SELF-LOCKING HOOK TO AVOID UNEXPECTED OPENING

Abstract

What is disclosed in the present invention is a self-locking hook to avoid unexpected opening. When a press-button is pressed down, a spring is compressed, a pressing arm and an axle pin are completely inserted into an insertion hole, at this point, the axle pin leaves a transverse clipping position and forms an openable state with a support arm, in which they can rotate along the curved slide rail in a mounting slot. An elastic arm is mounted inside the mounting slot and is pressed upon the bottom surface of the support arm to push a lock hook and maintain the locking state between a lock arm and a hook arm. The lock hook be rotated only when the press-button is pressed down. The present invention can avoid direct opening of the lock hook under a pressing force, thus preventing unexpected opening and loosening of the hook.

Claims

1. A self-locking hook to avoid unexpected release and opening, including a hook base and a lock hook, the lock hook is assembled with the hook base to form a relatively rotational structure through a rotation shaft; the head part of the hook base is provided with an opening, a hook arm is formed on one side of the opening, a mounting slot is located in the hook base, a -shaped transverse clipping position with a curved slide rail is disposed on both sides inside the mounting slot; the lock hook is an L-shaped bending structure, comprising a lock arm and a support arm, the support arm is embedded in the mounting slot of the hook base, the lock arm protrudes out toward the opening of the hook base, characterized in that: the structure also includes a press-button and an elastic arm, the front end of the press-button is extended with a pressing arm, the pressing arm is located inside the mounting slot, the press-button extends out of the hook base from the rear slot on the rear end of the mounting slot; an insertion hole matching the pressing arm and extending inward is configured along the rear end of the support arm, a spring is disposed inside the insertion hole, the spring is pressed upon the front end of the pressing arm, when the press-button is pressed down, the spring is compressed, and the pressing arm and the axle pin are completely inserted into the insertion hole, at this point, the axle pin leaves the transverse clipping position and forms an openable state with the support arm, in which they can rotate along the curved slide rail in the mounting slot; the elastic arm is mounted inside the mounting slot and pressed upon the bottom surface of the support arm to push the lock hook to maintain the locked state between the lock arm and the hook arm.

2. The self-locking hook to avoid unexpected release and opening defined in claim 1, characterized in that: an axle pin is disposed on both sides of said pressing arm, and a long opening structure matching the axle pin is disposed on both sides of the insertion hole, the axle pin is stuck in the opening structure. In addition, the axle pin protrudes on both sides of the pressing arm, and cooperates with the -shaped transverse clipping position and curved slide rail on both sides inside the mounting slot, forming a clip structure that can be opened by the two-stage action of pressing and rotation, so that when the press-button is released, the lock hook bounces back automatically, and the axle pin springs back to the -shaped transverse clipping position, implementing the self-locking function.

3. The self-locking hook to avoid unexpected release and opening defined in claim 1, characterized in that: the entire lock hook is an L-shaped structure, the bent part of the lock hook is disposed with a shaft hole, a rotation shaft is put through the shaft hole and connected to the fixing hole on the hook base.

4. The self-locking hook to avoid unexpected release and opening defined in claim 1, characterized in that: said elastic arm is connected to a decor cap, the decor cap is embedded in the slot mouth on the front end of the mounting slot to cover the mounting slot from the front end, and the elastic arm extends upward in an arched form from the lower side of the support arm to press upon the bottom surface of the support arm; or the elastic arm can be replaced by a metal reed or a spring to provide the source of elastic force against the support arm.

5. The self-locking hook to avoid unexpected release and opening defined in claim 4, characterized in that: a positioning hole is disposed on the hook base at a position close to the front edge, and a clip is disposed on both sides of the decor cap, by locking the clip inside the positioning hole, the decor cap and the hook base are assembled and fixed together.

6. The self-locking hook to avoid unexpected release and opening defined in claim 1, characterized in that: the head part of the hook arm is disposed with a hook head, the head part of the hook head is disposed with a lock head, the lock head and the hook head form an inverted T-shaped structure; the end part of the lock arm is disposed with a lock groove in a shape to match the hook head and the lock head, when the lock arm and the hook arm are engaged, the hook head and the lock head are caught inside the lock groove, forming a closed force-bearing structure with the hook arm, which can effectively share the stress on the hook arm, and provide the hook body with greater tensile force bearing capacity.

7. The self-locking hook to avoid unexpected release and opening defined in claim 1, characterized in that: The hook base, the lock hook and the press-button can be made of metallic or plastic materials; the pressing arm and the press-button can be an integral or separate structure; the decor cap and the elastic arm are an integral structure, and a separate structure of decor cap and elastic arm can be used as required, which is made of metallic or plastic materials.

8. The self-locking hook to avoid unexpected release and opening defined in claim 1, characterized in that: the tail end of the hook base is disposed with a connecting head, the connecting head and the hook base are formed in an integral structure, a swivel connecting loop is connected to the connecting head, and the connecting loop is locked on the connecting head through a clamping ring.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0015] FIG. 1 is an overall structural view of the present invention;

[0016] FIG. 2 is an overall structural view of the present invention from another viewing angle;

[0017] FIG. 3 is an exploded structural view of the present invention;

[0018] FIG. 4 is an exploded structural view of the present invention from another viewing angle;

[0019] FIG. 5 is a sectional view of the present invention from the locked state to the unlocked state.

[0020] 1 hook base [0021] 11 hook arm [0022] 12 hook head [0023] 13 lock head [0024] 14 mounting slot [0025] 141 transverse clipping position [0026] 142 curved slide rail [0027] 15 rear slot [0028] 16 positioning hole [0029] 17 connecting head [0030] 2 lock hook [0031] 21 lock arm [0032] 22 support arm [0033] 23 shaft hole [0034] 24 lock groove [0035] 25 insertion hole [0036] 3 press-button [0037] 31 pressing arm [0038] 32 axle pin [0039] 4 spring, [0040] 5 decor cap [0041] 51 elastic arm, [0042] 6 is rotation shaft, and [0043] 7 is connecting loop, [0044] a is the action path.

DETAILED DESCRIPTION OF THE INVENTION

[0045] In the present invention, as depicted in FIGS. 1 to 5, the self-locking hook to avoid unexpected opening comprises a hook base 1 and a lock hook 2. Said lock hook 2 is assembled with the hook base 1 to form a relatively rotational structure through a rotation shaft 6. The head part of the hook base 1 is disposed with an opening. One side of the opening is formed with a hook arm 11. The lock hook 2 is a bent structure including a lock arm 21 and a support arm 22. The support arm 22 is embedded inside the mounting slot 14 of the hook base 1. The lock arm 21 extends out toward the opening of the hook base 1. The structure also includes a press-button 3 and an elastic arm 51. The front end of the press-button 3 is extended with a pressing arm 31. The pressing arm 31 is located inside the mounting slot 14. The press-button 3 extends out of the hook base 1 from the rear slot 15 on the rear end of the mounting slot 14, so that it can be pressed down. An insertion hole 25 matching the pressing arm 31 and extending inward is configured along the rear end of the support arm 22. A spring 4 is disposed inside the insertion hole 25. The spring 4 is pressed upon the front end of the pressing arm 31. When the press-button 3 is pressed down (see solid short arrow in FIG. 5), the spring 4 is compressed, the pressing arm 31 is completely inserted into the insertion hole 25, meanwhile, the axle pin 32 leaves the transverse clipping position 141 inside the mounting slot 14, so that the support arm 22 forms a linked rotational combination. The lock hook 2 can be pushed by the pressing arm 31 (see hollow arrow in FIG. 5) to rotate along the internal curved slide rail 142, so that the lock arm 21 rotates inward to open the hook. The elastic arm 51 is mounted inside the mounting slot 14 and pressed upon the bottom surface of the support arm 22 to push the lock hook 2 to maintain the locked state between the lock arm 21 and the hook arm 11. Once the press-button 3 is released, the press-button 3 and the axle pin 32 are squeezed by the elastic arm 51, and return to the transverse clipping position 141 along internal curved slide rail 142, at this point, under the effect of the spring 4, the press-button 3 will bounce back out of the rear slot 15, and the pressing arm 31 will basically withdraw from the insertion hole 25, the axle pin 32 is restored and abuts on the transverse clipping position 141, so that complete linkage is failed. Under the force of the elastic arm 51, the lock hook 2 is pushed to rotate and reset, so that the lock arm 21 and the hook arm 11 are locked. In this way, the structure can realize self-locking.

[0046] An axle pin 32 is disposed across the two sides of the pressing arm 31, and a long opening structure matching the axle pin 32 is disposed on both sides of the insertion hole 25. The axle pin 32 is caught inside the opening structure. The axle pin 32 protrudes on both sides of the pressing arm 31, and cooperates with the -shaped transverse clipping position 141 and curved slide rail 142 on both sides inside the mounting slot 14, forming a clip structure that can be opened by the two-stage action of pressing and rotation, as the action path a of axle pin 32 (dotted arrow) in FIG. 5, when the press-button 3 is released, the lock hook 2 bounces back automatically in the opposite direction of path a, and the axle pin 32 springs back to the -shaped transverse clipping position 141, implementing the self-locking function.

[0047] The entire lock hook 2 is a L-shaped structure. The bent part of the lock hook 2 is disposed with a shaft hole 23. The rotation shaft 6 is put through the shaft hole 23 and connected to the fixing hole on the hook base 1.

[0048] The elastic arm 51 is connected with a decor cap 5. The decor cap 5 is embedded inside the slot mouth on the front end of the mounting slot 14 to cover the mounting slot from the front end 14. The elastic arm 51 extends in an arched form from the lower side of the support arm 22 and is pressed upon the bottom surface of the support arm 22.

[0049] A positioning hole 16 is disposed near the front edge on the hook base 1, a clip is disposed on both sides of the decor cap 5. By clipping the clip into the positioning hole 16, the decor cap 5 is assembled and fixed with the hook base 1. The assembly is convenient and can be performed without screws for fixing.

[0050] The head part of the hook arm 11 is disposed with a hook head 12. The head part of the hook head 12 is disposed with a lock head 13. The lock head 13 and the hook head 12 form an inverted T-shaped structure. A lock groove 24 having a shape matching the hook head 12 and the lock head 13 is disposed on the end part of the lock arm 21. When the lock arm 21 and the hook arm 11 are engaged, the hook head 12 and the lock head 13 are caught inside the lock groove 24 to avoid swing and ensure stable locking. A closed (non-unilateral force-bearing) force-bearing structure is formed with the hook arm 11, which can effectively share the stress on the hook arm 11 and provide the hook body with greater tensile force bearing capacity.

[0051] The hook base 1, the lock hook 2, and the press-button 3 are made of metallic or plastic materials. The pressing arm 31 and the press-button 3 are formed in an integral structure or a separate structure. The decor cap 5 and the elastic arm 51 are formed in an integral structure or a separate structure, made of metallic or plastic materials.

[0052] The tail end of the hook base 1 is disposed with a connecting head 17. The connecting head 17 and the hook base 1 are formed in an integral structure. A swivel connecting loop 7 is connected to the connecting head 17. The connecting loop 7 is locked on the connecting head 17 through a clamping ring.

[0053] Although the invention has been explained in relation to its preferred embodiment, it is to be understood that many other possible modifications and variations can be made without departing from the spirit and scope of the invention as hereinafter claimed.