CN220679926U - Height-adaptive material pressing mechanism - Google Patents

Abstract

The utility model discloses a height-adaptive material pressing mechanism which comprises a lifting base, a material pressing component and a plurality of unit driving components, wherein the plurality of unit driving components are arranged in the height direction and can be movably arranged on the lifting base in the height direction, the material pressing component is used for pressing stacked material loading plates, the material pressing component is connected with the unit driving component at the highest position, the unit driving component at the lowest position is connected with the bottom end of the lifting base, and the plurality of unit driving components are sequentially lifted or lowered to drive the material pressing component to lift. Above-mentioned every unit drive assembly of high swager of self-adaptation descends in proper order, drives swager subassembly and supports and lean on the loading board of stacking, can press the material in co-altitude department not only design benefit, occupation space is little, has improved swager efficiency moreover greatly, and the commonality is good.

Description

Height-adaptive material pressing mechanism

Technical Field

The utility model belongs to the technical field of automatic equipment, and particularly relates to a height-adaptive material pressing mechanism.

Background

Along with the gradual perfection of full-automatic detection of electronic components, the precision requirement of industry on automation equipment is gradually improved, the requirement on production efficiency is also higher and higher, especially, the PIN is a metal substance for completing conductive transmission of electric signals in a connector, when the terminal is assembled, the metal PIN is required to be firstly arranged on a feeding plate, then a plurality of feeding plates are stacked and placed and then pressed, and finally the assembly is carried out.

At present, the assembly of terminal has realized automaticly, and pressing mechanism is the indispensable subassembly of pressing the loading board, in specific pressing in-process, because the stacking height of loading board is different, and current pressing mechanism's pressure material highly fixed, all need change not high pressing mechanism when pressing material at every turn, obviously, there is the problem that the operation is complicated, pressing efficiency is low and degree of automation is low.

Disclosure of Invention

The utility model aims to provide a self-height-adaptive material pressing mechanism, which solves the problems of low material pressing efficiency and low automation degree of the material pressing mechanism in the prior art.

To achieve the purpose, the utility model adopts the following technical scheme:

a height-adaptive material pressing mechanism comprises a lifting base, a material pressing component and a plurality of unit driving components, wherein,

the plurality of unit driving components are arranged along the height direction, the plurality of unit driving components can be installed on the lifting base in a movable mode along the height direction, the material pressing component is used for pressing materials of stacked material loading plates, the material pressing component is connected with the unit driving component at the highest position, the unit driving component at the lowest position is connected with the bottom end of the lifting base, and the plurality of unit driving components are sequentially lifted or lowered to drive the material pressing component to lift.

Further, the plurality of unit driving components are arranged on the lifting base in a lifting manner through the guide component, the plurality of unit driving components comprise unit driving components and lifting components, the movable end of each unit driving component is connected with the corresponding lifting component, each unit driving component drives the corresponding lifting component to lift, and each lifting component is arranged on the guide component in a sliding manner through the sliding component.

Further, the base is provided with a height adjusting assembly, the sliding piece adopts a sliding block, the guiding assembly adopts a lifting guide rail, and the lifting piece is arranged on the lifting base in a lifting manner through a sliding pair formed by the sliding piece and the lifting guide rail.

Further, a limiting component is arranged between two adjacent lifting pieces and used for limiting the lifting travel of the lifting pieces.

Further, the limiting component comprises a limiting part and a movable part, the first end of the limiting part is detachably arranged on the lifting part at a low position, the second end of the limiting part is slidably arranged on the lifting part at a high position, a limiting groove is formed in the limiting part along the height direction, the limiting groove corresponds to the movable part, the movable part is fixed on the lifting part at the high position, and the movable part is lifted in the limiting groove so as to limit the lifting stroke of the lifting part.

Further, the limiting component comprises a limiting part and a movable part, the first end of the limiting part is detachably arranged on the lifting part at a high position, the second end of the limiting part is slidably arranged on the lifting part at a low position, a limiting groove is formed in the limiting part along the height direction, the limiting groove corresponds to the movable part, the movable part is fixed on the lifting part at the low position, and the movable part is lifted in the limiting groove so as to limit the lifting stroke of the lifting part.

Further, the limiting assembly further comprises two height sensing components, the two height sensing components are arranged on the limiting piece at intervals along the height direction, and the height sensing components are used for limiting the lifting stroke of the lifting piece.

Further, two adjacent unit driving members are connected through a floating joint.

Further, the pressing assembly comprises a pressing part and a connecting part, the first end of the connecting part is connected with the lifting part at the highest position, the second end of the connecting part is connected with the pressing part, the pressing surface of the pressing part is arranged downwards, and the plurality of unit driving parts sequentially drive the lifting parts to ascend or descend so as to drive the pressing part to lift.

Compared with the prior art, the self-adaptive height material pressing mechanism has the beneficial effects that: the plurality of unit driving parts are adopted to sequentially cooperate with lifting, so that the material pressing can be performed at different heights, the design is ingenious, the occupied space is small, the material pressing efficiency is greatly improved, and the universality is good; the automatic feeding device does not need to manually replace pressing mechanisms with different specifications, and has high automation degree and low cost; the limiting component ensures the lifting travel of the lifting piece and has accurate arrival precision.

Drawings

Fig. 1 is a schematic perspective view of a height-adaptive pressing mechanism according to an embodiment of the present utility model;

FIG. 2 is a schematic side view of a height adaptive press mechanism according to an embodiment of the present utility model;

fig. 3 is an enlarged schematic view at a in fig. 1.

Detailed Description

The technical scheme of the utility model is further described below by the specific embodiments with reference to the accompanying drawings.

In order that the utility model may be readily understood, a more complete description of the utility model will be rendered by reference to the appended drawings. Preferred embodiments of the present utility model are shown in the drawings. This utility model may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete. It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1 to 3, in this embodiment, a height-adaptive pressing mechanism includes a lifting base 1, a pressing component 2 and a plurality of unit driving components 3, where the plurality of unit driving components 3 are arranged along a height direction, the plurality of unit driving components 3 are movably mounted on the lifting base 1 along the height direction, the pressing component 2 is used for pressing stacked feeding plates, the pressing component 2 is connected with the unit driving component 3 at the highest position, the unit driving component 3 at the lowest position is connected with the bottom end of the lifting base 1, and the plurality of unit driving components 3 rise or fall sequentially to drive the pressing component 2 to lift.

As an embodiment, the plurality of unit driving assemblies 3 are all arranged on the lifting base 1 in a lifting manner through the guide assembly 4, the plurality of unit driving assemblies 3 comprise unit driving pieces 30 and lifting pieces 31, the movable end of each unit driving piece 30 is connected with the corresponding lifting piece 31, each unit driving piece 30 drives the corresponding lifting piece 31 to lift, and each lifting piece 31 is arranged on the guide assembly 4 in a sliding manner through the sliding piece 5, so that lifting stability is improved.

Therefore, the plurality of unit driving pieces 30 are adopted to sequentially cooperate to lift, and the material pressing can be carried out at different heights, so that the design is ingenious, the occupied space is small, the material pressing efficiency is greatly improved, and the universality is good.

As an embodiment, the slider 5 is a slider, the guide assembly 4 is a lifting rail, and the lifting member 31 is provided on the lifting base 1 in a liftable manner by a sliding pair of the slider and the lifting rail.

As an embodiment, a limiting component 6 is disposed between two adjacent lifting members 31, the limiting component 6 is used for limiting the lifting travel of the lifting members 31, the limiting component 6 includes a limiting member 60 and a movable member 61, a first end of the limiting member 60 is detachably disposed on the lifting member 31 located at a low position, a second end of the limiting member 60 is slidably disposed on the lifting member 31 located at a high position, a limiting groove 600 is disposed on the limiting member 60 along the height direction, the limiting groove 600 is disposed corresponding to the movable member 61, the movable member 61 is fixed on the lifting member 31 located at the high position, and the movable member 61 is lifted in the limiting groove 600 to limit the lifting travel of the lifting member 31.

Of course, as another embodiment, the first end of the limiting member 60 is detachably disposed on the lifting member 31 located at a high position, the second end of the limiting member 60 is slidably disposed on the lifting member 31 located at a low position, the limiting member 60 is provided with a limiting groove 600 along a height direction, the limiting groove 600 is disposed corresponding to the movable member 61, the movable member 61 is fixed on the lifting member 31 located at a low position, the movable member 61 is lifted in the limiting groove 600 to limit the lifting stroke of the lifting member 31, and the limiting assembly 6 ensures the lifting stroke of the lifting member 31 and has precise reaching precision.

As an embodiment, the limiting assembly 6 further includes two height sensing components 62, where the two height sensing components 62 are disposed on the limiting member 60 at intervals along the height direction, and the height sensing components 62 are used for limiting the lifting stroke of the lifting member 31.

As an embodiment, two adjacent unit driving pieces 30 are connected through the floating joint 7, so that the connection strength between the unit driving pieces 30 is enhanced, and the lifting stability is improved.

As an embodiment, the pressing assembly 2 includes a pressing member 20 and a connecting member 21, a first end of the connecting member 21 is connected to a lifting member 31 at a highest position, a second end of the connecting member 21 is connected to the pressing member 20, a pressing surface of the pressing member 20 is disposed downward, and the plurality of unit driving members 30 sequentially drive the corresponding lifting member 31 to lift or descend so as to drive the pressing member 20 to lift, thereby pressing the feeding plate.

The working principle of the self-adaptive height material pressing mechanism is as follows: each unit driving piece 30 drives the corresponding lifting piece 31 to rise to the maximum travel, the pressing piece 20 is at the initial position, the feeding plates stacked along the height direction are placed under the pressing piece 20, each unit driving piece 30 drives the corresponding lifting piece 31 to descend, the pressing piece 20 is driven to descend, the pressing piece 20 is abutted against the uppermost feeding plate, the pressing piece 20 is in the pressing state, and subsequent assembly is performed after glue pressing is completed.

The above embodiments merely illustrate the basic principles and features of the present utility model, and the present utility model is not limited to the above examples, but can be variously changed and modified without departing from the spirit and scope of the present utility model, which is within the scope of the present utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (9)

1. The height-adaptive material pressing mechanism is characterized by comprising a lifting base, a material pressing component and a plurality of unit driving components, wherein the material pressing component comprises a lifting base, a lifting base and a lifting base,

the plurality of unit driving components are arranged along the height direction, the plurality of unit driving components can be installed on the lifting base in a movable mode along the height direction, the material pressing component is used for pressing materials of stacked material loading plates, the material pressing component is connected with the unit driving component at the highest position, the unit driving component at the lowest position is connected with the bottom end of the lifting base, and the plurality of unit driving components are sequentially lifted or lowered to drive the material pressing component to lift.

2. The adaptive height swage mechanism of claim 1, wherein a plurality of said unit drive assemblies are each disposed liftably on said lift base by means of a guide assembly, said plurality of unit drive assemblies each comprising a unit drive member and a lift member, each movable end of each said unit drive member being connected to a corresponding said lift member, each said unit drive member driving a corresponding said lift member to rise and fall, each said lift member being slidably disposed on said guide assembly by means of a slide member.

3. The self-height-adaptive pressing mechanism according to claim 2, wherein the sliding piece adopts a sliding block, the guiding assembly adopts a lifting guide rail, and the lifting piece is arranged on the lifting base in a lifting manner through a sliding pair consisting of the sliding piece and the lifting guide rail.

4. The self-height-adaptive material pressing mechanism according to claim 2, wherein a limiting assembly is arranged between two adjacent lifting members, and the limiting assembly is used for limiting the lifting travel of the lifting members.

5. The adaptive height swager according to claim 4, wherein the stopper assembly comprises a stopper and a movable member, wherein a first end of the stopper is detachably disposed on the lifter at a low position, a second end of the stopper is slidably disposed on the lifter at a high position, a stopper groove is formed in the stopper in a height direction, the stopper groove is disposed corresponding to the movable member, the movable member is fixed on the lifter at a high position, and the movable member is lifted in the stopper groove to limit a lifting stroke of the lifter.

6. The adaptive height swager according to claim 4, wherein the stopper assembly comprises a stopper and a movable member, wherein a first end of the stopper is detachably disposed on the lifting member at a high position, a second end of the stopper is slidably disposed on the lifting member at a low position, a stopper groove is formed in the stopper along a height direction, the stopper groove is disposed corresponding to the movable member, the movable member is fixed on the lifting member at a low position, and the movable member is lifted in the stopper groove to limit a lifting stroke of the lifting member.

7. The adaptive height swager according to claim 5 or 6, wherein the stop assembly further comprises two height sensing members disposed on the stop member at intervals along the height direction, the height sensing members being configured to stop the lifting stroke of the lifting member.

8. The adaptive height swage of claim 2, wherein adjacent ones of said cell drivers are connected by a floating joint.

9. The self-height-adaptive material pressing mechanism according to claim 2, wherein the material pressing assembly comprises a material pressing member and a connecting member, a first end of the connecting member is connected with the lifting member at the highest position, a second end of the connecting member is connected with the material pressing member, a glue pressing surface of the material pressing member is arranged downwards, and a plurality of unit driving members sequentially drive the lifting member to lift or descend so as to drive the material pressing member to lift.