CN108580686B - Safe guide clamp sliding block shaping mechanism and hardware continuous die - Google Patents

Abstract

The invention discloses a safe guide clamp sliding block shaping mechanism and a hardware continuous die, wherein the safe guide clamp sliding block shaping mechanism comprises a gap bridge floating block, a pair of first shaping components and a pair of second shaping components; the first shaping assembly comprises a first shaping upper die and a first shaping lower die, the first shaping lower die comprises a first sliding block, and the first shaping upper die comprises a first guide block; the second shaping assembly comprises a second shaping upper die and a second shaping lower die, the second shaping lower die comprises a second sliding block, and the second shaping upper die comprises a second guide block; the first derivation block drives the first slide blocks to enable the pair of first slide blocks to move along the width direction of the gap bridge floating block and abut against the surface of the safety guide clamp; the second derivation block drives the second sliding blocks to enable the pair of second sliding blocks to move relatively along the length direction of the bridge-crossing floating block and to be in contact with the side edge of at least one elastic arm of the safety guide clamp; so that at least one elastic arm of the safety guide clip is mutually buckled. This technical scheme improves production efficiency.

Description

Safe guide clamp sliding block shaping mechanism and hardware continuous die

Technical Field

The invention relates to a hardware mould, in particular to a safe guide clamp sliding block shaping mechanism and a hardware continuous mould.

Background

At present, aiming at the forming process that two elastic arms on a safety guide clamp are mutually buckled, the crossing step of the two elastic arms is firstly completed by a manual single-engineering mould, and then the crossing step can be completed by the combined production of a plurality of moulds. The operation mode has the defects of low production speed, low efficiency, small product volume, inconvenience in clamping the elastic arm by the mold and unsuitability for mass production of the safety guide clamp.

Disclosure of Invention

The invention mainly aims to provide a sliding block reshaping mechanism of a safety guide clamp, aiming at improving the production efficiency of the safety guide clamp.

In order to achieve the above object, the present invention provides a shaping mechanism for a safety guide clamp slider, comprising:

the safety guide clamp is arranged on the gap bridge floating block;

the pair of first shaping assemblies are arranged on two sides of the gap bridge floating block, each first shaping assembly comprises a first shaping upper die and a first shaping lower die, each first shaping lower die comprises a first sliding block arranged on one side of the gap bridge floating block, and each first shaping upper die comprises a first push guide block linked with the corresponding first sliding block and used for shaping the safety guide clamp along the width direction of the gap bridge floating block;

the pair of second shaping assemblies are arranged on two sides of the gap bridge floating block, each second shaping assembly comprises a second shaping upper die and a second shaping lower die, each second shaping lower die comprises a second sliding block which is arranged on one side of the gap bridge floating block and is arranged along the length direction of the gap bridge floating block, and each second shaping upper die comprises a second pushing block which is linked with the corresponding second sliding block and is used for shaping the safety guide clamp along the length direction of the gap bridge floating block;

the first derivation block drives the first slide blocks so that the pair of first slide blocks relatively move along the width direction of the gap bridge floating block and respectively abut against the surface of the safety guide clamp; the second derivation block drives the second sliding blocks to enable the pair of second sliding blocks to move relatively along the length direction of the gap bridge floating block and to be in contact with the side edge of at least one elastic arm of the safety guide clamp; so that at least one elastic arm of the safety guide clip is mutually buckled.

Preferably, the inner sides of the lower ends of the first and second pushing blocks are provided with inclined planes, the upper ends of the first and second sliding blocks are also provided with inclined planes, the first pushing block and the first sliding block are matched with each other through the inclined planes to convert vertical motion into horizontal motion, and the second pushing block and the second sliding block are matched with each other through the inclined planes to convert vertical motion into horizontal motion.

Preferably, the slope length of each slope is equal or unequal.

Preferably, the inclined lengths of the inclined surfaces are equal, the machining stroke of the first sliding block is equal to the machining stroke of the second sliding block, the length of the first pushing block is longer than that of the second pushing block, the first pushing block and the second pushing block move vertically at the same time, and the first pushing block contacts the first sliding block first, so that the first sliding block contacts the safety guide clip before the second sliding block contacts the safety guide clip.

Preferably, the first sliding block includes a pressing portion, the pressing portion extends toward the floating block, the elastic arm of the safety guide clip includes an elastic portion, and the pressing portion presses against the elastic portion, so that the elastic portion presses against the surface of the floating block.

Preferably, the cross section of the gap bridge floating block is trapezoidal, the pressing part comprises a pressing surface, the pressing surface is parallel to the surface opposite to the gap bridge floating block, and the pressing surface presses against the elastic part, so that the elastic part presses against the surface of the gap bridge floating block.

Preferably, the second slider includes a pushing part, a clamping groove is formed in the side edge of the elastic arm, the second slider includes a pushing part, and the pushing part includes a matching groove used for matching with the clamping groove.

Preferably, the second slider further includes a slider body and a connecting portion connecting the slider body and the pushing portion, and the connecting portion extends from the slider body toward one side of the gap bridge floating block toward the direction of the safety guide clip.

Preferably, the safety guiding clamp further comprises a buckling part and a clamping part, the buckling part is arranged on one elastic arm, the clamping part is arranged on the other elastic arm, the buckling part comprises a first folding edge and a second folding edge connected with the first folding edge, the first folding edge and the second folding edge form a first included angle, the clamping part comprises a third folding edge and a fourth folding edge connected with the third folding edge, the third folding edge and the fourth folding edge form a second included angle, and the angle of the first included angle is larger than that of the second included angle.

The invention further provides a continuous hardware mould which comprises a cutting mechanism, a bending mechanism and a shaping mechanism, wherein the shaping mechanism comprises the safe guide clamp sliding block shaping mechanism.

According to the technical scheme, the sliding block shaping mechanism is arranged, so that the safety guide clamp is automatically produced in the hardware high-speed stamping continuous die, the problem of a production operation mode that the production efficiency of a single-stamping die is low is effectively solved, and the production efficiency of the safety guide clamp is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of a slide reshaping mechanism of a safety guide clamp according to the present invention;

FIG. 2 is a schematic view of another angle of the slide truing mechanism of the safety guiding clamp of FIG. 1;

FIG. 3 is a top view of the safety guide clip slider reforming mechanism of FIG. 1;

FIG. 4 is a schematic structural view of the shaping mechanism of the safety guide clamp slider in the use state in FIG. 1;

FIG. 5 is a schematic structural diagram of the first slider shown in FIG. 1;

FIG. 6 is a schematic structural diagram of a second slider shown in FIG. 1;

FIG. 7 is a schematic view of the safety guide clip of FIG. 1;

FIG. 8 is a schematic view of the safety guide clip of FIG. 7 in a locked position;

the reference numbers illustrate:

the implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that, if directional indications (such as up, down, left, right, front, and back … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative positional relationship between the components and the movement situation in a specific posture (shown in the drawings), and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description of "first", "second", etc. in an embodiment of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

In order to improve the production efficiency of the safety guide clip 100, the present invention provides a new shaping mechanism for a slide block of the safety guide clip, and fig. 1 to 8 and fig. 1 to 4 show the schematic structural diagrams of an embodiment of the shaping mechanism for a slide block of the safety guide clip of the present invention.

This safe guide presss from both sides slider plastic mechanism includes: the bridge-crossing floating block 200, the first reshaping component 300 and the second reshaping component 400, wherein the safety guide clamp 100 is sleeved on the bridge-crossing floating block 200; a pair of first shaping assemblies 300 are arranged at two sides of the gap bridge floating block 200, each first shaping assembly 300 comprises a first shaping upper die and a first shaping lower die, the first shaping lower die comprises a first sliding block 320 arranged at one side of the gap bridge floating block, and the first shaping upper die comprises a first push guide block 310 linked with the first sliding block 320 and used for shaping the safety guide clamp 100 along the width direction of the gap bridge floating block 200;

a pair of second shaping assemblies 400 are arranged at two sides of the gap bridge floating block 200, each second shaping assembly 400 comprises a second shaping upper die and a second shaping lower die, the second shaping lower die comprises a second sliding block 420 arranged at one side of the gap bridge floating block 200 and along the length direction of the gap bridge floating block 200, and the second shaping upper die comprises a second push guide block 410 linked with the second sliding block 420 and used for shaping the safety guide clamp 100 along the length direction of the gap bridge floating block 200;

the first guide block 310 drives the first sliding blocks 320, so that the pair of first sliding blocks 310 relatively move along the width direction of the gap bridge floating block 200 and respectively press against the surface of the safety guide clamp 100; the second guide block 410 drives the second slider 420 to make the pair of second sliders 320 relatively move along the length direction of the gap bridge floating block 200 and contact with the side edge of at least one elastic arm of the safety guide clip 100; so that at least one elastic arm of the safety guide clip 100 is engaged with each other.

In the present embodiment, according to the shape characteristics of the floating block 200, the safety guide clip 100 is directly sleeved on the floating block 200 to be suitable for the later processing.

The safety guide clamp slider shaping mechanism is arranged in a die, the die comprises an upper die holder and a lower die holder, wherein the two first guide blocks 310 and the two second guide blocks 410 can be fixed on the upper die holder or connected through a transmission mechanism, such as a guide column, a connecting rod and the like, so that the two first guide blocks 310 and the two second guide blocks 410 can be linked with the upper die holder. The two first sliders 320 and the two second sliders 420 are arranged on the lower die holder, inclined planes are arranged on the inner sides of the lower ends of the first push guide block 310 and the second push guide block 410, inclined planes are also arranged on the upper ends of the first slider 320 and the second slider 420, the first push guide block 310 and the first slider 320 are matched with each other through the inclined planes to convert vertical motion into horizontal motion, and the second push guide block 410 and the second slider 420 are matched with each other through the inclined planes to convert vertical motion into horizontal motion. The slope length of each slope may be equal or different, and is set according to actual needs, and is not specifically limited herein. In a specific embodiment, an included angle between the inclined plane and the horizontal plane is preferably 45 degrees, the inclined length of each inclined plane is equal, the machining stroke of the first slider 320 is equal to the machining stroke of the second slider 420, the length of the first guide block 310 is longer than that of the second guide block 410, the first guide block 310 and the second guide block 410 move vertically at the same time, the first guide block 310 contacts the first slider 320 first, so that the first slider 320 contacts the safety guide clip 100 before the second slider 420 contacts, the safety guide clip 100 is positioned first, then the second slider 420 contacts the side edge of the elastic arm and pushes the elastic arm to move in the opposite direction, and when the second slider 420 leaves the elastic arm, at least one elastic arm is elastically buckled together through self-elasticity. According to the arrangement, the inclined plane is arranged between the derivation block and the sliding block for derivation, and meanwhile, the standard of the model is unified, so that the structure is simple, the processing is convenient, the synchronism is good, the operation is easy, and the popularization and the application of the product are facilitated.

The working principle of the safety guide clamp sliding block shaping mechanism is as follows: the upper die base works downwards, the push guide block moves downwards along with the upper die base, and the inclined surface of the lower end of the push guide block correspondingly acts on the inclined surfaces (the two inclined surfaces slide relatively) on the corresponding slide blocks, so that the acting force of side push is generated to drive the slide blocks to move relatively, and the aim of acting the slide blocks on the safety guide clamp 100 is fulfilled.

As shown in fig. 4, the working process of the present invention is: the process is earlier the tablet through the preliminary cutting in material area of conventional mould, goes out bellied shape to tablet both sides punching press again, carries out the different symmetrical bending of cubic angle respectively after that and bends, and the first time is the outer 90 degrees of bending that are close to the border position, and the second time leans on approximate 70 degrees of the interior song of interior position, and the third is bent towards the centre again to two edges of turning over, obtains the preliminary three-dimensional shape of product, then cup joints the safety guide clamp 100 that obtains tentatively on the floating block 200 of passing a bridge. At this time, the shaping upper die base descends, the pushing blocks simultaneously move downwards, firstly, the pair of first pushing blocks 310 with longer length simultaneously push the pair of first sliding blocks 320 to approach to the middle, and continue to move forwards after contacting the surfaces of the two elastic arms 110 of the safety guide clamp 100 until the two elastic arms 110 contact the surface of the gap bridge floating block 200, so that the shaping and positioning functions are achieved. Then, the pair of second pushing blocks 410 with shorter length starts to contact the pair of second sliders 420 and are pushed to move toward the safety guiding clip 100, the two second sliders 420 respectively contact the sides of the two elastic arms 110 and continue to push to move in opposite directions, and when the second sliders 420 leave the safety guiding clip 100, the two elastic arms 110 are fastened to each other. At this point, the shaping of the safety guide clip 100 is completed, and the shaped safety guide clip 100 is separated from the gap bridge floating block 200. After the forming is finished, the derivation block moves upwards along with the upper die holder, and the sliding block automatically resets under the action of a corresponding reset piece (not shown) so as to prepare for the next forming; the reset piece can be a compression spring, a tension spring or an elastic sheet and the like.

It should be noted that, different fastening manners may be adopted for different relative positions of the two elastic arms 110, and no particular limitation is imposed here. Specifically, in this embodiment, when the two elastic arms 110 are symmetrically disposed, after the first slider 320 is pressed against the two elastic arms 110, the two elastic arms 110 are attached to each other, at this time, the second slider 420 moves relatively to stagger the two elastic arms 110 to interfere with each other, and after the two elastic arms 110 are completely staggered, the two elastic arms 110 are automatically buckled together by the resilience of the material thereof. Of course, another embodiment is that when the positions of the two elastic arms 110 are asymmetric at the beginning, and after the first slider 320 is pressed, a certain distance still exists in the length direction of the gap bridge floating speed, the two elastic arms 110 can be directly buckled together after being closed under the action of the second slider 420.

According to the technical scheme, the sliding block shaping mechanism is arranged, so that the safety guide clamp 100 is automatically produced in the hardware high-speed stamping continuous die, the problem of a production operation mode that the production efficiency of a single-stamping die is low is effectively solved, and the production efficiency of the safety guide clamp 100 is improved.

For positioning convenience, referring to fig. 5 and 7, the first slider 320 includes a pressing portion 321, the pressing portion 321 extends toward the floating block 200, the elastic arm 110 of the safety guide clip 100 includes an elastic portion 111, and the pressing portion 321 presses against the elastic portion 111, so that the elastic portion 111 abuts against the surface of the floating block 200. Specifically, in the present embodiment, the contact between the pressing portion 321 and the elastic portion 111 may be a point contact, a line contact or a surface contact, and it is only necessary to be able to press the elastic arm 110 against the surface of the floating block 200, and this is not particularly limited herein.

Further, referring to fig. 5 and 7, the cross section of the floating block 200 is trapezoidal, the pressing portion 321 includes a pressing surface 3211, the pressing surface 3211 is parallel to a surface of the floating block 200, and the pressing surface 3211 presses the elastic portion 111, so that the elastic portion 111 presses against the surface of the floating block 200.

Specifically, in this embodiment, the pressing portion 321 includes a pressing surface 3211 parallel to a surface opposite to the floating block 200, so that the contact between the pressing portion 321 and the elastic portion 111 is surface contact, the stressed area is increased, the positioning is more stable, and the subsequent shaping process is facilitated.

For convenience of pushing, referring to fig. 6 and 7, the side edge of the elastic arm 110 is provided with a slot 112, the second slider 420 includes a pushing portion 421, and the pushing portion 421 includes a matching slot 4211 for matching with the slot 112. Specifically, in the present embodiment, the two elastic arms 110 are provided with the locking grooves 112, which not only facilitates the positioning of the pushing portion 421 of the second slider 420, but also prevents the elastic arms 110 from easily sliding in the locking grooves 112 during the pushing movement process, so that the effect of corresponding deformation distance cannot be achieved, and thus the problem that the two elastic arms 110 cannot be locked due to insufficient elastic force is caused; correspondingly, the matching groove 4211 can be arranged on the pushing part 421 at a position corresponding to the clamping groove 112, so that the pushing part 421 can be quickly positioned on the elastic arm 110, the problem that the pushing part 421 and the elastic arm 110 are not clamped to cause buckling failure of the two elastic arms 110 is prevented, and the yield of products is improved.

In order to ensure the moving distance, referring to fig. 6, the second slider 420 further includes a slider body 422 and a connecting portion 423 connecting the slider body 422 and the pressing portion 421, and the connecting portion 423 extends from the slider body 422 toward the safety guide clip 100 toward a side of the bridge floating block 200. Specifically, in this embodiment, by providing the connecting portion 423, the distance between the slider body 422 of the second slider 420 and the safety guide clip 100 can be increased, the position of the second slider 420 can be conveniently set, the situation of interference and collision between the second slider 420 and the first slider 320 can be prevented, and the layout design of the mechanism can be reasonably optimized.

For the convenience of buckling, referring to fig. 7 and 8, the safety guiding clip 100 further includes a buckling portion 113 and a retaining portion 114, the buckling portion 113 is disposed on one elastic arm 110, the retaining portion 114 is disposed on the other elastic arm 110, the buckling portion 113 includes a first folding edge 1131 and a second folding edge 1132 connected to the first folding edge 1131, the first folding edge 1131 and the second folding edge 1132 form a first included angle, the retaining portion 114 includes a third folding edge 1141 and a fourth folding edge 1142 connected to the third folding edge 1141, the third folding edge 1141 and the fourth folding edge 1142 form a second included angle, and the angle of the first included angle is greater than the angle of the second included angle.

Specifically, in this embodiment, when the clamping portion 114 is clamped into the buckling portion 113, the second folding edge 1132 and the fourth folding edge 1142 are overlapped in a crossing manner, at this time, the openings of the first included angle and the second included angle face each other, and the angle of the first included angle is greater than that of the second included angle, so the clamping portion 114 can enter the buckling portion 113, in addition, the second folding edge 1132 and the fourth folding edge 1142 generate an acting force in the opposite direction by virtue of the elasticity of the second folding edge 1132, and the outer side wall of the third folding edge 1141 abuts against the inner side wall of the first folding edge 1131, thereby achieving the purpose of clamping. Like this, slider mechanism then rational utilization safety guide presss from both sides 100 self characteristics, makes two elastic arm 110 carry out the lock through the automatic resilience of self elasticity, and simple structure is convenient for the product shaping, improves production efficiency.

The invention further provides a continuous hardware mould, which comprises a cutting mechanism, a bending mechanism and a shaping mechanism, wherein the shaping mechanism comprises the safety guide clamp sliding block shaping mechanism, the specific structure of the safety guide clamp sliding block shaping mechanism refers to the embodiments, and the safety guide clamp sliding block shaping mechanism adopts all the technical schemes of all the embodiments, so that the continuous hardware mould at least has all the beneficial effects brought by the technical schemes of the embodiments, and the details are not repeated.

The above embodiments are merely examples, and not intended to limit the scope of the invention, and all modifications and equivalents that can be made by using the contents of the specification and drawings or directly/indirectly applied to other related technical fields are included in the scope of the invention.

Claims (10)

1. A safety guide clip slider shaping mechanism, comprising:

the safety guide clamp is arranged on the gap bridge floating block;

the pair of first shaping assemblies are arranged on two sides of the gap bridge floating block, each first shaping assembly comprises a first shaping upper die and a first shaping lower die, each first shaping lower die comprises a first sliding block arranged on one side of the gap bridge floating block, and each first shaping upper die comprises a first push guide block linked with the corresponding first sliding block and used for shaping the safety guide clamp along the width direction of the gap bridge floating block;

the pair of second shaping assemblies are arranged on two sides of the gap bridge floating block, each second shaping assembly comprises a second shaping upper die and a second shaping lower die, each second shaping lower die comprises a second sliding block which is arranged on one side of the gap bridge floating block and is arranged along the length direction of the gap bridge floating block, and each second shaping upper die comprises a second pushing block which is linked with the corresponding second sliding block and is used for shaping the safety guide clamp along the length direction of the gap bridge floating block;

the first derivation block drives the first slide blocks so that the pair of first slide blocks relatively move along the width direction of the gap bridge floating block and respectively abut against the surface of the safety guide clamp; the second derivation block drives the second sliding blocks so that the pair of second sliding blocks relatively move along the length direction of the gap bridge floating block and are in contact with the side edge of at least one elastic arm of the safety guide clamp; so that at least one elastic arm of the safety guide clip is mutually buckled.

2. The safety guide clip slider reshaping mechanism according to claim 1, wherein the first and second push guide blocks have a slope on the inner side of the lower end thereof, and the first and second slider blocks have a slope on the upper end thereof, the first push guide block and the first slider block are engaged with each other in a slope to convert the vertical movement into the horizontal movement, and the second push guide block and the second slider block are engaged with each other in a slope to convert the vertical movement into the horizontal movement.

3. The safety clip slider fairing mechanism of claim 2, wherein the slope length of each ramp is equal or unequal.

4. The safety guide clip slider reshaping mechanism according to claim 3, wherein the slope length of each slope is equal, the machining stroke of the first slider is equal to the machining stroke of the second slider, the length of the first guide block is longer than the length of the second guide block, the first guide block and the second guide block move vertically at the same time, and the first guide block contacts the first slider so that the first slider contacts the safety guide clip before the second slider.

5. The sliding block reshaping mechanism for the safety guide clip according to claim 1, wherein the first sliding block comprises a pressing portion extending toward the floating block, and the elastic arm of the safety guide clip comprises an elastic portion pressing against the elastic portion, so that the elastic portion abuts against the surface of the floating block.

6. The safety guide clamp slider reshaping mechanism according to claim 5, wherein the cross section of the gap bridge floating block is trapezoidal, the pressing portion comprises a pressing surface, the pressing surface is parallel to a surface of the gap bridge floating block, and the pressing surface presses against the elastic portion, so that the elastic portion presses against the surface of the gap bridge floating block.

7. The mechanism of claim 1, wherein the side of the elastic arm is provided with a slot, the second slider comprises a pushing portion, and the pushing portion comprises a matching slot for matching with the slot.

8. The guide clip reshaping mechanism according to claim 7, wherein the second slider further comprises a slider body and a connecting portion connecting the slider body and the pushing portion, the connecting portion extending from the slider body toward the bridge floating block in a direction of the guide clip.

9. The safety guide clamp slider shaping mechanism of any one of claims 1 to 8, wherein the safety guide clamp further comprises a buckling portion and a retaining portion, the buckling portion is disposed on one elastic arm, the retaining portion is disposed on the other elastic arm, the buckling portion comprises a first folded edge and a second folded edge connected to the first folded edge, the first folded edge and the second folded edge form a first included angle with each other, the retaining portion comprises a third folded edge and a fourth folded edge connected to the third folded edge, the third folded edge and the fourth folded edge form a second included angle with each other, and the angle of the first included angle is greater than the angle of the second included angle.

10. A progressive die of hardware comprising a cutting mechanism, a bending mechanism and a shaping mechanism, the shaping mechanism comprising a safety guide clip slider shaping mechanism as claimed in any one of claims 1 to 9.

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