CN116812526A - Flow dividing device - Google Patents

Abstract

The invention provides a flow dividing device, which relates to the technical field of mechanical equipment production and comprises a mounting seat, an migration assembly, a first driving piece and a distributing piece, wherein the migration assembly is arranged on the mounting seat; the first driving piece is connected with the migration assembly, and the migration assembly is used for driving the first driving piece to move along a first direction; the first driving piece is connected with the first driving piece, the first driving piece is provided with an extending state and a lifting state, the first driving piece is switched to drive the first driving piece to move along a second direction, the first direction is intersected with the second direction, when the first driving piece is in the extending state, the workpiece is located on a movement track of the distributing piece, and when the first driving piece is in the lifting state, the workpiece is located outside the movement track of the distributing piece. The conveying channel cannot be occupied all the time in the using process of the flow distribution device, and the smoothness of the assembly line workpiece during flow distribution is guaranteed.

Description

Flow dividing device

Technical Field

The invention relates to the technical field of mechanical equipment production, in particular to a flow dividing device.

Background

At present, the industrial production basically uses a production line for production and manufacturing, the production line is short for flow production operation, and workers are responsible for a certain production or manufacturing procedure on one production line, so that the purpose that the workers are skilled in the responsible procedure is achieved, and the aim of improving the production efficiency is achieved. In the running process of the production line, the workpieces on the main production line are required to be split frequently, and after the workpieces are split to different production lines, the same manufacturing process can be performed simultaneously, so that the production efficiency is improved, or different manufacturing processes are performed on different production lines to produce different products.

The conveying mechanism is provided with a conveying channel for conveying the workpieces, and when the current assembly line splitting device performs splitting, the splitting assembly occupies a part of the space for conveying the workpieces on the conveying channel, so that the space for conveying the workpieces by the conveying channel is reduced. When the work piece on transport mechanism passes through the reposition of redundant personnel subassembly, because the transfer passage part is occupied by the reposition of redundant personnel subassembly, the work piece card easily appears and blocks up in diverging device's reposition of redundant personnel mouth department, causes the jam of assembly line, influences the smoothness nature and the efficiency of work piece conveying in the production line. The above problems can be solved by widening the width of the conveying channel, but widening the width of the conveying channel increases the cost of manufacturing the conveying mechanism, which increases the cost of manufacturing the product, and the problem that the diverting assembly occupies the conveying channel space of the conveying mechanism needs to be solved so as to ensure the smoothness of the production line and the profit margin of the product manufacturing.

Disclosure of Invention

In view of the above-mentioned drawbacks of the prior art, an object of the present invention is to provide a splitting device, which is used for solving the problem that the current splitting assembly occupies the space of a conveying channel of a conveying mechanism in the prior art, and is easy to cause workpiece blocking and difficult to continue conveying when the splitting device splits.

To achieve the above and other related objects, the present invention provides a flow dividing device comprising:

a mounting base;

the migration assembly is arranged on the mounting seat;

the first driving piece is connected with the migration assembly, and the migration assembly is used for driving the first driving piece to move along a first direction;

the distributing piece is connected with the first driving piece;

the first driving part is provided with an extending state and a lifting state, the first driving part drives the distributing part to move along a second direction by switching the state of the first driving part, the first direction is intersected with the second direction,

when the first driving piece is in an extending state, the workpiece is located on the motion track of the distributing piece, the distributing piece is driven by the moving component to split the workpiece, when the first driving piece is in a lifting state, the workpiece is located outside the motion track of the distributing piece, and the distributing piece is driven by the moving component to pass through the workpiece.

Optionally, the migration subassembly includes action wheel, inert wheel and belt loop, follows the first direction, the action wheel with inert wheel interval sets up on the mount pad, the action wheel with the inert wheel all sets up the inboard of belt loop and will the belt loop struts, the action wheel passes through the belt loop drives the inert wheel is around the axis rotation of inert wheel.

Optionally, the shunt device further comprises a limiting support assembly, wherein the limiting support assembly is arranged on the mounting seat and used for limiting the movement track of the distributing piece.

Optionally, the spacing support assembly includes a spacing track and a spacing piece that set up along the first direction, spacing piece sliding connection is in on the spacing track, the spacing piece with first driving piece is connected.

Optionally, a limiting groove is formed in the limiting piece, the limiting piece is clamped on the limiting track through the limiting groove, and the setting direction of the limiting groove is the same as the extending direction of the limiting track.

Optionally, the driving wheel is provided with first tooth circumferentially, the belt loop inboard is provided with first tooth assorted second tooth, the action wheel passes through first tooth with the meshing of second tooth drives the belt loop motion.

Optionally, the idler wheel is circumferentially provided with a third tooth, which meshes with the second tooth on the belt loop.

Optionally, the migration assembly includes a second driving member, the second driving member is a motor, the motor is connected with the driving wheel, and the motor drives the driving wheel to rotate around the central axis of the driving wheel.

Optionally, the shunt device further comprises an inductor, the inductor is arranged on the mounting seat, an induction area of the inductor is located on a motion track of the first driving piece, and the inductor is used for prompting the motor to reduce the rotating speed before the first driving piece stops moving.

Optionally, the first direction is perpendicular to the second direction.

As described above, the shunt device of the present invention has the following beneficial effects:

when the workpiece is split, the first driving piece is switched to an extending state, and the workpiece moves on the moving track of the distributing piece, and the first driving piece drives the distributing piece to move by the moving assembly so as to split the workpiece; when the workpiece is not required to be split, the first driving piece is switched to be in a lifting state, and the workpiece is outside the motion track of the distributing piece, and the distributing piece is driven by the conveying assembly to move beyond the workpiece through the first driving piece. Through setting up the first driving piece that has two kinds of states, make the reposition of redundant personnel subassembly when carrying out reposition of redundant personnel, can switch the state of first driving piece according to needs, shunt the work piece, perhaps cross the work piece after, reverse reposition of redundant personnel is carried out to the work piece. Therefore, the problem that the space for conveying workpieces by the conveying channel is reduced and workpiece blocking is easy to occur due to the fact that the conveying channel is occupied by the splitting device all the time in the splitting process of the splitting device is solved. And the first driving piece with two states can increase the flexibility in the use process of the flow distribution device and ensure the smoothness of flow line workpiece distribution.

Drawings

Fig. 1 is a schematic structural diagram of a shunt device according to an embodiment of the invention.

Fig. 2 shows an exploded view of a shunt device according to an embodiment of the present invention.

Fig. 3 is a schematic view showing the structure of the capstan and the roll of tape in the embodiment of the present invention.

FIG. 4 shows a schematic view of the construction of the idler wheel and roll of tape in an embodiment of the present invention.

Part number description: 1. a mounting base; 2. an migration assembly; 3. a distributing member; 4. a first driving member; 5. a driving wheel; 6. an inert wheel; 7. a belt loop; 8. a limiting piece; 9. a limit rail; 10. a second tooth; 11. a third tooth; 12. a motor; 13. a first inductor; 14. a second inductor; 15. a third inductor; 16. a tow chain assembly; 17. and the limiting support assembly.

Detailed Description

Other advantages and effects of the present invention will become apparent to those skilled in the art from the following disclosure, which describes the embodiments of the present invention with reference to specific examples. The invention may be practiced or carried out in other embodiments that depart from the specific details, and the details of the present description may be modified or varied from the spirit and scope of the present invention.

Please refer to fig. 1 to 4. It should be noted that, the illustrations provided in the present embodiment merely illustrate the basic concept of the present invention by way of illustration, and only the components related to the present invention are shown in the drawings and are not drawn according to the number, shape and size of the components in actual implementation, and the form, number and proportion of the components in actual implementation may be arbitrarily changed, and the layout of the components may be more complex. The structures, proportions, sizes, etc. shown in the drawings attached hereto are for illustration purposes only and are not intended to limit the scope of the invention, which is defined by the claims, but rather by the claims. Also, the terms such as "upper," "lower," "left," "right," "middle," and "a" and the like recited in the present specification are merely for descriptive purposes and are not intended to limit the scope of the invention, but are intended to provide relative positional changes or modifications without materially altering the technical context in which the invention may be practiced.

Referring to fig. 1 and 2, the present invention provides a flow dividing device, which includes a mounting base 1, a moving assembly 2, a first driving member 4 and a distributing member 3; the migration assembly 2 is arranged on the mounting seat 1; the first driving piece 4 is connected with the migration assembly 2, and the migration assembly 2 is used for driving the first driving piece 4 to move along a first direction; the distributing piece 3 is connected with the first driving piece 4; the first driving piece 4 is provided with an extending state and a lifting state, the first driving piece 4 drives the distributing piece 3 to move along the second direction by switching the state of the first driving piece 4, the first direction is intersected with the second direction, when the first driving piece 4 is in the extending state, the workpiece is located on the movement track of the distributing piece 3, the distributing piece 3 is driven by the conveying component 2 to split the workpiece, when the first driving piece 4 is in the lifting state, the workpiece is located outside the movement track of the distributing piece 3, and the distributing component 2 drives the distributing piece 3 to pass over the workpiece. In this embodiment, the first driving member 4 is a cylinder, and the cylinder has a simple structure, is easy to install and maintain, has a large load, and has rapid response and good working environment adaptability. The selection of the first driving member 4 can be adjusted according to the actual production requirements. In this embodiment, the first direction is perpendicular to the second direction. Before the workpiece is split by the splitter 3, a blocking component is arranged on the conveying channel and used for blocking the workpiece to advance continuously so that the workpiece is split by the splitting device.

When the workpiece is split, the first driving piece 4 is switched to an extending state by arranging the migration assembly 2, the first driving piece 4 and the distributing piece 3, and the migration assembly 2 drives the distributing piece 3 to move through the first driving piece 4 so as to split the workpiece; when the workpiece is not required to be split, the first driving piece 4 is switched to be in a lifting state, and the workpiece is outside the movement range of the distributing piece 3, the conveying assembly 2 drives the distributing piece 3 through the first driving piece 4 and moves beyond the workpiece. The first driving piece 4 with two states is arranged in the shunting device, and when a workpiece needs to be shunted, the first driving piece 4 is switched to an extending state for shunting; when the workpiece is required to be split in the direction opposite to the movement direction of the distributing member 3, the first driving member 4 can be switched to a lifted state, and after the workpiece passes over the other side of the workpiece, the first driving member 4 is switched to an extended state to split the workpiece. The first driving piece 4 has two states, so that the flexibility of the flow dividing device in the use process can be increased, and the flow dividing smoothness of the assembly line workpiece is ensured.

The migration assembly 2 comprises a driving wheel 5, an inert wheel 6 and a belt ring 7, the driving wheel 5 and the inert wheel 6 are arranged on the mounting seat 1 at intervals along the first direction, the driving wheel 5 and the inert wheel 6 are arranged on the inner side of the belt ring 7 and are used for stretching the belt ring 7, and the driving wheel 5 drives the inert wheel 6 to rotate around the central axis of the inert wheel 6 through the belt ring 7. The driving wheel 5, the inert wheel 6 and the belt loop 7 are utilized for transmission, the structure is simple, and the operation is convenient.

The migration assembly 2 comprises a second driving piece, the second driving piece is a motor 12, the motor 12 is connected with the driving wheel 5, and the motor 12 drives the driving wheel 5 to rotate around the central axis of the driving wheel 5. The motor 12 has the advantages of convenient use and control, high working efficiency, reliable operation, low price and the like, has the functions of self-starting, accelerating, braking, reversing and the like, and can meet various operation requirements. The motor 12 is used for driving the driving wheel 5, so that the distributing part 3 can reciprocate on the migration assembly 2, and the flexibility of the use of the distribution assembly is improved. The selection of the second driving member can be adjusted according to actual requirements.

Specifically, as shown in fig. 3 and 4, a first tooth is circumferentially arranged on the driving wheel 5, a second tooth 10 matched with the first tooth is arranged on the inner side of the belt loop 7, and the driving wheel 5 is meshed with the second tooth 10 through the first tooth to drive the belt loop 7 to move. The idler wheel 6 is circumferentially provided with a third tooth 11, the third tooth 11 being in engagement with a second tooth 10 on the belt loop 7. Be provided with on the belt loop 7 with action wheel 5 and inertia wheel 6 engaged second tooth 10, when action wheel 5 drove inertia wheel 6 motion, promote action wheel 5 and belt loop 7's conveying precision, guarantee the reposition of redundant personnel effect of allocating the piece, avoid appearing the condition that belt loop 7 and action wheel 5 skid.

The flow dividing device further comprises a limiting support assembly 17, wherein the limiting support assembly 17 is arranged on the mounting seat 1, and the limiting support assembly 17 is used for limiting the movement track of the distributing part 3. When the belt loop 7 drives the distributing part 3 and the first driving part 4 to move, due to the influence of gravity of the distributing part 3 and the first driving part 4, the belt loop 7 at the first driving part 4 can deform along the gravity direction of the distributing part 3 and the first driving part 4, so that the moving track of the first driving part 4 changes, and the distributing effect of the first driving part 4 is influenced. After the limiting support assembly 17 is added to limit the running direction of the distributing part 3, the distributing part 3 is ensured to move on a preset movement track.

In detail, the limit supporting assembly 17 includes a limit rail 9 and a limit member 8 disposed along the first direction, the limit member 8 is slidably connected to the limit rail 9, and the limit member 8 is connected to the first driving member 4. In this embodiment, a limiting groove is formed in the limiting piece 8, the limiting piece 8 is clamped on the limiting rail 9 through the limiting groove, and the opening direction of the limiting groove is the same as the extending direction of the limiting rail 9. The limiting groove is matched with the limiting track 9, the movement track of the first driving piece 4 and the distributing piece 3 is limited, the contact area between the limiting groove and the limiting track 9 can be increased in the limiting process, so that the limiting track 9 can uniformly distribute the gravity of the distributing piece 3 and the first driving piece 4, the smoothness of the distributing piece 3 and the first driving piece 4 in the movement along the first direction is ensured, and the service life of the limiting track 9 in use is prolonged. In other embodiments, the mounting base 1 is provided with a strip-shaped sliding groove extending along the first direction, a sliding block sliding in the sliding groove is arranged in the sliding groove, the sliding block is connected with the first driving piece 4, and the sliding block and the sliding groove cooperate to limit the movement track of the distributing piece 3. The setting mode of the limiting component can be adjusted according to actual production requirements.

The shunt device further comprises an inductor, the inductor is arranged on the mounting seat 1, the induction area of the inductor is located on the motion track of the first driving piece 4, and the inductor is used for prompting the motor 12 to reduce the rotating speed before the first driving piece 4 stops moving. In the present embodiment, the drive wheel 5 is driven using the motor 12. When the motor 12 is required to output a high rotation speed to improve the shunt efficiency, if the workpiece is stopped suddenly after reaching a specified position, a rigid collision is generated inside the motor 12, and the motor 12 is damaged. In this embodiment, the mounting base 1 is sequentially provided with three sensors, namely, a first sensor 13, a second sensor 14 and a third sensor 15 along the first direction. The first driving member 4 has a first preset position and a second preset position, and the first driving member 4 reciprocates between the first preset position and the second preset position under the driving of the moving assembly 2. When the first driving member 4 is in the first preset position, the motor 12 is at mechanical zero point, which triggers the first inductor 13. When the first driving member 4 is located at the second preset position, the third sensor 15 may be activated. The second inductor 14 is located on the connection line between the first inductor 13 and the third inductor 15, and is close to the third inductor 15. When the first driving member 4 moves from the first sensor 13 to the third sensor 15, the logic judging module on the current diversion device checks that the sensing signal sent by the first sensor 13 or the third sensor 15 is received before the sensing signal of the second sensor 14 is received when the sensing signal of the second sensor 14 is received. If the logic judgment module receives the induction signal of the third inductor 15, the received induction signal is sent by the first inductor 13, and the logic judgment module will instruct the motor 12 to slow down the rotation speed of the motor 12, so that the first driving member 4 can slow down in advance before moving to the second preset position, and buffer, thereby reducing the damage when the motor 12 suddenly stops running. If the logic judgment module receives the induction signal of the third inductor 15, the received induction signal is sent by the first inductor 13, and the motor 12 is at the mechanical zero point when the first driving part 4 stops at the first preset position, so that no deceleration instruction is required to be made to the motor 12 in advance, so that the logic judgment module does not act. In the present embodiment, the first driving member 4 is a motor. The selection of the first driving member 4 can be adjusted according to the actual movement requirement.

In this embodiment, the installation seat 1 is further provided with a drag chain assembly 16 for dragging and protecting wires, etc., and the drag chain assembly 16 has a simple structure and a good dragging effect, and can prolong the service life of the wires, etc., thereby reducing the maintenance rate of the shunt device and ensuring the stability of the shunt device in use.

The workpiece is divided into a first station and a second station. When the first driving piece 4 is in an extending state and the first driving piece 4 moves from the first preset position to the second preset position, the distributing piece 3 can distribute the workpiece to the second station; when the first driving member 4 is in the extended state, and the first driving member 4 moves from the second preset position to the first preset position, the allocating member 3 may allocate the workpiece to the first station. When the first driving piece 4 is at the first preset position, the workpiece is required to be allocated to the second station, the first driving piece 4 is switched to be in an extending state, the migration assembly 2 drives the first driving piece 4 to move from the first preset position to the second preset position, the allocating piece 3 can allocate the workpiece to the second station, the first driving piece 4 is switched to be in a lifting state, and the shunting operation is completed. When the distributing member 3 is at the first preset position, the workpiece is required to be distributed to the first station, the first driving member 4 is in a lifting state, the first driving member 4 is driven to the second preset position by the migration assembly 2, the first driving member 4 is switched to an extending state, the migration assembly 2 drives the first driving member 4 to move from the second preset position to the first preset position, the distributing member 3 can distribute the workpiece to the first station, the first driving member 4 is switched to the lifting state, and the current distribution work is completed. Therefore, the flow dividing device can realize unidirectional flow division, can realize bidirectional alternate flow division, is convenient and concise to use, has a simple structure, and is easy to overhaul.

In summary, by arranging the transferring assembly 2, the first driving member 4 and the distributing member 3, when the workpiece is split, the first driving member 4 is switched to the extended state, and the workpiece moves on the moving track of the distributing member 3, the transferring assembly 2 drives the distributing member 3 to move through the first driving member 4, so as to split the workpiece; when the workpiece is not required to be split, the first driving piece 4 is switched to a lifting state, and the workpiece is outside the movement track of the distributing piece 3, and the conveying component 2 drives the distributing piece 3 to move beyond the workpiece through the first driving piece 4. By arranging the first driving piece 4 with two states, when the split assembly splits, the state of the first driving piece 4 can be switched according to the requirement to split the workpiece, or after the workpiece is crossed, the workpiece is split reversely. Therefore, the problem that the space for conveying workpieces by the conveying channel becomes small and workpiece blocking is easy to occur due to the fact that the conveying channel is occupied by the splitting device all the time in the splitting process of the splitting device is solved. And the first driving piece 4 with two states can increase the flexibility in the use process of the flow dividing device and ensure the smoothness of the flow line workpiece during flow dividing.

The above embodiments are merely illustrative of the principles of the present invention and its effectiveness, and are not intended to limit the invention. Modifications and variations may be made to the above-described embodiments by those skilled in the art without departing from the spirit and scope of the invention. Accordingly, it is intended that all equivalent modifications and variations of the invention be covered by the claims, which are within the ordinary skill of the art, be within the spirit and scope of the present disclosure.

Claims (10)

1. A shunt device, comprising:

a mounting base;

the migration assembly is arranged on the mounting seat;

the first driving piece is connected with the migration assembly, and the migration assembly is used for driving the first driving piece to move along a first direction;

the distributing piece is connected with the first driving piece;

the first driving part is provided with an extending state and a lifting state, the first driving part drives the distributing part to move along a second direction by switching the state of the first driving part, the first direction is intersected with the second direction,

when the first driving piece is in an extending state, the workpiece is located on the motion track of the distributing piece, the distributing piece is driven by the moving component to split the workpiece, when the first driving piece is in a lifting state, the workpiece is located outside the motion track of the distributing piece, and the distributing piece is driven by the moving component to pass through the workpiece.

2. The shunt device according to claim 1, wherein: the conveying assembly comprises a driving wheel, an inert wheel and a belt ring, the distance between the driving wheel and the inert wheel is arranged on the mounting seat along the first direction, the driving wheel and the inert wheel are both arranged on the inner side of the belt ring and spread the belt ring, and the driving wheel drives the inert wheel to rotate around the central axis of the inert wheel through the belt ring.

3. The shunt device according to claim 2, wherein: the flow dividing device further comprises a limiting support assembly, wherein the limiting support assembly is arranged on the mounting seat and used for limiting the movement track of the distributing piece.

4. A shunt device according to claim 3, wherein: the limiting support assembly comprises a limiting track and a limiting piece, wherein the limiting track and the limiting piece are arranged along the first direction, the limiting piece is connected to the limiting track in a sliding mode, and the limiting piece is connected with the first driving piece.

5. The shunt device according to claim 4, wherein: the limiting piece is provided with a limiting groove, the limiting piece is clamped on the limiting track through the limiting groove, and the setting direction of the limiting groove is the same as the extending direction of the limiting track.

6. The shunt device according to claim 2, wherein: the driving wheel is circumferentially provided with a first tooth, the inner side of the belt loop is provided with a second tooth matched with the first tooth, and the driving wheel is meshed with the second tooth through the first tooth to drive the belt loop to move.

7. The shunt device according to claim 6, wherein: the idler wheel is circumferentially provided with a third tooth which is meshed with the second tooth on the belt ring.

8. The shunt device according to claim 2, wherein: the migration assembly comprises a second driving piece, the second driving piece is a motor, the motor is connected with the driving wheel, and the motor drives the driving wheel to rotate around the central axis of the driving wheel.

9. The shunt device according to claim 8, wherein: the shunt device further comprises an inductor, the inductor is arranged on the mounting seat, an induction area of the inductor is located on a motion track of the first driving piece, and the inductor is used for prompting the motor to reduce the rotating speed before the first driving piece stops moving.

10. The shunt device according to claim 1, wherein: the first direction is perpendicular to the second direction.