CN115367450A - Following type material high-speed shunting device - Google Patents

Abstract

The invention relates to a following type material high-speed flow dividing device which comprises a flow guide mechanism, a conveying mechanism and a driving mechanism, wherein the conveying mechanism is used for conveying materials so that the materials move along a first direction; the driving mechanism is connected with the flow guide mechanism and used for driving the flow guide mechanism to move so that the flow guide mechanism has a working position and a non-working position; when the flow guide mechanism is in a working position, the flow guide mechanism is driven to move along a second direction; wherein the flow guide mechanism is configured to: when the material conveying device is located at the non-working position, the material conveying device does not interfere with the material so that the material continues to move along the first direction; when it is in the working position, it is used to guide and follow the material in the second direction. The invention can softly and stably shunt the materials conveyed at high speed.

Description

Following type material high-speed shunting device

Technical Field

The invention relates to the field of material distribution, in particular to a following type high-speed material distribution device.

Background

At present, to the reposition of redundant personnel of material, the reposition of redundant personnel that leads to the material through static water conservancy diversion mechanism mostly, but, on high-speed production line, the transport speed of material is very fast, and current static water conservancy diversion mechanism gives the power of a lateral direction of material a little, will lead to the transport of material to lose steadily to the influence is carried.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides a following type material high-speed flow dividing device which can divide materials conveyed at high speed softly and stably.

In order to solve the technical problems, the technical scheme of the invention is as follows: a follow-type material high-speed flow dividing device comprises:

a flow guide mechanism;

the conveying mechanism is used for conveying the materials to enable the materials to move in a first direction;

the driving mechanism is connected with the flow guide mechanism and used for driving the flow guide mechanism to move so that the flow guide mechanism has a working position and a non-working position; when the flow guide mechanism is in a working position, the flow guide mechanism is driven to move along a second direction; wherein the flow directing mechanism is configured to:

when the material conveying device is located at the non-working position, the material conveying device does not interfere with the material so that the material continues to move along the first direction; when it is in the working position, it is used to guide and follow the material in the second direction.

There is further provided a specific structure of a driving mechanism including two pulleys and an endless belt stretched between the two pulleys, one of the pulleys being drivingly rotatable, the deflector being mounted on the endless belt so as to move synchronously with the endless belt.

Further provides a concrete structure of the flow guide mechanism, wherein the flow guide mechanism comprises a plurality of baffle plates, and the plurality of baffle plates are arranged on part of the circumferential direction of the annular belt.

Further, a plurality of baffle plates are closely arranged.

Further, in order to conveniently adjust the position and/or angle of the driving mechanism and adjust the position and/or angle of the diversion mechanism in the working position, the following type high-speed material diversion device further comprises an installation adjusting mechanism, the driving mechanism further comprises a belt wheel frame, the two belt wheels are respectively and rotatably supported on the belt wheel frame, and the installation adjusting mechanism is used for installing the belt wheel frame on a fixed body and adjusting the position and/or angle of the belt wheel frame by operating the belt wheel frame.

Further provided is a concrete structure of a mounting adjustment mechanism, the mounting adjustment mechanism including two mounting adjustment assemblies, the mounting adjustment assemblies including:

the mounting rod is hinged on the belt wheel frame;

the mounting rod is arranged on the supporting piece in a sliding manner, and the supporting piece is used for driving the mounting rod to swing in the sliding process;

a first locking mechanism disposed between the support and the mounting rod for locking the position of the mounting rod after the mounting rod is slid into place;

a second locking mechanism disposed between the fixing body and the support member for locking a position of the support member after the support member is slid into place.

Further in order to limit the position of the material on the conveying mechanism and ensure smooth shunting, the following type material high-speed shunting device further comprises two first material blocking parts, wherein the two first material blocking parts are arranged on the conveying mechanism in parallel and block two sides of the material before shunting on the conveying mechanism and are used for limiting the position of the material before shunting on the conveying mechanism.

Further, in order to be suitable for materials with different sizes, the position of at least one first material blocking part is adjustable.

Further in order to ensure that the materials move smoothly along the second direction after being shunted, the following type high-speed material shunting device further comprises a second material blocking part, wherein the second material blocking part extends along the second direction and blocks the side, far away from the diversion mechanism, of the materials moving along the second direction.

Further, the position of the second material stopping part is adjustable so as to be suitable for materials with different sizes.

After the technical scheme is adopted, the invention has the following beneficial effects:

1. the diversion mechanism is provided with a working position and a non-working position under the driving of the driving mechanism, and does not interfere with materials when in the non-working position, so that the materials can be continuously conveyed along a first direction;

2. the driving mechanism adopts a structure that the belt wheel is matched with the annular belt, the flow guide mechanism is arranged on the annular belt and synchronously rotates along with the annular belt, so that the working position and the non-working position are switched, and the flow guide mechanism is driven by the annular belt to move along the second direction in the working position;

3. the driving mechanism is arranged on the fixed body through the installation adjusting mechanism, and the installation adjusting mechanism can be operated according to actual requirements in the actual production process so as to adjust the position and/or the angle of the driving mechanism and the flow guide mechanism connected with the driving mechanism, thereby improving the universality of the whole follow-up high-speed material flow dividing device.

Drawings

FIG. 1 is a schematic structural diagram of a follow-up high-speed material distribution device in an embodiment of the present invention;

FIG. 2 is a top view of FIG. 1;

FIG. 3 is a schematic structural diagram of the following type high-speed material distribution device without a conveying mechanism in the embodiment of the invention;

FIG. 4 is a schematic structural diagram of a driving mechanism and a guiding mechanism according to an embodiment of the present invention;

FIG. 5 is a schematic structural diagram of the driving mechanism with the pulley frame removed according to the embodiment of the present invention;

fig. 6 is an enlarged view of a portion a of fig. 3.

Detailed Description

In order that the manner in which the present invention is attained and can be understood in detail, a more particular description of the invention briefly summarized above may be had by reference to the embodiments thereof which are illustrated in the appended drawings.

As shown in fig. 1, 2, 3, 4, 5, and 6, a follower type high-speed material diversion device includes:

a flow guide mechanism 1;

a conveying mechanism 2 for conveying the material such that the material moves in a first direction;

the driving mechanism 3 is connected with the flow guide mechanism 1 and used for driving the flow guide mechanism 1 to move so that the flow guide mechanism 1 has a working position and a non-working position; when the flow guide mechanism 1 is located at the working position, the flow guide mechanism 1 is driven to move along a second direction; wherein the flow guide mechanism 1 is configured to:

when the material conveying device is located at the non-working position, the material conveying device does not interfere with the material so that the material continues to move along the first direction; when it is in the working position, it is used to guide and follow the material in the second direction.

In this embodiment, the linear velocity of the high-speed material is generally 60m/min to 200m/min.

Specifically, the diversion mechanism 1 of this embodiment has the work position and the non-work position under the drive of actuating mechanism 3, and when the non-work position, do not interfere the material for the material can continue to be carried along the first direction, and when the work position, still move along the second direction under the drive of actuating mechanism 3, relative material is static, and then can stir the material softly and carry along the second direction, thereby realize the steady reposition of redundant personnel of high-speed material.

The conveying mechanism 2 can be selected according to actual needs, and in the embodiment, the conveying mechanism 2 can be, but is not limited to, a belt conveyor.

As shown in fig. 1, 2, 3, 4 and 5, the driving mechanism 3 includes two pulleys 34 and an endless belt 31 tensioned between the two pulleys 34, one pulley 34 being drivingly rotatable, and the deflector mechanism 1 is mounted on the endless belt 31 so as to move synchronously with the endless belt 31.

In this embodiment, as shown in fig. 1, 2, 3, 4, and 5, the two belt wheels 34 are arranged in parallel along the second direction, the whole driving device 3 is located above the material, when the diversion mechanism 1 rotates to the lower side of the endless belt 31 along with the endless belt 31, the diversion mechanism 1 is located at the working position, when the diversion mechanism 1 is located at another position except the lower side of the endless belt 31, the diversion mechanism 1 located at the working position is located at the non-working position, and the diversion mechanism 1 located at the working position is driven by the endless belt 31 to move along the second direction, so as to guide and follow the material to move along the second direction.

As shown in fig. 1, 2, 3, 4 and 5, the driving mechanism 3 further includes a pulley frame 32 and a motor 33, two pulleys 34 are respectively rotatably supported on the pulley frame 32, a body of the motor 33 is fixedly mounted on the pulley frame 32, and an output shaft is connected to one of the pulleys 34 to drive the pulley 34 to rotate.

Specifically, the driving mechanism 3 of this embodiment adopts the structure in which the belt wheel 34 and the endless belt 31 are matched, the diversion mechanism 1 is installed on the endless belt 31, and rotates synchronously with the endless belt 31, and then switches between the working position and the non-working position, and moves in the second direction under the driving of the endless belt 31 in the working position, and the driving mechanism 3 of this structure has a simple structure, is easy to implement, and is low in cost.

As shown in fig. 1, 2, 3, 4, and 5, the flow guide mechanism 1 includes a plurality of blocking pieces 11, the plurality of blocking pieces 11 are installed in a part of the circumferential direction of the endless belt 31, and the plurality of blocking pieces 11 are closely arranged.

In this embodiment, as shown in fig. 5, a plurality of mounting blocks are mounted on the outer surface of the annular belt 31 at equal intervals, one blocking piece 11 is mounted on each mounting block, the adjacent blocking pieces 11 are overlapped, and the blocking pieces 11 contact with the side surface of the material when rotating to the lower side to guide and move along with the material.

In this embodiment, the structure of the driving mechanism is not limited to that described above, the driving mechanism may also drive a mounting plate to move linearly in a reciprocating manner along a straight line in the second direction by a linear module, or an air cylinder or an oil cylinder, the blocking piece 11 is slidably disposed on the mounting plate and can extend or retract under the driving of the air cylinder or the oil cylinder, when the mounting plate moves along the second direction, the blocking piece 11 is in an extending state and guides and follows the material to move, and when the mounting plate moves along a direction opposite to the second direction, the blocking piece 11 is in a retracting state without interfering with the material, so that the material can continue to move along the first direction.

As shown in fig. 1, 2, 3, 4 and 6, in order to adjust the position and/or angle of the driving mechanism 3 for adjusting the position and/or angle of the diversion mechanism 1 in the working position, the follower type high-speed material diversion device further includes an installation adjusting mechanism 4, and the installation adjusting mechanism 4 is used for installing the belt wheel carrier 32 on a fixed body 5 and adjusting the position and/or angle of the belt wheel carrier 32 by operating the same.

Specifically, the driving mechanism 3 of this embodiment is installed on the fixing body 5 through the installation adjusting mechanism 4, and in the actual production process, the installation adjusting mechanism 4 can be operated according to actual needs to adjust the position and/or the angle of the driving mechanism 3 and the diversion mechanism 1 connected with the driving mechanism 3, so that the universality of the whole following type high-speed material diversion device is improved.

As shown in fig. 1, 2, 3, and 6, the installation adjustment mechanism 4 includes two installation adjustment assemblies, including:

a mounting lever 41 hinged on the belt pulley carrier 32;

a supporting member 42 slidably fitted on the fixed body 5, wherein the mounting rod 41 is slidably fitted on the supporting member 42, and the supporting member 42 is used for driving the mounting rod 41 to swing in the sliding process;

a first locking mechanism disposed between the support member 42 and the mounting rod 41 and for locking the position of the mounting rod 41 after the mounting rod 41 is slid into position;

a second locking mechanism disposed between the fixed body 5 and the support member 42 and for locking the position of the support member 42 after the support member 42 is slid into position.

In this embodiment, as shown in fig. 1, 2, 3, and 6, a connection line of the hinge points of the two mounting bars 41 on the belt wheel frame 32 is parallel to or approximately parallel to a straight line of the second direction, the two mounting bars 41 are always parallel to each other, the two supporting members 42 are both in a vertical state, and the arrangement direction of the two supporting members 42 is parallel to or approximately parallel to a straight line of the first direction.

In this embodiment, as shown in fig. 1, 2, 3 and 6, the mounting rod 41 is provided with a scale mark for marking a position.

In this embodiment, as shown in fig. 1, 2, 3, and 6, a first groove is opened on the supporting member 42, the mounting rod 41 is movably inserted into the first groove, the first locking mechanism includes a first locking plate 43 and a plurality of first locking bolts, the first locking plate 43 is located on a side surface of the mounting rod 41 away from a groove bottom of the first groove, and is mounted on the supporting member 42 through the plurality of first locking bolts, the first locking bolt is tightened, the mounting rod 41 is clamped by the supporting member 42 and the first locking plate 43 together, the position of the mounting rod 41 on the supporting member 42 is locked, and the mounting rod 41 can slide by loosening the first locking bolt.

In order to reduce the sliding resistance of the mounting rod 41 during sliding, two rows of guide wheels 45 are mounted on the first locking plate 43, and the mounting rod 41 is positioned between the two rows of guide wheels 45 and is tangent to the guide wheels 45.

In this embodiment, as shown in fig. 1, 2, 3, and 6, a second groove is formed in the mounting part 42, the second groove is slidably fitted on the fixing rod on the fixing body 5, the second locking mechanism includes a second locking plate 44 and a plurality of second locking bolts, the second locking plate 44 is located on a side surface of the fixing rod away from a groove bottom of the second groove, and is mounted on the supporting part 42 through the plurality of second locking bolts, the second locking bolts are tightened to complete the locking of the position of the supporting part 42 on the fixing rod, and the supporting part 42 can be slid by loosening the second locking bolts.

In the present embodiment, the structures of the first locking mechanism and the second locking mechanism are not limited to those described above, and may be other structures.

As shown in fig. 1 and 2, in order to limit the position of the material on the conveying mechanism 2 and ensure smooth shunting, the following type high-speed material shunting device further includes two first material blocking members 6, where the two first material blocking members 6 are installed on the conveying mechanism 2 in parallel and block two sides of the material before shunting on the conveying mechanism 2, and are used to limit the position of the material before shunting on the conveying mechanism 2.

As shown in fig. 1 and 2, in order to adapt to materials with different sizes, the position of at least one first material blocking member 6 is adjustable.

In this embodiment, be connected with a plurality of first connecting rods 61 perpendicular thereto on the first fender material 6, fixed mounting has a plurality of staple bolts on the frame of conveying mechanism 2, first connecting rod 61 passes corresponding staple bolt, two tip of staple bolt are locked by the bolt, and the position of first connecting rod 61 then can be adjusted to the unscrew bolt, and then the position of the first fender material 6 of adjustment.

In this embodiment, the adjustment of the position of the first material blocking member 6 is not limited to the above, and may be in other structures.

As shown in fig. 1, 2, 3, and 4, in order to ensure that the material is smoothly moved along the second direction after being shunted, the follow-up high-speed material shunting device further includes a second material blocking member 7, where the second material blocking member 7 is parallel to a straight line where the second direction is located and blocks a side, far away from the diversion mechanism 1, of the material moving along the second direction.

As shown in fig. 1, 2, 3 and 4, the position of the second stop 7 is adjustable in order to adapt to different sizes of material.

In this embodiment, as shown in fig. 1, 2, 3, and 4, the band wheel frame 32 is connected with at least one second connecting rod 71, the second connecting rod 71 passes through the second material blocking member 7, nuts are screwed to positions of the second connecting rod 71 located on both sides of the second material blocking member 7, and the position of the second material blocking member 7 can be adjusted by rotating the corresponding nuts.

In this embodiment, as shown in fig. 1, 2, 3 and 4, the second link 71 is provided with a graduation mark for indicating the position of the second material blocking member 7.

In this embodiment, the adjustment of the position of the second material blocking member 7 is not limited to the above-described adjustment, and may have other structures.

In light of the foregoing description of the preferred embodiments of the present invention, it is clear that many changes and modifications can be made by the workers skilled in the art without departing from the scope of the present invention, and the technical scope of the present invention is not limited to the description, but must be determined by the claims.

Claims (10)

1. A following type material high-speed shunting device, which is characterized in that,

the method comprises the following steps:

a flow guide mechanism (1);

the conveying mechanism (2) is used for conveying the materials so that the materials move along a first direction;

the driving mechanism (3) is connected with the flow guide mechanism (1) and is used for driving the flow guide mechanism (1) to move so that the flow guide mechanism (1) has a working position and a non-working position; when the flow guide mechanism (1) is in a working position, the flow guide mechanism (1) is driven to move along a second direction; wherein the flow guiding mechanism (1) is configured to:

when the material conveying device is located at the non-working position, the material conveying device does not interfere with the material so that the material continues to move along the first direction; when it is in the working position, it is used to guide and follow the material in the second direction.

2. The follow-on material high-speed flow divider according to claim 1,

the driving mechanism (3) comprises two belt wheels (34) and an annular belt (31) tensioned between the two belt wheels (34), wherein one belt wheel (34) can be driven to rotate, and the flow guide mechanism (1) is installed on the annular belt (31) to move synchronously with the annular belt (31).

3. The follow-on material high-speed flow divider according to claim 2,

the flow guide mechanism (1) comprises a plurality of baffle plates (11), and the baffle plates (11) are installed on part of the circumference of the annular belt (31).

4. The follow-on material high-speed flow divider according to claim 3,

a plurality of baffle plates (11) are closely arranged.

5. The follower type high-speed material flow divider according to claim 2,

the belt wheel driving mechanism further comprises an installation adjusting mechanism (4), the driving mechanism (3) further comprises a belt wheel frame (32), two belt wheels (34) are respectively and rotatably supported on the belt wheel frame (32), and the installation adjusting mechanism (4) is used for installing the belt wheel frame (32) on a fixed body (5) and adjusting the position and/or the angle of the belt wheel frame (32) by operating the installation adjusting mechanism.

6. The follow-on material high-speed flow divider according to claim 5,

the mounting adjustment mechanism (4) comprises two mounting adjustment assemblies, the mounting adjustment assemblies comprising:

a mounting bar (41) hinged to the pulley carrier (32);

the supporting piece (42) is matched on the fixed body (5) in a sliding mode, the mounting rod (41) is matched on the supporting piece (42) in a sliding mode, and the supporting piece (42) is used for driving the mounting rod (41) to swing in the sliding process;

a first locking mechanism disposed between the support member (42) and the mounting rod (41) for locking the position of the mounting rod (41) after the mounting rod (41) is slid into position;

a second locking mechanism disposed between the fixed body (5) and the support (42) and for locking the position of the support (42) after the support (42) is slid into place.

7. The follow-on material high-speed flow divider according to claim 1,

the material distributing mechanism is characterized by further comprising two first material blocking parts (6), wherein the two first material blocking parts (6) are arranged on the conveying mechanism (2) in parallel, are blocked on two sides of materials before distribution on the conveying mechanism (2), and are used for limiting the positions of the materials before distribution on the conveying mechanism (2).

8. The follow-on material high-speed flow divider according to claim 7,

the position of at least one first material blocking part (6) is adjustable.

9. The follow-on material high-speed flow divider according to claim 1,

the material conveying device is characterized by further comprising a second material blocking part (7), wherein the second material blocking part (7) extends along the second direction and blocks the side, far away from the flow guide mechanism (1), of the material moving along the second direction.

10. The follow-on material high-speed flow divider according to claim 9,

the position of the second material blocking part (7) is adjustable.

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