As shown in Figure 6, a first adjacent section 31a projects from the first actuating component 3a along the lateral direction. A second cooperating section 43b is formed at a free end of the second elastic arm 41b and is configured to interact with the first adjacent section 31a. The first actuating component 3a, through the contact of the first adjacent section 31a and the second cooperating section 43b, elastically deforms the second elastic arm 41b away from the locked section 5 in order to release the second locking head 42b from the locked section 5. A second adjacent section 31b projects from the second actuating component 3b along the lateral direction. A first cooperating section 43a is formed at a free end of the first elastic arm 41a and is configured to interact with the second adjacent section 31b.The second actuating component 3b, through the contact of the second adjacent section 31b and the first cooperating section 43a, elastically deforms the first elastic arm 41a away from the locked section 5 in order to release the first locking head 42a from the locked section 5. Preferably, the first cooperating section 43a can be aligned with the second adjacent section 31b along the lateral direction, and the second cooperating section 43b can be aligned with the first adjacent section 31a along the lateral direction, which makes the contact of the actuating component 3 more precise and the release actuation of the buckle assembly 100 easier.

[0060] As in Fig. 3, Fig. 4, Fig. 5 to Fig. As shown in Figure 6, the first locking head 42a projects laterally from an inner wall of the first elastic arm 41a. The first cooperating section 43a is adjacent to the first locking head 42a. The second locking head 42b projects laterally from an inner wall of the second elastic arm 41b. The second cooperating section 43b is adjacent to the second locking head 42b. Thus, when the first adjacent section 31a and the second adjacent section 31b each push the second cooperating section 43b and the first cooperating section 43a, the first elastic arm 41a and the second elastic arm 41b, respectively, are elastically deformed away from the locked section 5 to rapidly release the first locking head 42a and the second locking head 42b from the locked section 5.Preferably, the first locking head 42a and the first cooperating section 43a can be arranged sequentially along a direction from a mounting end of the first elastic arm 41a to the free end of the first elastic arm 41a, and the second locking head 42b and the second cooperating section 43b can be arranged sequentially along a direction from a mounting end of the second elastic arm 41b to the free end of the second elastic arm 41b. The first cooperating section 43a and the second cooperating section 43b can each be arranged at the free end of the first elastic arm 41a and at the free end of the second elastic arm 41b, respectively, so that the force acting on the actuating component 3 and applied by the user for elastic deformation of the first elastic arm 41a and the second elastic arm 41b can be small.

[0061] In particular, the first cooperating section 43a and the second cooperating section 43b can be arranged at different heights in the top-bottom direction, which in Fig. The arrow direction P shown in Figure 6 can be present, and the first adjacent section 31a and the second adjacent section 31b can be arranged at different heights in the top-bottom direction, such that the contact of the first adjacent section 31a and the second cooperating section 43b, as well as the contact of the second adjacent section 31b and the first cooperating section 43a, are arranged at different heights. This prevents any structural disturbance during the displacement movements of the first actuating component 3a and the second actuating component 3b along the lateral direction and ensures the reliability of the release actuation of the buckle assembly 100. According to this embodiment, the heights of the second adjacent section 31b and the first cooperating section 43a can be higher than the heights of the first adjacent section 31a and the second cooperating section 43a.However, it is not limited to this embodiment.

[0062] Preferably, the first cooperating section 43a can be oriented offset from the second cooperating section 43b along the lateral direction, and the first adjacent section 31a can be oriented offset from the second adjacent section 31b along the lateral direction, so that the occupied space along the top-bottom direction can be reduced and the arrangement of the interior of the buckle assembly 100 is facilitated. According to this embodiment, the first adjacent section 31a and the second cooperating section 43b can be arranged in front of the second adjacent section 31b and the first cooperating section 43a along an extension direction that is in Fig. The arrow direction Q shown in section 5 can be perpendicular to the lateral direction and the joining direction. However, it is not limited to this embodiment.

[0063] It is understandable that, according to another embodiment, if only a single locking section is arranged on one side of the locked section and configured to engage with the locked section, only one actuating component can be arranged on the other side of the locked section opposite the locking section in order to elastically push the locking section away from the locked section so that the locking section can release from the locked section. In other words, the actuating component and the locking section can be arranged on two opposite sides of the locked section in order to push the locking section through the actuating component to release the locking section from the locked section.Alternatively, according to another embodiment, the operating component and the locking section can be arranged on the same side of the locked section in order to pull the locking section through the operating component to release the locking section from the locked section.

[0064] As in Fig. 3, Fig. 4, Fig. 5 to Fig. As shown in Figure 6, the locked section 5 comprises an adjacent structure 51 and a locked structure 52, which is configured to engage with the two locking heads, i.e., the first locking head 42a and the second locking head 42b. The adjacent structure 51 rests against the two locking heads to elastically deform the two elastic arms, i.e., the first elastic arm 41a and the second elastic arm 41b, and to pass the two locking heads, so that the locked structure 52 can engage with the two locking heads during an assembly process of the first buckle component 1 and the second buckle component 2. The actuating component 3 elastically deforms the two elastic arms to release the two locking heads from the locked structure 52 during the displacement movement of the actuating component 3 relative to the second buckle component 2.Preferably, an end section of the adjacent structure 51 can comprise a first inclined section 511 that is inclined relative to the joining direction. Each locking head comprises a second inclined section 421 for interacting with the first inclined section 511. The adjacent structure 51 elastically deforms the two elastic arms through the contact of the first inclined section 511 and the second inclined section 421 of the two locking heads in order to pass the two locking heads, so that the locked structure 52 can engage with the two locking heads during the joining process of the first buckle component 1 and the second buckle component 2. Furthermore, the locked structure 52 can be an undercut, and the two locking heads can engage with the undercut. However, this is not limited to the possibility of engagement.

[0065] As in Fig. 3, Fig. 4 to Fig. As shown in Figure 5, each elastic component 6 is arranged between the second buckle component 2 and a corresponding element, namely the first actuating component 3a or the second actuating component 3b, and is configured to bias the corresponding element (first actuating component 3a or second actuating component 3b) away from the locking section 4, so that the first actuating component 3a and the second actuating component 3b can be elastically reset by the two elastic components 6 when the first actuating component 3a and the second actuating component 3b are released. However, the number of elastic components is not limited to this embodiment. For example, according to another embodiment, if there is only one actuating component, only one elastic component may be present.

[0066] In particular, two C-shaped structures 24 are formed on the second buckle component 2 and are designed to receive the two elastic components 6. The two elastic components 6 are arranged between the first actuating component 3a and the second buckle component 2, and between the second actuating component 3b and the second buckle component 2.

[0067] As in Fig. 3, Fig. 4 to Fig. As shown in Figure 5, a retaining projection 33 protrudes from either the first actuating component 3a or the second actuating component 3b of the actuating component 3. Two retaining blocks 25 are formed on the second buckle component 2 and interact with the two retaining projections 33. The second buckle component 2 blocks the first actuating component 3a and the second actuating component 3b of the actuating component 3 by means of the two retaining blocks 25 and the two retaining projections 33, thus preventing the first actuating component 3a and the second actuating component 3b of the actuating component 3 from detaching from the second buckle component 2. However, the number of retaining blocks is not limited to this embodiment. For example, according to another embodiment, if there is only one actuating component, only one retaining block may be present.

[0068] As in Fig. 3, Fig. 4 to Fig. As shown in Figure 5, the locking section 4 can preferably be detachably connected to the second buckle component 2. Such a device thus allows for easy replacement of the locking section 4 or the second buckle component 2 in case of damage and simplifies the manufacturing process of the buckle assembly 100. In particular, the locking section 4 further comprises an engagement clip 44. An engagement structure is formed on the second buckle component 2 and configured to detachably engage with the engagement clip 44. The engagement clip 44 is fixedly connected to the attachment end of the first elastic arm 41a and the attachment end of the second elastic arm 41b and is detachably embedded in the engagement structure. Furthermore, the engagement structure particularly comprises two spaced-apart engagement rods 22. The engagement clip 44 is embedded between the two engagement rods 22.Each engagement bar 22 comprises an upper retention section 221 and a lower retention section 222. The upper retention section 221 and the lower retention section 222 are configured to prevent movement of the engagement clip 44. The engagement clip 44 is positioned between the upper retention section 221 and the lower retention section 222 when the engagement clip 44 is detachably embedded in the engagement structure. Preferably, the engagement clip 44 may comprise two stepped structures 441 for engaging with the two lower retention sections 222 when the engagement clip 44 is detachably embedded in the engagement structure. Consequently, such a configuration can prevent unintentional release of the locking section 4 and the two lower retention sections 222 and allow for adequate use of the interior space of the second buckle component 2.Preferably, a clearance space 9 can be formed between the two engagement rods 22, allowing the two elastic arms to move. The two elastic arms protrude from the clearance space 9 and can be elastically deformed to move within the clearance space 9.

[0069] However, the number of engagement rods and stepped structures is not limited to this embodiment. According to another embodiment, for example, the engagement structure can comprise one, three, or more engagement rods, and the engagement clamp can accordingly comprise one, three, or more stepped structures.

[0070] As in Fig. 3, Fig. 4, Fig. 5 to Fig. As shown in Figure 6, the buckle assembly 100 further comprises a first magnetic structure 7 and a second magnetic structure 8. The first magnetic structure 7 is arranged on the first buckle component 1. The second magnetic structure 8 is arranged on the second buckle component 2. The first magnetic structure 7 and the second magnetic structure 8 can magnetically attract each other during the joining process of the first buckle component 1 and the second buckle component 2, thereby accelerating the joining process.On the other hand, even when the locking section 4 and the locked section 5 are separated, the first buckle component 1 and the second buckle component 2 can be prevented from moving away from each other due to the magnetic attraction of the first magnet structure 7 and the second magnet structure 8, thus ensuring the safety of the buckle assembly 100. However, it is not limited to this embodiment. According to another embodiment, for example, the first magnet structure and the second magnet structure can be configured to magnetically repel each other during the assembly process of the first buckle component and the second buckle component, thereby accelerating the release actuation of the buckle assembly 100.

[0071] In particular, a first embedding chamber 11 is formed on the first buckle component 1. A second embedding chamber 23 is formed on the second buckle component 2. The first magnetic structure 7 is embedded in the first embedding chamber 11. The second magnetic structure 8 is embedded in the second embedding chamber 23. Preferably, the first embedding chamber 11 can be aligned with the second embedding chamber 23 along the joining direction to enhance the magnetic attraction between the first magnetic structure 7 and the second magnetic structure 8. However, this embodiment is not limited to this configuration. In particular, the second embedding chamber 23 can be aligned with a space between the first locking head 42a and the second locking head 42b along the joining direction, as shown in [Figure]. Fig. 6 shown, so that adequate use of the space of the buckle assembly 100 is made possible, thereby making the structure of the buckle assembly 100 more compact.

[0072] As in Fig. 5 and Fig. As shown in Figure 6, an actuation principle of the buckle assembly 100 is described as follows. When the buckle assembly 100 is released, the first actuating component 3a and the second actuating component 3b can be pressed or actuated by the contact of the first contacting section 31a and the second cooperating section 43b, respectively, to elastically deform the second elastic arm 41b and the first elastic arm 41a, respectively, so that the second locking head 42b and the first locking head 42a release from the locked section 5. Once the second locking head 42b and the first locking head 42a have released from the locked section 5, i.e.,When the buckle assembly 100 is in a release state, the first buckle component 1 can be separated from the second buckle component 2, thus placing the buckle assembly 100 in a separation state. Subsequently, when the first actuating component 3a and the second actuating component 3b are released, the two elastic components 6 drive the first actuating component 3a and the second actuating component 3b to return to their original position.

[0073] When the first buckle component 1 engages with the second buckle component 2, the locked section 5 can be inserted through the adjacent structure 51 into the joining hole 21 to abut against the first locking head 42a and the second locking head 42b in order to elastically deform the first elastic arm 41a and the second elastic arm 41b so that the adjacent structure 51 can pass the first locking head 42a and the second locking head 42b. When the adjacent structure 51 passes the first locking head 42a and the second locking head 42b to align the locked structure 52 with the first locking head 42a and the second locking head 42b, the first locking head 42a and the second locking head 42b can be driven by the first elastic arm 41a and the second elastic arm 41b to engage with the locked structure 52.

[0074] It will be on Fig. 7, Fig. 8, Fig. 9 to Fig. 10 referenced. Fig. Figure 7 shows a schematic view of a buckle arrangement 100' according to a second embodiment of the present invention. Fig. Figure 8 shows an exploded view of the buckle arrangement 100' according to the second embodiment of the present invention. Fig. 9 and Fig. Figure 10 shows views of the buckle arrangement 100' in various states according to the second embodiment of the present invention. As in Fig. 7, Fig. 8, Fig. 9 to Fig. As shown in Figure 10, the buckle assembly 100' comprises the first buckle component 1, a second buckle component 2', the actuating component 3, the two elastic components 6, the first magnet structure 7, and the second magnet structure 8. The structures of the first buckle component 1, the actuating component 3, the elastic component 6, the first magnet structure 7, and the second magnet structure 8 of this embodiment are similar to those of the first embodiment. For the sake of simplicity, a detailed description is omitted here. The second buckle component 2' comprises a locking section 4'. The locking section 4' comprises a first locking section 4a' and a second locking section 4b'.The first locking section 4a' and the second locking section 4b' are arranged on the two opposite sides of the locked section 5 of the first buckle component 1 and clamp the locked section 5 along the lateral direction that is in . Fig. 9 and Fig. The direction of the arrow shown in Figure 10 can be M1 or M2. The first locking section 4a' and the first actuating component 3a of the actuating component 3 are arranged on the same side. The first locking section 4a' is configured to interact with the second actuating component 3b of the actuating component 3. The second locking section 4b' and the second actuating component 3b of the actuating component 3 are arranged on the same other side. The second locking section 4b' is configured to interact with the first actuating component 3a of the actuating component 3.

[0075] In particular, the first locking section 4a' comprises a first pivot arm 41a' and a first locking head 42a'. The first locking head 42a' is configured to engage with the locked section 5. The first pivot arm 41a' is pivotally connected to the second buckle component 2' by a first pivotable section 411a'. A first cooperating section 43a' is formed on the first pivot arm 41a' and configured to cooperate with the second adjacent section 31b of the second actuating component 3b. The first cooperating section 43a' is aligned with the second adjacent section 31b along the lateral direction. The first locking head 42a' is connected to the first pivot arm 41a' and projects from an inner wall of the first pivot arm 41a' along the lateral direction.

[0076] The second locking section 4b' comprises a second pivot arm 41b' and a second locking head 42b'. The second locking head 42b' is configured to engage with the locked section 5. The second pivot arm 41b' is pivotally connected to the second buckle component 2' by a second pivotable section 411b'. A second cooperating section 43b' is formed on the second pivot arm 41b' and configured to interact with the first adjacent section 31a of the first actuating component 3a. The second cooperating section 43b' is aligned with the first adjacent section 31a along the lateral direction. The second locking head 42b' is connected to the second pivot arm 41b' and projects from an inner wall of the second pivot arm 41b' along the lateral direction.

[0077] According to this embodiment, the first interacting section 43a' and the second interacting section 43b' can be arranged at different heights along the top-bottom direction, and the first interacting section 43a' can be oriented offset from the second interacting section 43b' along the lateral direction. This prevents any structural disturbance during release actuation of the buckle assembly 100', thus ensuring the reliability of the release actuation of the buckle assembly 100' and allowing for adequate use of the interior space of the buckle assembly 100'. Preferably, according to this embodiment, the first pivotable section 411a' and the second pivotable section 411b' can be two recess structures, such that two pivot axes of the second buckle component 2' can pass through these recess structures.

[0078] Furthermore, the first locking section 4a' also comprises a first return component 44a'. The second locking section 4b' also comprises a second return component 44b'. The first return component 44a' is arranged between the first pivot arm 41a' and the second buckle component 2' and is configured to bias the first pivot arm 41a' for rotation, so that the first locking head 42a' engages with the locked section 5 along the lateral direction. The second return component 44b' is arranged between the second pivot arm 41b' and the second buckle component 2' and is configured to bias the second pivot arm 41b' for rotation, so that the second locking head 42b' engages with the locked section 5 along the lateral direction. Preferably, according to the embodiment, the first return component 44a' and the second return component 44b' can be two compression springs.However, it is not limited to this. For example, in another embodiment, the first restoring component and the second restoring component can be two torsion springs.

[0079] When the buckle assembly 100' is released, the first actuating component 3a and the second actuating component 3b of the actuating component 3 can be pressed or actuated by the contact of the first contacting section 31a of the first actuating component 3a and the second cooperating section 43b' of the second locking section 4b' or by the contact of the second contacting section 31b of the second actuating component 3b and the first cooperating section 43a' of the first locking arm 4a', respectively, to drive the second rotary arm 41b' and the first rotary arm 41a', so that the second return component 44b' and the first return component 44a' are elastically pressed to release the second locking head 42b' and the first locking head 42a' from the locked section 5. When the second locking head 42b' and the first locking head 42a' have detached from the locked section 5, i.e.When the buckle assembly 100' is in the release state, the first buckle component 1 can be separated from the second buckle component 2' to bring the buckle assembly 100' into a separation state. Thereafter, when the first actuating component 3a and the second actuating component 3b are released, the two elastic components 6 drive the first actuating component 3a and the second actuating component 3b to return to their original position.

[0080] When the first buckle component 1 engages with the second buckle component 2', the locked section 5 can be inserted through the adjacent structure 51 into an assembly hole of the second buckle component 2' to abut against the first locking head 42a' and the second locking head 42b', causing the first pivot arm 41a' and the second pivot arm 41b' to rotate in order to elastically press the first return component 44a' and the second return component 44b', so that the adjacent structure 51 can pass the first locking head 42a' and the second locking head 42b'.When the adjacent structure 51 passes the first locking head 42a' and the second locking head 42b' to align the locked structure 52 with the first locking head 42a' and the second locking head 42b', the first locking head 42a' and the second locking head 42b' can be driven by the first reset component 44a' and the second reset component 44b' to engage with the locked structure 52.

[0081] It is understandable that, according to another embodiment, if there is only one locking section arranged on one side of the locked section and configured to engage with the locked section, only one actuating component can be arranged on the opposite side of the locked section, opposite the locking section, to elastically push the locking section away from the locked section, thus releasing the locking section from the locked section. In other words, the actuating component and the locking section can be arranged on two opposite sides of the locked section to push the locking section through the actuating component, releasing the locking section from the locked section.Alternatively, according to another embodiment, the actuating component and the locking section can be arranged on the same side of the locked section in order to pull the locking section through the actuating component to release the locking section from the locked section.

[0082] It will be on Fig. 11, Fig. 12, Fig. 13, Fig. 14 to Fig. 15 referenced. Fig. Figure 11 shows a schematic view of a buckle arrangement 100'' according to a third embodiment of the present invention. Fig. Figure 12 shows a partial view of the buckle arrangement 100'' according to the third embodiment of the present invention. Fig. Figure 13 shows an exploded view of the buckle arrangement 100'' according to the third embodiment of the present invention. Fig. 14 and Fig. Figure 15 shows views of the buckle arrangement 100'' in various states according to the third embodiment of the present invention. As in Fig. 11, Fig. 12, Fig. 13, Fig. 14 to Fig. As shown in Figure 15, the buckle assembly 100'' comprises the first buckle component 1, a second buckle component 2'', an actuating component 3'', an elastic component 6'', the first magnet structure 7, and the second magnet structure 8. The structures of the first buckle component 1, the first magnet structure 7, and the second magnet structure 8 of this embodiment are similar to those of the first embodiment. For the sake of simplicity, a detailed description is omitted here. The second buckle component 2'' comprises a locking section 4''. The locking section 4'' comprises a first locking section 4a'' and a second locking section 4b''. The first locking section 4a'' and the second locking section 4b'' are arranged on the two opposite sides of the locked section 5 of the first buckle component 1 and clamp the locked section 5 along the lateral direction that is shown in Figure 15. Fig. 14 and Fig. The direction of arrow M1 or M2 shown in Figure 15 can be the actuating component. The actuating component 3'' is exposed by a lateral wall of the second buckle component 2'' and is displaceable relative to the second buckle component 2'' along the direction of extension shown in Figure 15. Fig. 14 and Fig. The direction of arrow Q shown in Figure 15 can be [not specified]. A first adjacent section 31a'' and a second adjacent section 31b'' project from the actuating component 3" along the direction of extension. The first locking section 4a'' and the second adjacent section 31b'' are arranged on the same side and configured to interact with each other. The second locking section 4b'' and the first adjacent section 31a'' are arranged on the same other side and configured to interact with each other. The elastic component 6" is arranged between the actuating component 3" and the second buckle component 2".

[0083] In particular, the first locking section 4a'' comprises a first pivot arm 41a'' and a first locking head 42a''. The first locking head 42a'' is configured to engage with the locked section 5. The first pivot arm 41a'' is pivotably connected to the second buckle component 2" by a first pivotable section 411a''. A first cooperating section 43a'' is formed on the first pivot arm 41a'' and configured to interact with the second adjacent section 31b''. The first cooperating section 43a'' is aligned with the second adjacent section 31b'' along its extension direction. The first locking head 42a'' is connected to the first pivot arm 41a'' and projects from an inner wall of the first pivot arm 41a'' along the lateral direction. The second locking section 4b'' comprises a second pivot arm 41b'' and a second locking head 42b''.The second locking head 42b'' is configured to engage with the locked section 5. The second pivot arm 41b'' is pivotably connected to the second buckle component 2'' by a second pivotable section 411b''. A second cooperating section 43b'' is formed on the second pivot arm 41b'' and configured to interact with the first adjacent section 31a''. The second cooperating section 43b'' is aligned with the first adjacent section 31a'' along its extension direction. The second locking head 42b'' is connected to the second pivot arm 41b'' and projects from an inner wall of the second pivot arm 41b'' along the lateral direction. Preferably, according to the embodiment, the first pivotable section 411a'' and the second pivotable section 411b'' can be two recess structures, such that two pivot axes can each pass through the recess structures.

[0084] Furthermore, the first locking section 4a'' comprises a first return component 44a''. The second locking section 4b'' comprises a second return component 44b''. The first return component 44a'' is arranged between the first pivot arm 41a'' and the second buckle component 2" and is configured to pre-tension the first pivot arm 41a'' to rotate in order to engage the first locking head 42a'' with the locked section 5 along the lateral direction. The second return component 44b'' is arranged between the second pivot arm 41b'' and the second buckle component 2" and is configured to pre-tension the second pivot arm 41b'' to rotate in order to engage the second locking head 42b'' with the locked section 5 along the lateral direction. Preferably, according to this embodiment, the first return component 44a'' and the second return component 44b'' can be two compression springs.However, it is not limited to this embodiment. For example, according to another embodiment, the first return component and the second return component can be two torsion springs.

[0085] When the buckle assembly 100" is released, the actuating component 3" can be pressed or actuated by the contact of the second contacting section 31b'' and the first cooperating section 43a'' of the first locking section 4a'' or by the contact of the first contacting section 31a'' and the second cooperating section 43b'' of the second locking section 4b'' to the respective drives of the first pivot arm 41a'' and the second pivot arm 41b'' in order to elastically press the first return component 44a" and the second return component 44b'' so that the first locking head 42a" and the second locking head 42b'' release from the locked section 5. Once the first locking head 42a'' and the second locking head 42b'' have released from the locked section 5, e.g.,When the buckle assembly 100" is in the release state, the first buckle component 1 can be separated from the second buckle component 2" to bring the buckle assembly 100" into a separation state. Subsequently, when the actuating component 3" is released, the elastic component 6 drives the actuating component 3" to return to its original position.

[0086] When the first buckle component 1 engages with the second buckle component 2'', the locked section 5 can be inserted into an assembly hole of the second buckle component 2'' to bear against the first locking head 42a'' and the second locking head 42b'' through the adjacent structure 51, so that the first pivot arm 41a'' and the second pivot arm 41b'' are driven to rotate to elastically press the first return component 44a'' and the second return component 44b'', so that the adjacent structure 51 can pass the first locking head 42a'' and the second locking head 42b''.When the adjacent structure 51 passes the first locking head 42a" and the second locking head 41b" to align the locked structure 52 with the first locking head 42a" and the second locking head 42b" the first locking head 42a" and the second locking head 42b" can be driven by the first reset component 44a" and the second reset component 44b" to engage with the locked structure 52.

[0087] It is understandable that, according to another embodiment, if there is only one locking section arranged on one side of the locked section and configured to engage with the locked section, only one adjacent section can be arranged to push the rotary arm for rotation, so that the return component is elastically deformed to release the locking section from the locked section. Alternatively, according to another embodiment, the actuating component can be configured to push the rotary arm for rotation in order to release the locking section from the locked section.

[0088] It will be on Fig. 17, Fig. 18, Fig. 19 to Fig. 20 referenced. Fig. Figure 17 shows a partial view of the buckle arrangement 100''' according to the fourth embodiment of the present invention. Fig. Figure 18 shows an exploded view of the buckle arrangement 100''' according to the fourth embodiment of the present invention. Fig. 19 and Fig. Figure 20 shows views of the buckle arrangement 100''' in various states according to the fourth embodiment of the present invention. As in Fig. 17, Fig. 18, Fig. 19 to Fig. As shown in Figure 20, the buckle assembly 100''' comprises the first buckle component 1, a second buckle component 2''', an actuating component 3''', an elastic component (not shown in the drawings), a first magnetic structure (not shown in the drawings), and the second magnetic structure 8. The structures of the first buckle component 1, the first magnetic structure, and the second magnetic structure 8 according to this embodiment are similar to those of the first embodiment. For the sake of simplicity, a detailed description is omitted here. The second buckle component 2''' comprises a locking section 4'''. The locking section 4''' comprises a first locking section 4a''' and a second locking section 4b'''.The first locking section 4a''' and the second locking section 4b'" are arranged on the two opposite sides of the locked section 5 of the first buckle component 1 and clamp the locked section 5 along the lateral direction that is in . Fig. The direction of the arrow shown in Figure 17 can be M1 or M2. The actuating component 3'" is exposed from a front wall of the second buckle component 2"' and is displaceable relative to the second buckle component 2"' along the merging direction shown in Figure 17. Fig.The direction of arrow P shown in Figure 17 can be the same. A first adjacent section 31a'" and a second adjacent section 31b'" project from the actuating component 3"' along the assembly direction. The first locking section 4a''' and the second adjacent section 31b'" are arranged on the same side and configured to interact with each other. The second locking section 4b"' and the first adjacent section 31a"' are arranged on the same other side and configured to interact with each other. The elastic component is arranged between the actuating component 3'" and the second buckle component 2'".

[0089] In particular, the first locking section 4a"' comprises a first pivot arm 41a'" and a first locking head 42a'". The first locking head 42a'" is configured to engage with the locked section 5. The first pivot arm 41a'" is pivotally connected to the second buckle component 2'" by a first pivotable section 411a"'. A first cooperating section 43a'" is formed on the first pivot arm 41a''' and configured to cooperate with the second adjacent section 31b'". The first cooperating section 43a'" is aligned with the second adjacent section 31b"' along the assembly direction. The first locking head 42a'" is connected to the first pivot arm 41a'" and projects from an inner wall of the first pivot arm 41a"' along the lateral direction. The second locking section 4b'' comprises a second pivot arm 41b'' and a second locking head 42b''.The second locking head 42b"' is configured to engage with the locked section 5. The second pivot arm 41b'" is pivotally connected to the second buckle component 2"' by a second pivotable section 411b"'. A second cooperating section 43b'" is formed on the second pivot arm 41b"' and configured to interact with the first adjacent section 31a"'. The second cooperating section 43b"' is aligned with the first adjacent section 31a'" along the assembly direction. The second locking head 42b"' is connected to the second pivot arm 41b"' and projects from an inner wall of the second pivot arm 41b"' along the lateral direction. Preferably, according to this embodiment, the first pivotable section 411a'" and the second pivotable section 411b'' can be two pivot axes for passing through two recess structures formed on the second buckle component 2'".

[0090] Furthermore, the first locking section 4a'" comprises a first return component 44a"'. The second locking section 4b"' further comprises a second return component 44b"'. The first return component 44a"' is arranged between the first pivot arm 41a"' and the second buckle component 2"' and is configured to pre-tension the first pivot arm 41a'" to rotate in order to engage the first locking head 42a"' with the locked section 5 along the lateral direction. The second return component 44b"' is arranged between the second pivot arm 41b"' and the second buckle component 2"' and is configured to pre-tension the second pivot arm 41b'" to rotate in order to engage the second locking head 42b'" with the locked section 5.

[0091] When the buckle assembly 100"' is released, the actuating component 3"' can be pressed or actuated by the contact of the second contacting section 31b"' and the first cooperating section 43a"' of the first locking section 4a'" and the contact of the first contacting section 31a"' and the second cooperating section 43b"' of the second locking section 4b'" to respectively drive the first rotary arm 41a'" and the second rotary arm 41b"', so that the first return component 44a"' and the second return component 44b"' are elastically pressed to release the first locking head 42a'" and the second locking head 42b'" from the locked section 5. When the first locking head 42a'" and the second locking head 42b'' have detached from the locked section 5, i.e.When the buckle assembly 100"' is in a release state, the first buckle component 1 can detach from the second buckle component 2'" to bring the buckle assembly 100"' into a separation state. Subsequently, when the actuating component 3'" is released, the elastic component drives the actuating component 3"' to return to its original position.

[0092] When the first buckle component 1 engages with the second buckle component 2''', the locked section 5 can be inserted into an assembly hole of the second buckle component 2''' to bear against the first locking head 42a''' and the second locking head 42b''' through the adjacent structure 51, so that the first pivot arm 41a''' and the second pivot arm 41b''' are driven to rotate to elastically press the first return component 44a''' and the second return component 44b''' to allow the adjacent structure 51 to pass the first locking head 42a''' and the second locking head 42b'''.When the adjacent structure 51 passes the first locking head 42a'" and the second locking head 42b"' to align the locked structure 52 with the first locking head 42a"' and the second locking head 42b'"", the first locking head 42a'" and the second locking head 42b"" can be driven by the first reset component 44a"' and the second reset component 44b"' to engage with the locked structure 52.

[0093] It is understandable that, according to another embodiment, if there is only one locking section arranged on one side of the locked section and configured to engage with the locked section, only one adjacent section can be arranged to push the rotary arm for rotation, so that the return component is elastically deformed to release the locking section from the locked section. Alternatively, according to another embodiment, the actuating component can be configured to push the rotary arm for rotation in order to release the locking section from the locked section.

[0094] In contrast to the prior art, according to the present invention, the actuating component is arranged on the second buckle component, comprising the locking section that interacts with the locked section of the first buckle component. The actuating component drives the locking section to release it from the locked section when the actuating component is actuated. Therefore, the present invention offers the advantages of a simple structure as well as ease of use and simplified operation.

[0095] The person skilled in the art will readily recognize that numerous modifications and changes to the apparatus and the method are possible while maintaining the teaching of the invention. Accordingly, the above disclosure should be interpreted as being limited only by the provisions and boundaries of the appended claims.

Claims

[1] A buckle arrangement (100, 100'), characterized by , that the buckle arrangement (100, 100') includes: a first buckle component (1) comprising a locked section (5); a second buckle component (2, 2') comprising a locking section (4, 4') designed to interact with the locked section (5), wherein the locking section (4, 4') engages with the locked section (5) along a lateral direction of the buckle assembly (100, 100') when the second buckle component (2, 2') is joined with the first buckle component (1) along an assembly direction; and an actuating component (3) which is partially embedded in the second buckle component (2, 2') and partially exposed from the second buckle component (2, 2'), wherein the actuating component (3) is configured to interact with the locking section (4, 4') and to be displaceable relative to the second buckle component (2, 2') along the lateral direction, wherein the actuating component (3) drives the locking section (4, 4') such that during a displacement movement of the actuating component (3) relative to the second buckle component (2, 2') the locking section (4, 4') moves away from the locked section (5) so that the locking section (4, 4') releases from the locked section (5). [2] Buckle arrangement (100, 100') according to claim 1, characterized by , that the locked section (5) is arranged on a front surface of the first buckle component (1). [3] Buckle arrangement (100, 100') according to claim 1 or 2, characterized by, that the locking section (4, 4') is an elastic structure; and the actuating component (3) elastically deforms the locking section (4, 4') so that the locking section (4, 4') is released from the locked section (5) during the displacement movement of the actuating component (3) relative to the second buckle component (2, 2'). [4] Buckle arrangement (100, 100') according to claim 3, characterized by , that the locking section (4) comprises an elastic arm (41a, 41b) and a locking head (42a, 42b) connected to the elastic arm (41a, 41b), wherein the elastic arm (41a, 41b) is configured to interact with the actuating component (3), wherein the locking head (42a, 42b) is configured to engage with the locked section (5), wherein the elastic arm (41a, 41b) is pre-tensioned to engage the locking head (42a, 42b) with the locked section (5), and wherein the actuating component (3) elastically deforms the elastic arm (41a, 41b) so that the locking head (42a, 42b) is released from the locked section (5) during the displacement movement of the actuating component (3) relative to the second buckle component (2). [5] Buckle arrangement (100, 100') according to claim 4, characterized by , that the actuating component (3) is displaceable relative to the second buckle component (2) along the lateral direction; an adjacent section (31a, 31b) protrudes from the actuating component (3) along the lateral direction; a cooperating section (43a, 43b) is formed at a free end of the elastic arm (41a, 41b) for cooperating with the adjacent section (31a, 31b); and the actuating component (3) is pressed against the cooperating section (43a, 43b) by the adjacent section (31a, 31b) to elastically deform the elastic arm (41a, 41b) so that the locking head (42a, 42b) is released from the locked section (5) during the displacement movement of the actuating component (3) relative to the second buckle component (2). [6] Buckle arrangement (100, 100') according to claim 5, characterized by , that the cooperating section (43a, 43b) is aligned with the adjacent section (31a, 31b) along the lateral direction. [7] Buckle arrangement (100, 100') according to claim 6, characterized by , that the locking head (42a, 42b) projects from an inner wall of the elastic arm (41a, 41b) along the lateral direction and the cooperating section (43a, 43b) is adjacent to the locking head (42a, 42b). [8] Buckle arrangement (100) according to claim 7, characterized by, that the locking head (42a, 42b) and the cooperating section (43a, 43b) are arranged sequentially along a direction from a fixed end of the elastic arm (41a, 41b) to the free end of the elastic arm (41a, 41b). [9] Buckle arrangement (100, 100', 100'') according to claim 4, characterized by , that the locking section (4, 4') is detachably connected to the second buckle component (2, 2'). [10] Buckle arrangement (100, 100') according to claim 9, characterized by , that the locking section (4) further comprises an engagement clamp (44) which is firmly connected to a fastening end of the elastic arm (41a, 41b); an engagement structure is formed on the second buckle component (2) and is designed for releasable engagement with the engagement clip (44); and the intervention clamp (44) is detachably embedded in the intervention structure. [11] Buckle arrangement (100, 100') according to claim 10, characterized by , that the intervention structure comprises at least two spaced-apart intervention rods (22); the engagement clamp (44) is embedded between the at least two engagement rods (22); the at least two engagement rods (22) each comprise an upper retention section (221) and a lower retention section (222); the upper retention section (221) and the lower retention section (222) are designed to prevent movement of the engagement clamp (44); and the engagement clamp (44) is arranged between the upper retention section (221) and the lower retention section (222) when the engagement clamp (44) is detachably embedded in the engagement structure. [12] Buckle arrangement (100, 100') according to claim 11, characterized by, that the engagement clamp (44) comprises a step-shaped structure (441) which engages with the lower retention section (222) when the engagement clamp (44) is detachably embedded in the engagement structure. [13] Buckle arrangement (100, 100') according to claim 11, characterized by , that a clearance space (9) is formed between the at least two engagement rods (22) and allows the elastic arm (41a, 41b) to move. [14] Buckle arrangement (100, 100') according to claim 4, characterized by , that the interlocked section (5) comprises an adjacent structure (51) and an interlocked structure (52); the adjacent structure (51) rests against the locking head (42a, 42b) in order to elastically deform the elastic arm (41a, 41b) during an assembly process of the first buckle component (1) and the second buckle component (2); the interlocked structure (52) is set up to engage with the interlocking head (42a, 42b); and the actuating component (3) elastically deforms the elastic arm (41a, 41b) to release the locking head (42a, 42b) from the locked structure (52) during the displacement movement of the actuating component (3) relative to the second buckle component (2). [15] Buckle arrangement (100, 100') according to claim 14, characterized by , that an end section of the adjacent structure (51) comprises a first inclined section (511) which is inclined relative to the joining direction, the locking head (42a, 42b) comprises a second inclined section (421) for interaction with the first inclined section (511), and the adjoining structure (51) elastically deforms the elastic arm (41a, 41b) by the contact of the first inclined section (511) and the second inclined section (421) in order to pass the locking head (42a, 42b) so that the locked structure (52) engages with the locking head (42a, 42b) during the joining process of the first buckle component (1) and the second buckle component (2'). [16] The buckle arrangement (100, 100') according to claim 14, characterized by , that the locked structure (52) is an undercut and the locking head (42a, 42b) is designed to engage with the undercut.