CN112722686A - Intelligent direct-drive belt assembly line - Google Patents

Abstract

The invention discloses an intelligent direct-drive belt assembly line which structurally comprises a conveyor belt, a control button and a support frame, wherein the control button is connected with the support frame, the conveyor belt is arranged at the upper end position of the support frame, nuts standing on the upper side of the conveyor belt enter between two lower sliding plates on an upper contact plate and then pull the two lower sliding plates downwards, the lower sliding plates can slide downwards along a plate body, so that the two lower sliding plates can extrude the nuts standing on the side, the situation that the nuts standing on the upper side of the conveyor belt roll along the advancing of the upper contact plate on the conveyor belt and even roll to the ground is effectively avoided, in the process that the nuts with small volume between the two lower sliding plates are pulled upwards, the upper push plate can gradually push the extension plate to extend upwards along a fixed frame under the matching of a transition block, so that the extension plate can push out the nuts from top to bottom, so that the worker can easily take out the nut with smaller volume upwards.

Description

Intelligent direct-drive belt assembly line

Technical Field

The invention relates to the field of belt production lines, in particular to an intelligent direct-drive belt production line.

Background

The intelligent direct-drive assembly line belt conveyor is mainly equipment for conveying workpieces across areas, the workpieces are placed on the upper surface of the conveyor, and the workpieces can be conveyed forwards at a constant speed through the conveyor, so that workers can take the workpieces at fixed positions, and based on the above description, the inventor finds that the existing intelligent direct-drive assembly line mainly has the following defects, for example:

because the upper surface that assembly line belt conveyer was directly driven to intelligence is comparatively level and smooth, and the nut rolls easily when standing on one's side, if the nut appears standing on one's side when placing on assembly line belt conveyer is directly driven to intelligence, then follow the conveyer belt forward appears in the in-process of conveying easily, and the phenomenon of synchronous rolling forward to lead to the nut to roll the subaerial condition easily.

Disclosure of Invention

Aiming at the problems, the invention provides an intelligent direct-drive belt production line.

In order to achieve the purpose, the invention is realized by the following technical scheme: an intelligent direct-drive belt assembly line structurally comprises a conveyor belt, a control button and a support frame, wherein the control button is connected with the support frame, and the conveyor belt is arranged at the upper end of the support frame; the conveying belt comprises an upper touch plate, a linkage belt and a power frame, wherein the upper touch plate is arranged on the outer surface of the linkage belt, and the linkage belt is movably clamped with the power frame.

As a further optimization of the invention, the upper touch plate comprises a lower sliding plate, a pull-back strip, an outward pushing mechanism, a bottom plate and a plate body, wherein the lower sliding plate is movably clamped with the plate body, the pull-back strip is arranged between the lower sliding plate and the plate body, the outward pushing mechanism and the bottom plate are of an integrated structure, the plate body is fixedly embedded on the upper surface of the bottom plate, and the two lower sliding plates are uniformly and symmetrically distributed on the plate body.

As a further optimization of the invention, the lower sliding plate comprises an overhanging plate, a shrinking plate, a connecting plate and a bearing plate, wherein the left side of the overhanging plate is fixedly connected with the bearing plate, the overhanging plate is in clearance fit with the shrinking plate, the shrinking plate is connected with the bearing plate through the connecting plate, and three overhanging plates are uniformly distributed on the right side of the bearing plate in parallel.

As a further optimization of the invention, the overhanging plate comprises a connecting frame, a gripping block, two boosting rings and a rear plate, wherein the connecting frame is movably clamped with the rear plate, the gripping block is embedded and fixed at the right side of the connecting frame, the boosting rings are arranged between the connecting frame and the rear plate, and the gripping blocks are uniformly and symmetrically distributed at the right side of the connecting frame.

As a further optimization of the invention, the outward pushing mechanism comprises an extension plate, a fixed frame, an upper pushing plate and a transition block, wherein the extension plate is fixedly embedded at the upper end position of the transition block, the upper pushing plate is arranged at the bottom positions of the inner walls of the transition block and the fixed frame, the transition block is movably clamped with the fixed frame, and the extension plate can be downwards contracted under the matching of the transition block through the pressure of a nut on the extension plate.

As a further optimization of the invention, the extension plate comprises a middle connecting piece, a beating bottom plate and two upper swinging plates, wherein the middle connecting piece is arranged between the two upper swinging plates, the upper swinging plates are hinged with the upper end of the beating bottom plate, and the two upper swinging plates are uniformly and symmetrically distributed at the upper end of the beating bottom plate.

As a further optimization of the invention, the upper swinging plate comprises a contact plate, an outer pushing sheet, a plate block and a bearing plate, wherein the contact plate and the bearing plate are in an integrated structure, the bearing plate is movably clamped with the plate block through the outer pushing sheet, and the contact plate is made of a nitrile rubber material with high density.

The invention has the following beneficial effects:

1. the nut that inclines through the conveyer belt enters into and produces decurrent pulling to two lower sliding plates behind between two lower sliding plates on the last touch panel, can make the lower sliding plate slide down along the plate body to make two lower sliding plates can extrude the nut of inclining, the effectual nut of having avoided the conveyer belt incline can follow the conveyer belt on the advancing of last touch panel and appear rolling, roll the condition on ground even.

2. Through the in-process that the little volume nut between two lower sliding plates was upwards pulled out, the push-up plate can promote gradually and stretch out the board and upwards stretch out along fixed frame under the cooperation of transition piece to make stretch out that the board can top-down release the nut, so that the staff can easily upwards take out the less nut of volume.

Drawings

FIG. 1 is a schematic structural diagram of an intelligent direct-drive belt assembly line.

FIG. 2 is a schematic partial side view of a conveyor belt according to the present invention in half cross-section.

FIG. 3 is a schematic structural diagram of a side view cross section of the upper touch plate of the present invention.

FIG. 4 is a side view of the lower slide plate of the present invention.

FIG. 5 is a side view of a half-section of the outrigger of the present invention.

FIG. 6 is a schematic structural diagram of a side view cross section of the extrapolation mechanism of the present invention.

Fig. 7 is a schematic structural view of a side view cross section of the extension board of the present invention.

FIG. 8 is a side view of the top swing plate with a half-section structure.

In the figure: the device comprises a conveying belt-1, a control button-2, a support frame-3, an upper touch plate-11, a linkage belt-12, a power frame-13, a lower sliding plate-a 1, a pull-back strip-a 2, an outward pushing mechanism-a 3, a bottom plate-a 4, a plate body-a 5, an outward extending plate-a 11, a contraction plate-a 12, a connecting plate-a 13, a bearing plate-a 14, a connecting frame-b 1, a grabbing block-b 2, a boosting ring-b 3, a rear plate-b 4, an outward extending plate-c 1, a fixing frame-c 2, an upward pushing plate-c 3, a transition block-c 4, a middle connecting plate-c 11, a bottom plate-c 12, an upward swinging plate-c 13, a contact plate-d 1, an outward pushing plate-d 2, a plate-d 3 and a bearing plate-d 4.

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.

Example 1

As shown in fig. 1-5:

the invention provides an intelligent direct-drive belt assembly line which structurally comprises a conveyor belt 1, a control button 2 and a support frame 3, wherein the control button 2 is connected with the support frame 3, and the conveyor belt 1 is arranged at the upper end of the support frame 3; the conveyor belt 1 comprises an upper contact plate 11, a linkage belt 12 and a power frame 13, wherein the upper contact plate 11 is installed on the outer surface of the linkage belt 12, and the linkage belt 12 is movably clamped with the power frame 13.

The upper touch plate 11 comprises a lower sliding plate a1, a pulling strip a2, an outward pushing mechanism a3, a bottom plate a4 and a plate body a5, wherein the lower sliding plate a1 is movably clamped with the plate body a5, the pulling strip a2 is installed between the lower sliding plate a1 and the plate body a5, the outward pushing mechanism a3 and the bottom plate a4 are of an integrated structure, the plate body a5 is embedded in the upper surface of the bottom plate a4, the number of the lower sliding plates a1 is two, the two lower sliding plates a2 are uniformly and symmetrically distributed on the plate body a5, and a downward pulling force is generated on the lower sliding plate a1 through nuts, so that the lower sliding plate a1 can slide downwards along the plate body a 5.

The lower sliding plate a1 comprises an overhanging plate a11, a contracting plate a12, a connecting piece a13 and a bearing plate a14, the left side of the overhanging plate a11 is fixedly connected with the bearing plate a14 in an embedded mode, the overhanging plate a11 is in clearance fit with the contracting plate a12, the contracting plate a12 is connected with the bearing plate a14 through the connecting piece a13, three overhanging plates a11 are arranged and are uniformly distributed on the right side of the bearing plate a14 in parallel, and the outer side of the overhanging plate a11 can be tightly attached to the surface of a nut through extrusion of the nut on the contracting plate a 12.

The outer extending plate a11 comprises an engaging frame b1, a grabbing block b2, a boosting ring b3 and a rear plate b4, the engaging frame b1 is movably clamped with the rear plate b4, the grabbing block b2 is embedded at the right position of the engaging frame b1, the boosting ring b3 is installed between the engaging frame b1 and the rear plate b4, the grabbing block b2 is provided with two blocks, the two blocks are uniformly distributed on the right side of the engaging frame b1 in a symmetrical mode, and friction force on the surface of the nut can be enhanced through a pulling strip a 2.

The detailed use method and action of the embodiment are as follows:

in the invention, the nuts standing on the upper side of the conveyor belt 1 enter between the two lower sliding plates a1 on the upper touch plate 11 and then pull the two lower sliding plates a1 downwards, so that the lower sliding plates a1 can slide downwards along the plate body a5, so that the two lower sliding plates a1 can press the nuts standing on the side, and the contraction plate a12 can be contracted leftwards under the coordination of the connecting piece a13 by the reverse thrust generated by the nuts standing on the side to the contraction plate a12, so that the outer part of the outer extending plate a11 can be attached to the outer surface of the side nut, and then the pushing ring b3 generates outward pushing force to the connecting frame b1, so that the gripping block b2 can be closely attached to the side nut, therefore, the grabbing force of the overhanging plate a11 to the laterally standing nuts can be enhanced, and the situation that the laterally standing nuts on the conveyor belt 1 roll along with the advance of the upper contact plate 11 on the conveyor belt 1 and even fall to the ground is effectively avoided.

Example 2

As shown in fig. 6-8:

the outward pushing mechanism a3 comprises an extension plate c1, a fixed frame c2, an upper pushing plate c3 and a transition block c4, wherein the extension plate c1 is embedded at the upper end position of the transition block c4, the upper pushing plate c3 is installed at the bottom position of the inner wall of the transition block c4 and the fixed frame c2, the transition block c4 is movably clamped with the fixed frame c2, the extension plate c1 can be contracted downwards under the matching of the transition block c4 through the pressure generated by a nut on the extension plate c1, and the extension plate c1 can be gradually pushed upwards to ascend through the upper pushing plate c3 when the nut is taken upwards.

The extension plate c1 comprises a middle connecting piece c11, a bottom plate c12 and an upper swinging plate c13, the middle connecting piece c11 is installed between two upper swinging plates c13, the upper swinging plate c13 is hinged to the upper end of the bottom plate c12, the two upper swinging plates c13 are arranged and are uniformly distributed at the upper end of the bottom plate c12 in a symmetrical mode, and the upper swinging plate c13 can swing upwards along the bottom plate c12 through the inertia force generated by upward extension of the mechanism.

The upper swing plate c13 comprises a contact plate d1, an outer pushing piece d2, a plate d3 and a bearing plate d4, the contact plate d1 and the bearing plate d4 are of an integrated structure, the bearing plate d4 is movably clamped with the plate d3 through the outer pushing piece d2, the contact plate d1 is made of nitrile rubber with high density, and extrusion force on a nut can be enhanced through the contact plate d 1.

The detailed use method and action of the embodiment are as follows:

in the invention, because the friction force generated by the gripping block b2 on the nut is larger, the nut with smaller volume is difficult to pull out due to small contact area with the fingers of the worker, as the small-sized nuts between the two lower sliding plates a1 are pulled upward, the upper push plate c3 can gradually push the protrusion plate c1 to protrude upward along the fixed frame c2 in cooperation with the transition block c4, thereby the extending plate c1 can push out the nut from top to bottom, and the upper swinging plate c13 can swing upwards along the bottom opening plate c12 by the extrusion of the nut between the two upper swinging plates c13, so that the upper swing plate c13 can press the nut, and thus the upper swing plate c13 can cooperate with the contact plate d1 to push the nut upward, so that the worker can easily take out the nut with smaller volume upwards, and the situation that the nut with smaller volume between the two lower sliding plates a1 is difficult to directly take out is effectively avoided.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.

Claims (7)

1. The utility model provides an intelligence directly drives belt assembly line, its structure includes conveyer belt (1), control button (2), support frame (3), control button (2) are connected its characterized in that with support frame (3): the conveyor belt (1) is arranged at the upper end of the support frame (3);

the conveying belt (1) comprises an upper contact plate (11), a linkage belt (12) and a power frame (13), wherein the upper contact plate (11) is installed on the outer surface of the linkage belt (12), and the linkage belt (12) is movably clamped with the power frame (13).

2. The intelligent direct-drive belt production line of claim 1, characterized in that: go up touch-sensitive plate (11) and include slide down (a1), pull back strip (a2), extrapolation mechanism (a3), bottom plate (a4), plate body (a5), slide down (a1) and plate body (a5) activity block, pull back strip (a2) and install down between slide (a1) and plate body (a5), extrapolation mechanism (a3) and bottom plate (a4) are the integral structure, plate body (a5) is embedded and is fixed in the upper surface position of bottom plate (a 4).

3. The intelligent direct-drive belt production line of claim 2, characterized in that: the lower sliding plate (a1) comprises an outer extending plate (a11), a contraction plate (a12), a connecting piece (a13) and a bearing plate (a14), wherein the left side of the outer extending plate (a11) is fixedly connected with the bearing plate (a14), the outer extending plate (a11) is in clearance fit with the contraction plate (a12), and the contraction plate (a12) is connected with the bearing plate (a14) through the connecting piece (a 13).

4. The intelligent direct drive belt production line of claim 3, wherein: the outer extending plate (a11) comprises a connecting frame (b1), a grabbing force block (b2), a boosting ring (b3) and a rear plate (b4), the connecting frame (b1) is movably clamped with the rear plate (b4), the grabbing force block (b2) is embedded and fixed at the right side position of the connecting frame (b1), and the boosting ring (b3) is installed between the connecting frame (b1) and the rear plate (b 4).

5. The intelligent direct-drive belt production line of claim 2, characterized in that: the outward pushing mechanism (a3) comprises an extension plate (c1), a fixed frame (c2), a push-up plate (c3) and a transition block (c4), wherein the extension plate (c1) is embedded at the upper end position of the transition block (c4), the push-up plate (c3) is installed at the bottom position of the inner walls of the transition block (c4) and the fixed frame (c2), and the transition block (c4) is movably clamped with the fixed frame (c 2).

6. The intelligent direct-drive belt production line of claim 5, wherein: the extension plate (c1) comprises a middle connecting piece (c11), a bottom plate (c12) and an upper swinging plate (c13), wherein the middle connecting piece (c11) is installed between the two upper swinging plates (c13), and the upper swinging plate (c13) is hinged with the upper end of the bottom plate (c 12).

7. The intelligent direct drive belt production line of claim 6, wherein: the upper swing plate (c13) comprises a contact plate (d1), an outer pushing piece (d2), a plate block (d3) and a bearing plate (d4), the contact plate (d1) and the bearing plate (d4) are of an integrated structure, and the bearing plate (d4) is movably clamped with the plate block (d3) through the outer pushing piece (d 2).

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