CN220264142U - Movable blocking rolling mechanism and assembly line working section using same - Google Patents

Abstract

The application provides a movable type blocking rolling mechanism and a production line working section using the same. The movable type blocking rolling mechanism comprises a driving assembly, a supporting assembly and a movable type rolling assembly; the driving assembly comprises a driving part and a blocking part, and the driving part is in driving connection with the blocking part; the supporting component and the blocking part are arranged at intervals; the movable rolling assembly comprises a connecting part, a swinging part and a rolling part, wherein the connecting part and the rolling part are arranged at intervals and are respectively connected with the swinging part, the swinging part is rotationally connected with the supporting assembly, and the connecting part is further in driving connection with the driving part through a connecting blocking part and is used for driving the swinging part to rotate compared with the supporting assembly so as to drive the rolling part to move. The assembly line workshop section includes transport mechanism and aforesaid movable blocking rolling mechanism, and supporting component is connected with transport mechanism, and transport mechanism has the transportation passageway of transportation material, and drive portion drive blocking portion is the straight reciprocating motion in order to invade or dodge the transportation passageway to drive movable rolling component and realize blocking or rolling to the material.

Description

Movable blocking rolling mechanism and assembly line working section using same

Technical Field

The application relates to the technical field of mechanical assembly, in particular to a movable blocking rolling mechanism and a production line working section using the same.

Background

The use of pipelines for transporting materials is a common practice in modern industry, such as centrifugal washing machines, which are currently used for transporting materials (plate-like materials or materials loaded on a carrier plate) by rails. When the rail is used for transporting materials, the rail is usually kept in a continuously opened state by taking adverse factors such as rail running inertia and abrasion caused by repeated opening into consideration, so that a blocking mechanism is additionally arranged to block the materials, and the materials can be stopped. When using the track transportation material, still need set up rolling mechanism and carry out the roll extrusion helping hand to the material to promote the efficiency of track transportation. The blocking mechanism and the rolling mechanism are usually separately arranged, the blocking mechanism and the rolling mechanism are driven by respective driving parts, and the respective driving parts of the blocking mechanism and the rolling mechanism are usually controlled separately. The whole mechanism is provided with a plurality of different driving parts, corresponding control wiring harnesses and the like, so that the whole mechanism is large in size, and the miniaturization of equipment or the improvement of the economy of the equipment are not facilitated. How to solve the above problems is considered by those skilled in the art.

Disclosure of Invention

In order to solve the problems in the prior art, the embodiment of the application provides a movable blocking rolling mechanism driven by a single driving part to realize blocking and rolling, and a production line working section applying the movable blocking rolling mechanism.

The application implementation provides a movable blocking rolling mechanism, which comprises a driving assembly, a supporting assembly and a movable rolling assembly. The driving assembly comprises a driving part and a blocking part, and the driving part is in driving connection with the blocking part. The support component and the blocking part are arranged at intervals. The movable rolling assembly comprises a connecting part, a swinging part and a rolling part, wherein the connecting part is arranged at intervals with the rolling part and is respectively connected with the swinging part, the swinging part is rotationally connected with the supporting assembly, and the connecting part is further connected with the driving part in a driving way through the blocking part and is used for driving the swinging part and the rolling part to rotate compared with the supporting assembly.

It can be appreciated that the movable blocking rolling mechanism of the present application, the driving portion is in driving connection with the blocking portion, so that the blocking portion can extend or retract, so as to respectively realize blocking and avoiding. The connecting portion is further connected with the blocking portion in a driving mode, when the driving portion drives the blocking portion to do linear reciprocating motion, the blocking portion drives the swinging portion to rotate compared with the supporting component through the connecting portion, and the swinging portion drives the rolling portion to move and achieve rolling assistance or avoidance. That is, the synchronous control of the blocking action and the rolling action can be realized by one driving part, the number of the driving parts is reduced, and the miniaturization of the equipment or the improvement of the economy of the equipment is facilitated.

In an embodiment, the swinging part comprises a first end part, a second end part and a swinging arm, wherein the first end part and the second end part are arranged at intervals, the swinging arm is connected with the first end part and the second end part, the first end part is connected with the rolling part, the second end part is connected with the connecting part, the swinging arm is movably connected with the supporting component, and the connecting part of the swinging arm and the supporting component is positioned between the first end part and the second end part.

In an embodiment, the swing arm includes a first arm and a second arm disposed at an included angle, the support assembly and the swing arm are connected at a connection between the first arm and the second arm, the first end is connected to a side of the first arm away from the connection, and the second end is connected to a side of the second arm away from the connection.

In one embodiment, the first force arm is disposed on a side of the second force arm away from the driving portion.

In an embodiment, the connecting portion includes a connecting rod and a connecting arm, the connecting rod is connected with the blocking portion, one end of the connecting arm is connected with the connecting rod, and the other end of the connecting arm is movably connected with the swinging portion.

In an embodiment, the movable rolling assembly includes two swinging parts and two rolling parts, the two swinging parts are arranged at intervals on two opposite sides of the blocking part, each swinging part is connected with one rolling part, the connecting part includes two connecting arms, the two connecting arms are respectively positioned on two opposite sides of the blocking part and are respectively connected with the connecting rod, and each connecting arm is connected with one swinging part.

In an embodiment, the support assembly includes a bottom plate portion, a first side plate portion and a second side plate portion, the driving portion is fixedly connected with the bottom plate portion, the first side plate portion and the second side plate portion are respectively disposed on two opposite sides of the driving portion and are respectively connected with the bottom plate portion, and the first side plate portion and the second side plate portion are respectively connected with one swinging portion.

In an embodiment, the first side plate portion is fixedly connected with the bottom plate portion, the bottom plate portion is provided with a chute, and the second side plate portion includes a slider end movably adapted to the chute, so that the second side plate portion is slidably connected with the bottom plate portion.

In an embodiment, the driving portion is configured to push the blocking portion to reciprocate linearly, the blocking portion is configured to extend to block or retract to avoid, the movable rolling assembly is configured to tilt the rolling portion to avoid when the blocking portion extends, and the movable rolling assembly is further configured to tilt the rolling portion to roll when the blocking portion retracts.

An embodiment of the present application further provides an assembly line station comprising a transport mechanism and a movable barrier rolling mechanism as described in any of the previous embodiments. The supporting component is connected with the conveying mechanism, the conveying mechanism is provided with a conveying channel for conveying materials, and the driving part drives the blocking part to do linear reciprocating motion so as to invade or avoid the conveying channel, so that the movable rolling component is driven to block or roll the materials.

It can be appreciated that the assembly line section with the movable blocking rolling mechanism has significant advantages in various aspects such as equipment miniaturization, equipment economy and the like.

Drawings

Fig. 1 is a schematic perspective view of an angle of a movable rolling blocking mechanism according to an embodiment of the present application.

Fig. 2 is a schematic perspective view of another angle of the movable rolling blocking mechanism according to the embodiment of the present application.

Fig. 3 is a schematic perspective view of another angle of the movable rolling blocking mechanism according to the embodiment of the present application.

Fig. 4 is a schematic perspective view of a pipeline section provided in an embodiment of the present application.

Fig. 5 is a schematic perspective view of a transport device for an assembly line section according to an embodiment of the present application.

Fig. 6 is a schematic diagram of a working state in which a blocking portion protrudes to block and a rolling portion tilts to avoid in a production line working section provided in an embodiment of the present application.

Fig. 7 is a schematic diagram of a working state of a blocking portion in a pipeline section provided by an embodiment of the present application, wherein the blocking portion is retracted to avoid the blocking portion, and a rolling portion is turned over to roll the blocking portion.

Description of the main reference signs

Movable block rolling mechanism 10

Drive assembly 11

Drive unit 111

Blocking portion 112

Support assembly 12

Bottom plate portion 121

Chute 1210

First side plate portion 122

Second side plate portion 123

Slider end 1231

Movable rolling assembly 13

Connecting portion 131

Connecting rod 1311

Connecting arm 1312

Swing portion 132

Swing arm 1320

First end 1321

Second end 1322

First arm 1323

Second arm 1324

Junction 1325

Rolling part 133

Pipeline section 2

Transport mechanism 20

Transport tunnel 201

Support 202

Transport roller 203

The following detailed description will further illustrate the application in conjunction with the above-described figures.

Detailed Description

The following description will refer to the accompanying drawings in order to more fully describe the present application. Exemplary embodiments of the present application are illustrated in the accompanying drawings. This application may, however, be embodied in many different forms and should not be construed as limited to the exemplary embodiments set forth herein. These exemplary embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the application to those skilled in the art. Like reference numerals designate identical or similar components. The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the application. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. Furthermore, as used herein, "comprises" and/or "comprising" and/or "having," integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, regions, integers, steps, operations, elements, and/or groups thereof. Unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. Furthermore, unless the context clearly defines otherwise, terms such as those defined in a general dictionary should be construed to have meanings consistent with their meanings in the relevant art and the present application, and should not be construed as idealized or overly formal meanings. The following description of exemplary embodiments will be provided with reference to the accompanying drawings. It is noted that the components depicted in the referenced figures are not necessarily shown to scale; and the same or similar components will be given the same or similar reference numerals or similar technical terms.

In general, when a rail is used for transporting materials, the rail is usually kept continuously opened due to factors such as inertia of the running rail and abrasion caused by repeated opening, so that an additional blocking mechanism is required to block the materials, and the materials can be stopped. When using the track transportation material, still need set up rolling mechanism and carry out the roll extrusion helping hand to the material to promote the efficiency of track transportation. The blocking mechanism and the rolling mechanism are usually separately arranged, the blocking mechanism and the rolling mechanism are driven by respective driving parts, and the respective driving parts of the blocking mechanism and the rolling mechanism are usually controlled separately. The whole mechanism is provided with a plurality of different driving parts, corresponding control wiring harnesses and the like, so that the whole mechanism is large in size, and the miniaturization of equipment or the improvement of the economy of the equipment are not facilitated.

Accordingly, the present application provides a movable blocking rolling mechanism, which comprises a driving assembly, a supporting assembly and a movable rolling assembly. The driving assembly comprises a driving part and a blocking part, and the driving part is in driving connection with the blocking part. The support component and the blocking part are arranged at intervals. The movable rolling assembly comprises a connecting part, a swinging part and a rolling part, wherein the connecting part is arranged at intervals with the rolling part and is respectively connected with the swinging part, the swinging part is rotationally connected with the supporting assembly, and the connecting part is further connected with the driving part in a driving way through the blocking part and is used for driving the swinging part and the rolling part to rotate compared with the supporting assembly.

It can be appreciated that the movable blocking rolling mechanism of the present application, the driving portion is in driving connection with the blocking portion, so that the blocking portion can extend or retract, so as to respectively realize blocking and avoiding. The connecting portion is further connected with the blocking portion in a driving mode, when the driving portion drives the blocking portion to do linear reciprocating motion, the blocking portion drives the swinging portion to rotate compared with the supporting component through the connecting portion, and the swinging portion drives the rolling portion to move and achieve rolling assistance or avoidance. That is, the synchronous control of the blocking action and the rolling action can be realized by one driving part, the number of the driving parts is reduced, and the miniaturization of the equipment or the improvement of the economy of the equipment is facilitated.

Moreover, the existing rolling mechanism is usually located above the track all the time, and when the existing rolling mechanism is in butt joint with a mechanism above the track, such as a buffer and the like, the rolling mechanism is located above, so that the space for lifting and rising materials is blocked, and the butt joint cannot be realized.

Therefore, the swinging part comprises a first end part, a second end part and a swinging arm, wherein the first end part and the second end part are arranged at intervals, the swinging arm is connected with the first end part and the second end part, the first end part is connected with the rolling part, the second end part is connected with the connecting part, the swinging arm is movably connected with the supporting component, and the connecting part of the swinging arm and the supporting component is positioned between the first end part and the second end part. The swing arm is including being the first arm of force and the second arm of force that the contained angle set up, supporting component with the swing arm connect in first force arm with the junction of second arm of force, first end connect in first force arm is kept away from junction one side, second end connect in second arm of force is kept away from junction one side. The first force arm is arranged on one side of the second force arm far away from the driving part.

It can be understood that the first force arm and the second force arm which are arranged at an included angle are respectively connected with the rolling part and the connecting part, the driving assembly drives the connecting part to do linear motion and drives the second force arm to rotate, and the second force arm further drives the first force arm to rotate, so that the rolling part rotates to the upper part of the material to realize rolling assistance. When the rolling assistance is not needed, the rolling part can rotate to a position (such as a side surface) which is not upper than the material, so that interference to the butt joint of the material in the upper direction is avoided.

As will be appreciated by those skilled in the art, an "angled arrangement" means that the first moment arm and the second moment arm are not parallel or overlapping.

It will be appreciated by those skilled in the art that the "driving portion" refers to a structure having driving capability, and may be, for example, a cylinder, a motor, an engine, etc., and in this embodiment, the driving portion is illustrated as a stroke-adjustable connecting rod cylinder.

It will be understood by those skilled in the art that the "blocking portion" refers to a structure that has a certain actual volume and can stop the material by contacting and abutting, such as a pushing head or a stopper of a cylinder, and in this embodiment, the blocking portion is shown by taking a hard metal block with a surface provided with a flexible material (such as euler's glue) as an example.

It will be understood by those skilled in the art that the "rolling portion" refers to a structure capable of rotating to assist in rolling, and may be, for example, a roller, a pulley, etc., and in this embodiment, the rolling portion is shown as a roller to which a rotating shaft is connected.

The following detailed description of specific embodiments of the present application refers to the accompanying drawings.

As shown in fig. 1 to 3, the present application provides a movable blocking rolling mechanism 10, which includes a driving assembly 11, a supporting assembly 12 and a movable rolling assembly 13. The driving component 11 is fixedly connected with the supporting component 12, the movable rolling component 13 is movably connected with the supporting component 12, the driving component 11 and the supporting component 12 can be connected to the same side of the supporting component 12, and the other side of the supporting component 12, which is away from the driving component 11, is used for facing the feeding direction of materials. The driving assembly 11 is in driving connection with the movable rolling assembly 13 and is used for driving the movable rolling assembly 13 to swing towards or away from the feeding direction, so that controllable rolling assistance is realized.

In one embodiment, the driving assembly 11 includes a driving portion 111 and a blocking portion 112, and the driving portion 111 is in driving connection with the blocking portion 112. The support assembly 12 is spaced apart from the stop 112. The movable rolling assembly 13 comprises a connecting portion 131, a swinging portion 132 and a rolling portion 133, wherein the connecting portion 131 and the rolling portion 133 are arranged at intervals and are respectively connected with the swinging portion 132, the swinging portion 132 is rotationally connected with the supporting assembly 12, the connecting portion 131 is further in driving connection with the driving portion 111 through the connecting blocking portion 112, and the swinging portion 132 is used for driving the swinging portion 132 to rotate compared with the supporting assembly 12 to drive the rolling portion 133 to move.

In one embodiment, the driving portion 111 is configured to push the blocking portion 112 to reciprocate linearly, and the blocking portion 112 is configured to extend to block or retract to avoid. The movable roller assembly 13 is configured to tilt the roller 133 for relief when the blocking portion 112 is extended, and the movable roller assembly 13 is further configured to tilt the roller 133 for rolling when the blocking portion 112 is retracted.

It can be appreciated that when the movable blocking rolling mechanism 10 is matched with the conveying mechanism 20, the blocking portion 112 will pass through the conveying path (extending direction of the conveying channel 201) of the material when performing the linear reciprocating motion, and the direction of the linear reciprocating motion of the blocking portion 112 is intersected with the direction of the conveying path, so that the blocking portion 112 can invade the conveying path of the material to block the material in the process of the linear reciprocating motion of the blocking portion 112, specifically, the blocking portion 112 is driven by the driving portion 111 to extend out of the conveying path of the invaded material to block, and the blocking portion 112 is driven by the driving portion 111 to retract out of the conveying path of the material to avoid. On the other hand, two ends of the swinging part 132 are respectively connected with the connecting part 131 and the rolling part 133, when the blocking part 112 drives the connecting part 131 to move, the swinging part 132 rotates with the axle center of the rotating connection of the swinging part 132 and the supporting component 12 as an axle, so that one end of the swinging part 132 connected with the rolling part 133 can rotate to be positioned above the conveying channel 201 of the material and realize rolling assistance on the material, or one end of the swinging part 132 connected with the rolling part 133 rotates to be far away from one side of the conveying channel 201 of the material and is separated from the material.

Further, in the movable blocking rolling mechanism 10 of the present application, the driving portion 111 is in driving connection with the blocking portion 112, so that the blocking portion 112 can extend or retract to achieve blocking and avoiding respectively. The connecting portion 131 is further connected with the driving portion 111 through the connection blocking portion 112, when the driving portion 111 drives the blocking portion 112 to do linear reciprocating motion, the blocking portion 112 drives the swinging portion 132 to rotate compared with the supporting assembly 12 through the connecting portion 131, and the swinging portion 132 further drives the rolling portion 133 to move and achieve rolling assistance or avoidance. That is, the one driving part 111 can realize the synchronous control of the blocking action and the rolling action, thereby reducing the number of the driving parts 111 and facilitating the realization of the miniaturization of the equipment or the improvement of the economy of the equipment.

In the present embodiment, the direction in which the blocking portion 112 makes the linear reciprocating motion and the direction of the transport path are shown as an example; in other embodiments, the direction of the linear reciprocating motion of the blocking portion 112 and the direction of the transportation path may be other intersecting forms.

In one embodiment, the swing portion 132 includes a first end 1321 and a second end 1322 disposed at intervals, and a swing arm 1320 connecting the first end 1321 and the second end 1322. The first end 1321 is connected to the rolling portion 133, the second end 1322 is connected to the connecting portion 131, the swing arm 1320 is movably connected to the support assembly 12, and the connection portion 1325 between the swing arm 1320 and the support assembly 12 is located between the first end 1321 and the second end 1322.

In this embodiment, the first end portion 1321 and the second end portion 1322 are respectively located at two opposite sides of the swing arm 1320, and in other embodiments, the first end portion 1321 and the second end portion 1322 may be located at the same side of the swing arm 1320, so that the connection portion 131 can drive the swing arm 1320 to rotate compared with the support assembly 12 to drive the rolling portion 133 to move by keeping the connection portion 1325 between the swing arm 1320 and the support assembly 12 and the first end portion 1321 at a distance.

In one embodiment, the swing arm 1320 includes a first arm 1323 and a second arm 1324 disposed at an angle, the support assembly 12 and the swing arm 1320 are connected to a connection 1325 between the first arm 1323 and the second arm 1324, the first end 1321 is connected to a side of the first arm 1323 away from the connection 1325, and the second end 1322 is connected to a side of the second arm 1324 away from the connection 1325.

In the present embodiment, the swing arm 1320 is substantially L-shaped, the first force arm 1323 and the second force arm 1324 are respectively two sub-force arms of the swing arm 1320 extending along different directions, and the swing arm 1320 is made of hard material. Therefore, when the connecting portion 131 drives the second arm 1324 to rotate, the first arm 1323 also rotates by a corresponding angle, so as to control the position of the rolling portion 133.

In one embodiment, the first force arm 1323 is disposed on a side of the second force arm 1324 away from the driving portion 111. The second arm 1324 is closer to the driving portion 111 than the first arm 1323, so that the rolling portion 133 is turned over to roll when the blocking portion 112 is retracted, and the rolling portion 133 is turned up to avoid when the blocking portion 112 is extended.

It can be understood that the first force arm 1323 and the second force arm 1324 disposed at an included angle are respectively connected with the rolling portion 133 and the connecting portion 131, the driving assembly 11 drives the connecting portion 131 to perform linear motion and drives the second force arm 1324 to rotate, and the second force arm 1324 further drives the first force arm 1323 to rotate, so that the rolling portion 133 rotates above the material to realize rolling assistance. When the rolling assistance is not needed, the rolling portion 133 can be rotated to a position other than the upper position (e.g., a side surface) of the material, so that interference to the butt joint of the material in the upper direction is avoided.

In this embodiment, the swing arm 1320 may be connected to the support assembly 12 through a shaft pin, such that the swing arm 1320 may rotate relative to the support assembly 12. The connecting portion 131 may also be connected to the swing arm 1320 through a shaft pin, so that the swing arm 1320 is movably connected to the connecting portion 131, so that the second arm 1324 can still be better connected to the connecting portion 131 in the rotation process.

In an embodiment, the connecting portion 131 includes a connecting rod 1311 and a connecting arm 1312, the connecting rod 1311 is connected to the blocking portion 112, one end of the connecting arm 1312 is connected to the connecting rod 1311, and the other end of the connecting arm 1312 is movably connected to the swinging portion 132.

It should be understood that, to avoid interference, the blocking portion 112 is spaced apart from the movable rolling assembly 13 and the supporting assembly 12, and therefore the connecting portion 131 is required to connect the blocking portion 112 and the movable rolling assembly 13. Similarly, to avoid interference of the connection portion 131 with the blocking portion 112, the extending direction of the link 1311 should not be the same as or too close to the extending direction of the transportation path 201 or the direction in which the blocking portion 112 moves linearly.

In this embodiment, the link 1311 is disposed through the blocking portion 112, the link 1311 may be cylindrical, one end of the connecting arm 1312 is sleeved on the link 1311 through a sleeve-shaped structure, and the connecting arm 1312 and the link 1311 may be fixedly disposed or slidably disposed. The other end of the connecting arm 1312 is connected to a second arm 1324.

In one embodiment, the movable rolling assembly 13 includes two swinging portions 132 and two rolling portions 133, and the two swinging portions 132 are disposed at two opposite sides of the blocking portion 112. Each swinging part 132 is connected with one rolling part 133, the connecting part 131 comprises two connecting arms 1312, the two connecting arms 1312 are respectively positioned on two opposite sides of the blocking part 112 and are respectively connected with a connecting rod 1311, and each connecting arm 1312 is connected with one swinging part 132.

In this embodiment, considering that the transported material is mostly plate-shaped, in order to improve the stability of the rolling assistance process, two rolling portions 133 may be provided to simultaneously perform rolling assistance, and correspondingly, two swinging portions 132 and two connecting arms 1312 may be provided to cooperate with the two rolling portions 133. As can be appreciated by those skilled in the art, the two rolling portions 133 may have the same structure and the same placement posture, so as to improve the stability of the rolling assistance of the plate-shaped material; when the material requiring the rolling assistance is in a special shape, such as an arc surface or a trapezoid surface, the number of the rolling parts 133 and the structure or the placement posture of each rolling part 133 can be correspondingly adjusted to achieve the goal of improving the rolling assistance stability.

In one embodiment, the support assembly 12 includes a bottom plate portion 121, a first side plate portion 122, and a second side plate portion 123. The driving portion 111 is fixedly connected to the bottom plate portion 121, the first side plate portion 122 and the second side plate portion 123 are respectively provided on opposite sides of the driving portion 111 and are respectively connected to the bottom plate portion 121, and the first side plate portion 122 and the second side plate portion 123 are respectively connected to one swinging portion 132.

As can be appreciated by those skilled in the art, the two rolling portions 133 in the present embodiment correspond to each other, and the support assembly 12 is provided with a first side plate portion 122 and a second side plate portion 123 for connecting the two rolling portions 133. The first side plate 122 and the second side plate 123 may be disposed on opposite sides of the driving unit 11 at intervals along the extending direction of the link 1311.

In an embodiment, the first side plate 122 is fixedly connected to the bottom plate 121, the bottom plate 121 is provided with a chute 1210, and the second side plate 123 includes a slider end 1231, and the slider end 1231 is movably fitted into the chute 1210 to slidably connect the second side plate 123 to the bottom plate 121.

In the present embodiment, the second side plate portion 123 is slidably connected to the bottom plate portion 121 such that the distance between the first side plate portion 122 and the second side plate portion 123 can be adjusted. The connecting arm 1312 connected with the second side plate portion 123 is slidably connected with the connecting rod 1311, and compared with the distance between the swinging portion 132 and the rolling portion 133 connected with the second side plate portion 123 and the distance between the swinging portion 132 and the rolling portion 133 connected with the first side plate portion 122, the distance between the two rolling portions 133 can be adjusted, and therefore the movable blocking rolling mechanism 10 can be applicable to materials with different sizes.

Those skilled in the art will appreciate that the slider end 1231 may be a split lock nut configuration.

Further in connection with fig. 4, an embodiment of the present application also provides an in-line station 2 comprising a transport mechanism 20 and a movable stop-roll mechanism 10 as in any of the previous embodiments. The supporting component 12 is connected with the conveying mechanism 20, the conveying mechanism 20 is provided with a conveying channel 201 for conveying materials, and the driving part 111 drives the blocking part 112 to do linear reciprocating motion so as to invade or avoid the conveying channel 201, so that the movable rolling component 13 is driven to block or roll the materials.

It will be appreciated that the use of the pipeline section 2 with the movable stop-rolling mechanism 10 provides significant advantages in terms of equipment miniaturization, equipment economy, etc.

As further shown in fig. 5, in the present embodiment, the transporting mechanism 20 includes a support 202 and a plurality of transporting rollers 203 disposed on the support 202, where the plurality of transporting rollers 203 are disposed side by side and spaced apart to form a transporting channel 201.

Referring to fig. 4 and 5, in the present embodiment, the first side plate 122 is fixedly connected to the bracket 202, and the movable blocking rolling mechanism 10 is located on the same side (downstream in the feeding direction) of the plurality of conveying rollers 203. Especially, the rolling portion 133 is located at the same side of the plurality of transporting rollers 203, when the rolling portion 133 does not perform rolling assistance on the material, the rolling portion 133 disposed at the side can avoid shielding the space above the material, and when the rolling portion 133 performs rolling assistance on the material, the rolling portion 133 moves to the above of the material under the driving of the swinging portion 132 to perform rolling assistance.

Further referring to fig. 6, a schematic view of the working state in which the blocking portion 112 extends to block and the rolling portion 133 is tilted to avoid is shown. In this working state, the driving part 111 pushes the blocking part 112 to extend and invade the transporting passage 201 to block the material, so that the material is stopped, and the end of the swinging part 132 connected with the rolling part 133 rotates to the side far away from the transporting passage 201 of the material and is separated from the material.

Further referring to fig. 7, a schematic view of the working state in which the blocking portion 112 is retracted to avoid and the rolling portion 133 is turned over to roll is shown. In this working state, the blocking portion 112 is driven by the driving portion 111 to retract and withdraw from the conveying channel 201 so as to avoid the material to continue passing, and the end, connected with the rolling portion 133, of the swinging portion 132 can rotate to be located above the conveying channel 201 and realize rolling assistance on the material.

Hereinabove, the specific embodiments of the present application are described with reference to the accompanying drawings. However, those of ordinary skill in the art will appreciate that various modifications and substitutions can be made to the specific embodiments of the present application without departing from the scope thereof. Such modifications and substitutions are intended to be within the scope of the present application.

Claims (10)

1. The utility model provides a movable rolling mechanism that blocks, includes drive assembly, drive assembly includes drive division and stops the portion, drive division with stop the portion drive connection, its characterized in that, movable rolling mechanism that blocks still includes:

a support assembly disposed in spaced relation to the barrier;

the movable rolling assembly comprises a connecting part, a swinging part and a rolling part, wherein the connecting part is arranged at intervals with the rolling part and is respectively connected with the swinging part, the swinging part is rotationally connected with the supporting assembly, and the connecting part is further connected with the driving part in a driving way through the blocking part and is used for driving the swinging part and the rolling part to rotate compared with the supporting assembly.

2. The movable blocking rolling mechanism of claim 1 wherein the swinging portion comprises a first end portion, a second end portion and a swinging arm connecting the first end portion and the second end portion, wherein the first end portion is connected with the rolling portion, the second end portion is connected with the connecting portion, the swinging arm is movably connected with the supporting assembly, and a connection point of the swinging arm and the supporting assembly is located between the first end portion and the second end portion.

3. The movable blocking rolling mechanism of claim 2 wherein the swing arm comprises a first arm and a second arm disposed at an angle, the support assembly and the swing arm are connected at the junction of the first arm and the second arm, the first end is connected at a side of the first arm remote from the junction, and the second end is connected at a side of the second arm remote from the junction.

4. A movable stop and roll mechanism according to claim 3 wherein said first force arm is disposed on a side of said second force arm remote from said drive portion.

5. The movable blocking rolling mechanism of claim 1 wherein the connecting portion comprises a connecting rod and a connecting arm, the connecting rod is connected with the blocking portion, one end of the connecting arm is connected with the connecting rod, and the other end of the connecting arm is movably connected with the swinging portion.

6. The movable type blocking rolling mechanism as claimed in claim 5, wherein the movable type rolling assembly comprises two swinging parts and two rolling parts, the two swinging parts are arranged on two opposite sides of the blocking part at intervals, each swinging part is connected with one rolling part, the connecting part comprises two connecting arms, the two connecting arms are respectively arranged on two opposite sides of the blocking part and are respectively connected with the connecting rod, and each connecting arm is connected with one swinging part.

7. The movable blocking rolling mechanism of claim 1 wherein the support assembly comprises a bottom plate portion, a first side plate portion and a second side plate portion, the driving portion is fixedly connected with the bottom plate portion, the first side plate portion and the second side plate portion are respectively disposed on opposite sides of the driving portion and are respectively connected with the bottom plate portion, and the first side plate portion and the second side plate portion are respectively connected with one swinging portion.

8. The movable bar-rolling mechanism of claim 7 wherein the first side plate portion is fixedly connected to the bottom plate portion, the bottom plate portion defines a chute, and the second side plate portion includes a slider end that is movably adapted to the chute such that the second side plate portion is slidably connected to the bottom plate portion.

9. The movable barrier roll mechanism of claim 1 wherein the drive portion is configured to push the barrier portion in a linear reciprocating motion, the barrier portion being configured to extend for blocking or retracting for unseating, the movable roll assembly being configured to tilt the roll portion for unseating when the barrier portion extends, the movable roll assembly being further configured to tilt the roll portion for rolling when the barrier portion retracts.

10. An assembly line working section, which is characterized by comprising a conveying mechanism and a movable blocking rolling mechanism as claimed in any one of claims 1 to 9, wherein the supporting component is connected with the conveying mechanism, the conveying mechanism is provided with a conveying channel for conveying materials, and the driving part drives the blocking part to do linear reciprocating motion so as to invade or avoid the conveying channel, so as to drive the movable rolling component to block or roll the materials.