CN113120523A

CN113120523A - High-speed belt assembly line

Info

Publication number: CN113120523A
Application number: CN202110484141.5A
Authority: CN
Inventors: 陈国发
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-04-30
Filing date: 2021-04-30
Publication date: 2021-07-16

Abstract

The invention discloses a high-speed belt assembly line, which structurally comprises a rack, a driving box, a transmission box, an assembly line, an adaptive structure and an adjusting plate, wherein the adjusting plate is arranged at the lower end of the assembly line, the adjusting plate is embedded and arranged between the racks, the driving box is vertically arranged at the lower end of the assembly line, the driving box is connected with the assembly line through the transmission box, the adaptive structure is horizontally arranged at the upper end of the assembly line and comprises an installation block, a side lever, an adjusting groove and an adaptive plate, the side lever is vertically arranged at the upper end of the installation block, the adjusting groove is arranged on the inner side of the side lever, and the adaptive plate is horizontally arranged between the side levers; set up between front bezel and outer edge plate and continue to connect the structure, make it when carrying out the transition transport, more steady smooth and easy, improved the transport effect of goods.

Description

High-speed belt assembly line

Technical Field

The invention belongs to the field of belt production lines, and particularly relates to a high-speed belt production line.

Background

In present goods transport transmission, adopt the belt assembly line usually to carry out short distance's transportation to these goods to save artifical and improve work efficiency, and along with the goods that carry the transport increase, for the speed that improves the transport, and then derived high-speed belt assembly line, accelerate the speed of transport, but prior art has following not enough:

because the belt assembly line of turning over downwards forms level and two faces of downward sloping, makes to have the angular difference between it to this when carrying out high-speed transmission, the goods will be along with the horizontal plane to the inclined plane removal, will receive inertial influence and directly drop on the inclined plane, cause inboard goods impaired, influence transport effect.

The present application thus provides a high speed belt line that ameliorates the above-mentioned deficiencies.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a high-speed belt assembly line to solve the problems that in the prior art, due to the fact that a belt assembly line which is turned over downwards forms two horizontal and downward inclined surfaces, and an angle difference exists between the two surfaces, when high-speed transmission is carried out, goods move towards an inclined surface along with the horizontal surface, and directly fall onto the inclined surface under the influence of inertia, so that the goods on the inner side are damaged, and the carrying effect is influenced.

In order to achieve the purpose, the invention is realized by the following technical scheme: a high-speed belt assembly line structurally comprises a rack, driving boxes, transmission boxes, an assembly line, an adaptive structure and an adjusting plate, wherein the adjusting plate is installed at the lower end of the assembly line and fixedly connected with the lower end of the assembly line, the adjusting plate is embedded between the rack and movably connected with the rack, the driving boxes are vertically installed at the lower end of the assembly line and mechanically connected with the assembly line, the driving boxes are connected with the assembly line through the transmission boxes, and the adaptive structure is horizontally installed at the upper end of the assembly line and fixed through bolts; the adaptive structure comprises an installation block, side rods, an adjusting groove and an adaptive plate, wherein the side rods are vertically installed at the upper end of the installation block and welded together, the adjusting groove is arranged on the inner side of the side rods and is of an integrated structure, and the adaptive plate is horizontally installed between the side rods and is movably connected with the adjusting groove.

The invention is further improved, the adaptive plate comprises a front plate, a guide structure, a movable block, a splicing structure, an outer edge plate and an adjusting block, the guide structure is embedded and installed at the lower end of the front plate and is movably connected, the movable block is fixed at two sides of the front plate and is movably connected with the adjusting groove, the outer edge plate is embedded and installed at the inner side of the front plate and is connected with the front plate through the adjusting block, and the splicing structure is fixed on the front plate and is movably connected with the outer edge plate.

The invention is further improved, the guide structure comprises a support, outer arc plates, rolling shafts and a rotating structure, the outer arc plates are arranged on the outer side of the support and are welded with each other, the rolling shafts are embedded in the inner sides of the outer arc plates and are connected by hinges, and the rotating structure is embedded in the inner sides of the support and is clamped with each other.

The invention is further improved, the rotating structure comprises an outer ring, a movable structure, an outer spring and an inner disc, the movable structure is abutted against the inner side of the outer ring and is movably connected, the outer spring is embedded and installed on the inner side of the outer ring and is abutted against the outer side of the movable structure, and the inner disc is sleeved on the inner side of the outer ring and is fixedly connected with the movable structure.

The invention is further improved, the movable structure comprises a mounting plate, a movable block, an adaptive frame, a sliding block and an inner spring, the mounting plate is mounted on the left side of the movable block and welded with the movable block, the movable block is embedded and mounted on the inner side of the adaptive frame and movably connected with the adaptive frame, the sliding block is fixed on the right side of the adaptive frame and welded with the adaptive frame, and the inner spring is arranged on the inner side of the adaptive frame and abutted between the movable block and the sliding block.

The invention is further improved, the splicing structure comprises embedding blocks, linkage plates and guide shafts, the embedding blocks are fixed on the outer sides of the linkage plates and are welded with the linkage plates, the linkage plates are connected through hinges, and the guide shafts are embedded between the linkage plates and are movably connected.

The invention is further improved, the linkage plate comprises plate bodies, pressing plates, rotating shafts and springs, the plate bodies are movably connected through the rotating shafts, the pressing plates are embedded in the inner sides of the rotating shafts and clamped, and the springs are embedded in the inner sides of the plate bodies and one ends of the springs are abutted to the pressing plates.

The invention is further improved, the moving angle between the plate bodies is 0-90 degrees, the moving directions of the plate bodies in the same row are the same, and springs are arranged between the plate bodies for matching the pressing plates.

According to the technical scheme, the high-speed belt assembly line has the following beneficial effects:

the invention is provided with an adaptive structure at the upper end of the production line, the support is stressed and extruded under the guidance of the outer arc plate to push the rotary structure, the outer ring is stressed to push the movable structure, so that the movable block and the adaptive frame move relatively, the inner spring is extruded to achieve the buffering effect, the sliding block can move at the inner side of the outer ring along with the deviation of the goods, the outer spring is extruded to ensure the timely reset of the outer arc plate integrally, the goods are conveyed stably at the upper end, and the inertia of the goods is buffered, so that the completeness of the goods is ensured.

The invention sets a continuous structure between the front plate and the outer edge plate, the embedded block pulls the linkage plate to enable the plate bodies to rotate relatively around the rotating shaft, and drives the pressing plate to extrude the spring, so that the plate bodies form an arc shape, thus completing adjustment and conveying goods.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic structural view of a high speed belt line of the present invention;

FIG. 2 is a schematic diagram of a compliant structure according to the present invention;

FIG. 3 is a schematic view of a structure of a compliant plate according to the present invention;

FIG. 4 is a schematic structural view of a guide structure according to the present invention;

FIG. 5 is a schematic structural view of a rotary structure of the present invention;

FIG. 6 is a schematic structural view of the mobile structure of the present invention;

FIG. 7 is a schematic structural view of a splicing structure according to the present invention;

FIG. 8 is a schematic structural view of a linkage plate according to the present invention.

In the figure: a frame-1, a driving box-2, a transmission box-3, a production line-4, an adaptation structure-5, an adjustment plate-6, a mounting block-51, a side lever-52, an adjustment groove-53, an adaptation plate-54, a front plate-541, a guide structure-542, a movable block-543, a splicing structure-544, an outer edge plate-545, an adjustment block-546, a bracket-42 a, an outer arc plate-42 b, a roller-42 c, a rotation structure-42 d, an outer ring-d 1, a movable structure-d 2, an outer spring-d 3, an inner disc-d 4, a mounting plate-d 21, a movable block-d 22, an adaptation frame-d 23, a sliding block-d 24, an inner spring-d 25, an embedding block-44 a, a linkage plate-44 b, a guide shaft-44 c, an adjustment plate-546, a support plate-42 b, a rotation, Plate body-b 1, pressure plate-b 2, rotating shaft-b 3 and spring-b 4.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

The first embodiment is as follows: referring to fig. 1-6, the embodiments of the present invention are as follows:

the structure of the device comprises a rack 1, driving boxes 2, transmission boxes 3, a production line 4, an adaptive structure 5 and an adjusting plate 6, wherein the adjusting plate 6 is installed at the lower end of the production line 4 and fixedly connected with the lower end of the production line 4, the adjusting plate 6 is embedded between the rack 1 and movably connected with the rack, the driving boxes 2 are vertically installed at the lower end of the production line 4 and mechanically connected with the lower end of the production line 4, the driving boxes 2 and the production line 4 are connected through the transmission boxes 3, and the adaptive structure 5 is horizontally installed at the upper end of the production line 4 and fixed; the adaptive structure 5 comprises a mounting block 51, a side rod 52, an adjusting groove 53 and an adaptive plate 54, wherein the side rod 52 is vertically mounted at the upper end of the mounting block 51 and welded with the mounting block, the adjusting groove 53 is arranged inside the side rod 52 and is an integrated structure, and the adaptive plate 54 is horizontally mounted between the side rods 52 and movably connected with the adjusting groove 53.

Referring to fig. 3, the adapting plate 54 includes a front plate 541, a guiding structure 542, a movable block 543, a connecting structure 544, an outer edge plate 545 and an adjusting block 546, the guiding structure 542 is embedded in the lower end of the front plate 541 and is movably connected, the movable block 543 is fixed on both sides of the front plate 541 and is movably connected with the adjusting slot 53, the outer edge plate 545 is embedded in the inner side of the front plate 541 and is connected with the front plate 541 through the adjusting block 546, the connecting structure 544 is fixed on the front plate 541 and is movably connected with the outer edge plate 545, and the position can be adjusted according to the size of the goods, so as to adapt to the transportation of the goods with different sizes, preliminarily limit the entering goods and make them more stable.

Referring to fig. 4, the guiding structure 542 includes a bracket 42a, an outer arc plate 42b, a roller 42c, and a rotating structure 42d, the outer arc plate 42b is installed outside the bracket 42a and welded to the outer arc plate, the roller 42c is installed inside the outer arc plate 42b in an embedded manner and connected to the outer arc plate by a hinge, and the rotating structure 42d is embedded inside the bracket 42a and clamped to the outer arc plate, and guides and buffers the outer arc plate when entering, so as to better enter.

Referring to fig. 5, the rotating structure 42d includes an outer ring d1, a movable structure d2, an outer spring d3, and an inner disc d4, the movable structure d2 abuts against the inner side of the outer ring d1 and is movably connected to the outer ring d1, the outer spring d3 is embedded in the outer ring d1 and abuts against the outer side of the movable structure d2, and the inner disc d4 is sleeved on the inner side of the outer ring d1 and is fixedly connected to the movable structure d2, and can move and adjust along with the extrusion of goods, so that the goods can be conveniently fed in.

Referring to fig. 6, the movable structure d2 includes a mounting plate d21, a movable block d22, an adaptive frame d23, a sliding block d24 and an inner spring d25, the mounting plate d21 is mounted on the left side of the movable block d22 and welded thereto, the movable block d22 is embedded inside the adaptive frame d23 and movably connected thereto, the sliding block d24 is fixed on the right side of the adaptive frame d23 and welded thereto, the inner spring d25 is disposed inside the adaptive frame d23 and abuts between the movable block d22 and the sliding block d24, and the lateral force can be squeezed and buffered while swinging.

Based on the above embodiment, the specific working principle is as follows:

the adaptive structure 5 is adjusted according to the height of the goods, the adaptive plate 54 is integrally adjusted on the adjusting groove 53 between the side bars 52, the adjusting block 546 is rotated to adjust the angle between the outer edge plate 545 and the front plate 541, so that the whole is parallel to the production line 4, the operation can be started, the driving box 2 drives the production line 4 connected with the transmission box 3 to work, the goods can be placed at the upper end of the production line 4, the transportation can be started, the goods can enter the lower end of the adaptive plate 54 from between the side bars 52 along with the approach of the adaptive structure 5, at this time, the goods are firstly contacted with the guide structure 542 and are guided by the outer arc plate 42b, the support 42a is pressed by force, the rotating structure 42d is pushed, the outer ring d1 is wholly forced to push the movable structure d2, the relative movement between the movable block d22 and the adaptive frame d23 is pushed, and the inner spring d25 is further pressed to achieve the buffering effect, and along with the deviation of goods, the sliding block d24 can also move on the inner side of the outer ring d1, the outer spring d3 is also squeezed to ensure that the outer arc plate 42b is reset in time, the sliding block can continuously move inwards along the matching of the rolling shaft 42c, and then the goods can be conveyed downwards in an angle-changing and inclined manner through the front plate 541, the continuous structure 544 and the outer edge plate 545, so that the goods can be conveyed circularly.

Example two: referring to fig. 3, 7-8, the embodiment of the present invention is as follows:

the adaptive plate 54 comprises a front plate 541, a guide structure 542, a movable block 543, a continuous structure 544, an outer edge plate 545 and an adjusting block 546, wherein the guide structure 542 is embedded in the lower end of the front plate 541 and movably connected, the movable block 543 is fixed on two sides of the front plate 541 and movably connected with the adjusting groove 53, the outer edge plate 545 is embedded in the inner side of the front plate 541 and connected with the inner side of the front plate 541 through the adjusting block 546, and the continuous structure 544 is fixed on the front plate 541 and movably connected with the outer edge plate 545.

Referring to fig. 7, the splicing structure 544 includes an embedded block 44a, a linkage plate 44b, and a guide shaft 44c, the embedded block 44a is fixed outside the linkage plate 44b and welded thereto, the linkage plate 44b is connected with each other by a hinge, and the guide shaft 44c is embedded between the linkage plates 44b and movably connected to guide the position of the connection in an arc shape, so as to adapt to the adjusted outer edge plate 545 and facilitate guiding to an inclined assembly line.

Referring to fig. 8, the linkage plate 44b includes a plate body b1, a pressing plate b2, a rotating shaft b3 and a spring b4, the plate body b1 is movably connected through a rotating shaft b3, the pressing plate b2 is embedded in the rotating shaft b3 and clamped, the spring b4 is embedded in the plate body b1, one end of the spring is abutted to the pressing plate b2, and the spring b4 can swing and adapt to the outer edge plate 545 to form a combined arc-like shape so as to facilitate guiding.

Referring to fig. 8, the moving angle between the plate bodies b1 is 0-90 degrees, the moving direction of the plate bodies b1 in the same row is the same, and springs b4 are arranged between the plate bodies b1 to match with the pressing plates b2, so that the angles can be changed along with adjustment, and the rotating shafts b3 between the plate bodies can guide goods better.

Based on the above embodiment, the specific working principle is as follows:

when the adjusting block 546 is adjusted, the angle between the front plate 541 and the outer edge plate 545 is changed, and the adjusting block 546 is driven to drive the outer continuous connection structure 544, the embedded block 44a pulls the linkage plate 44b, so that the plate body b1 relatively rotates around the rotating shaft b3, and drives the pressing plate b2 to press the spring b4, so that the plate body b1 forms a similar arc shape, and thus the adjustment is completed, and the goods are conveyed, and are guided along the guide shaft 44c between the linkage plates 44b, so as to transition to the outer edge plate 545, and are conveyed out, and thus the goods are conveyed circularly.

The invention solves the problem that in the prior art, because a belt assembly line which is turned downwards forms two horizontal and downward inclined surfaces, an angle difference exists between the two surfaces, when the belt assembly line is transmitted at high speed, goods move along with the horizontal surface to the inclined surface and directly fall on the inclined surface under the influence of inertia, so that the goods at the inner side are damaged, and the carrying effect is influenced, through the mutual combination of the components, an adaptive structure is arranged at the upper end of the assembly line, a support is extruded under the guidance of an outer arc plate under the stress, so that the support is pushed to push a rotating structure, the whole outer ring pushes the movable structure under the stress, and the relative movement between the movable block and the adaptive frame is further extruded to achieve the buffering effect by extruding an inner spring, and a sliding block can also move at the inner side of the outer ring along with the deviation of the goods, the outer spring is also extruded to ensure the timely reset of the whole outer, the goods are stably conveyed at the upper end, and the inertia of the goods is buffered, so that the completeness of the goods is ensured; set up continuous structure of connecing between front bezel and outer edge plate, inlay piece pulling linkage plate, make between the plate body carry out relative rotation round the axis of rotation with this, and drive the clamp plate and come the extrusion spring, it is circular-arc-like to make to form between the plate body, can accomplish the regulation, carry out the transport of goods, along with the touching adaptation board of goods, and move inwards along guide structure's direction, and get into the front bezel and begin to contact continuous structure of connecing, and then lead along the guiding axle between the linkage plate, with this transition to outer edge plate, make it when transiting the transport, more steady smooth and easy, the transport effect of goods has been improved.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims

1. A high-speed belt assembly line structurally comprises a rack (1), a driving box (2), a transmission box (3), an assembly line (4), an adaptation structure (5) and an adjusting plate (6), wherein the adjusting plate (6) is installed at the lower end of the assembly line (4), the adjusting plate (6) is installed between the rack (1) in an embedded mode, the driving box (2) is vertically installed at the lower end of the assembly line (4), the driving box (2) is connected with the assembly line (4) through the transmission box (3), and the adaptation structure (5) is horizontally installed at the upper end of the assembly line (4); the method is characterized in that:

the adaptive structure (5) comprises an installation block (51), side rods (52), an adjusting groove (53) and an adaptive plate (54), wherein the side rods (52) are vertically installed at the upper ends of the installation block (51), the adjusting groove (53) is arranged on the inner sides of the side rods (52), and the adaptive plate (54) is horizontally installed between the side rods (52).

2. A high speed belt line as in claim 1, wherein: the adaptive plate (54) comprises a front plate (541), a guide structure (542), a movable block (543), a splicing structure (544), an outer edge plate (545) and an adjusting block (546), wherein the guide structure (542) is embedded and mounted at the lower end of the front plate (541), the movable block (543) is fixed at two sides of the front plate (541), the outer edge plate (545) is embedded and mounted at the inner side of the front plate (541) and connected with the front plate through the adjusting block (546), and the splicing structure (544) is fixed on the front plate (541).

3. A high speed belt line as claimed in claim 2, wherein: the guide structure (542) comprises a support (42a), an outer arc plate (42b), a rolling shaft (42c) and a rotating structure (42d), wherein the outer arc plate (42b) is installed on the outer side of the support (42a), the rolling shaft (42c) is installed on the inner side of the outer arc plate (42b) in an embedded mode, and the rotating structure (42d) is embedded on the inner side of the support (42 a).

4. A high speed belt line as claimed in claim 3, wherein: the rotating structure (42d) comprises an outer ring (d1), a movable structure (d2), an outer spring (d3) and an inner disc (d4), the movable structure (d2) abuts against the inner side of the outer ring (d1), the outer spring (d3) is embedded and mounted on the inner side of the outer ring (d1), and the inner disc (d4) is sleeved on the inner side of the outer ring (d 1).

5. A high speed belt line as in claim 4 wherein: the movable structure (d2) includes mounting panel (d21), movable block (d22), adaptation frame (d23), sliding block (d24), inner spring (d25), mounting panel (d21) are installed in movable block (d22) left side, movable block (d22) embedding is installed in adaptation frame (d23) inboard, sliding block (d24) are fixed in adaptation frame (d23) right side, inner spring (d25) are located and are adapted frame (d23) inboard.

6. A high speed belt line as claimed in claim 2, wherein: the continuous connection structure (544) comprises an embedded block (44a), linkage plates (44b) and guide shafts (44c), the embedded block (44a) is fixed on the outer sides of the linkage plates (44b), the linkage plates (44b) are connected through hinges, and the guide shafts (44c) are embedded between the linkage plates (44 b).

7. A high speed belt line as in claim 6 wherein: linkage board (44b) is including plate body (b1), clamp plate (b2), axis of rotation (b3), spring (b4), through axis of rotation (b3) swing joint between plate body (b1), clamp plate (b2) embedding is installed in axis of rotation (b3) inboard, spring (b4) embedding is inboard in plate body (b 1).

8. A high speed belt line as in claim 7 wherein: the movable angle between the plate bodies (b1) is 0-90 degrees, the movable direction of the plate bodies (b1) in the same row is the same, and springs (b4) are arranged between the plate bodies (b1) to match the pressure plate (b 2).