CN211104651U - Cutting and separating device for cutting off and separating continuous plate bodies - Google Patents

Abstract

The utility model discloses a cutting separator for cutting off continuous plate body and separation belongs to the equipment technical field who cuts off continuous plate body and separate. The utility model discloses a cut separator for cutting off and separating continuous plate body, including striding the double belt conveyor of synchronous cutting machine, double belt conveyor includes the conveyor frame, and conveyor frame top is equipped with telescopic first roller group, second roller group, and two roller groups are connected with the cutting machine frame, still is equipped with the deflector roll slide that can slide along the conveyor frame in the conveyor frame, and the deflector roll slide has first deflector roll, second deflector roll; the first conveyor belt is sleeved on the first roller set and the first guide roller, and the second conveyor belt is sleeved on the second roller set and the second guide roller. The utility model discloses can realize cutting off the purpose of separation with wet base plate in succession, wet base plate transmits on the conveyer belt, can avoid the deformation of wet base plate and guaranteed the stability in the wet base plate transmission course.

Description

Cutting and separating device for cutting off and separating continuous plate bodies

Technical Field

The utility model relates to a cutting separator, especially a cutting separator for cutting off and separating continuous plate body belongs to the equipment technical field who cuts off and separate continuous plate body.

Background

ECP board, extrusion Cement board, is a new Cement board produced by using Cement, fiber and siliceous material as main material and through vacuum high pressure extrusion forming and high temperature high pressure steam curing. The board does not contain any harmful substance, belongs to an environment-friendly building material product actively encouraged by the state, has excellent properties of high strength, light weight, fire resistance, weather resistance, earthquake resistance, sound insulation and the like, and is widely applied to building outer walls and inner walls. And through the organic combination of the various texture changes and the design style of the surface of the plate, the outer wall of the building forms the decorative effect of the building, and the plate is particularly suitable for standard buildings and large stadiums. In addition, the sound insulation board can be widely applied to partition walls of high-grade hotels due to excellent sound insulation effect and strength, or can be matched with concrete frame structures and buildings in steel structure forms through specially-made connecting pieces.

In the process of manufacturing the ECP plate, various raw materials are stirred and mixed into pug, and then the pug is continuously extruded by an extruder to form a continuous wet blank plate; at this time, the continuous wet blank plates must be cut into discontinuous wet blank plates with required sizes, and the discontinuous wet blank plates are separated to keep a certain distance between the discontinuous wet blank plates, so that the discontinuous wet blank plates are stacked and transferred to a curing kiln for high-temperature and high-pressure steam curing.

For the purpose of cutting and separating the continuous wet blank, a synchronous cutting and separating system is adopted. The synchronous cutting and separating system comprises: arranged at the outlet of an extruder for extruding a continuous wet billet, in sequence: the automatic cutting machine comprises a guide belt conveyor, a synchronous conveyor (a single belt conveyor) spanned with a synchronous cutting machine, an unpowered roller table (a roller is a free roller and has no conveying belt), and a variable-speed conveyor; the synchronous cutting machine is used for synchronously cutting continuous wet blank plates into discontinuous wet blank plates, and the discontinuous wet blank plates can be separated through the variable-speed transmission of the variable-speed conveyor.

The working principle of the synchronous cutting and separating system is as follows: continuously extruding the continuous wet blank plate from the outlet of the extruder to form a continuous wet blank plate, walking the continuous wet blank plate from a guide belt conveyor to a synchronous conveyor, walking under the action of the synchronous conveyor (synchronous transmission is based on a speed measuring unit, real-time data of the detected continuous extrusion speed of the outlet of the extruder is fed back to a controller, the controller receives the data and outputs the data for controlling the synchronous conveyor to run after the data is calculated and processed, so that the consistency of the extrusion speed and the speed of the synchronous conveyor is realized), starting a synchronous cutting machine after the length of the continuous wet blank plate reaches a set requirement, keeping synchronous motion with the synchronous conveyor, synchronously cutting the continuous wet blank plate, continuously following the cutting machine after the cutting is finished, and walking the discontinuous wet blank plate on the variable-speed conveyor after the cutting machine is cut (after the cutting machine is cut, the continuous wet blank plate forms an individual plate blank with a fixed length, and the cutting process enables the continuous wet blank plate on the synchronous conveyor and the variable-speed conveyor originally, the blank is separated into independent blanks which can be respectively conveyed, and the condition of quick separation of a variable speed conveyor is met), the cutting is completed immediately through the switching of high speed/low speed gears of the variable speed conveyor (the low speed gear of the variable speed conveyor is synchronous with the conveying speed of a synchronous conveyor, and the high speed gear of the variable speed conveyor is more than the conveying speed of the synchronous conveyor by multiple times), the unpowered roller table plays a transition role in the switching, so that the distance between two adjacent wet blank plates is gradually increased and quickly conveyed to the next conveyor, after the cut blank is quickly conveyed to the next conveyor, the variable speed conveyor is decelerated to the low speed gear to operate, and meanwhile, the synchronous cutting machine is quickly reset to a starting point to wait for the next cutting; thereby realizing the purposes of cutting the continuous wet blank plate formed by continuous extrusion to form the discontinuous wet blank plate and separating the discontinuous wet blank plate.

When the synchronous cutting and separating system works, extruded continuous wet blank plates are conveyed by a synchronous conveyor and are cut into independent blanks, and then the separated blanks reach a variable-speed conveyor for conveying to perform separating action after passing through an unpowered roller table with a certain length (the unpowered roller table is composed of a plurality of independent unpowered free rollers).

Therefore, the utility model discloses a cutting separator for cutting off continuous plate body and separation can realize cutting off the purpose of separation with wet base plate in succession, and wet base plate transmits on the conveyer belt, can avoid the deformation of wet base plate and guaranteed the stability in the wet base plate transmission course.

Disclosure of Invention

The invention of the utility model aims to: in view of the above problems, the present invention provides a cutting and separating apparatus for cutting and separating a continuous plate body, which can cut and separate a continuous wet blank plate, and can prevent the wet blank plate from being deformed without being in direct contact with a roller.

The utility model adopts the technical scheme as follows:

a cutting and separating device for cutting and separating continuous plate bodies comprises a synchronous conveyor, wherein a synchronous cutting machine is spanned on the synchronous conveyor;

the synchronous conveyor is a double-belt conveyor and comprises a conveyor frame and 2 sets of telescopic roller sets assembled at the top of the conveyor frame, a cutting wheel of the synchronous cutting machine is positioned between the two telescopic roller sets, the two telescopic roller sets are connected with the cutting machine frame of the synchronous cutting machine, and the two telescopic roller sets are respectively a first roller set and a second roller set which are positioned at the front and the back;

the conveyor frame is also provided with a guide roller sliding seat which can reciprocate along the conveyor frame, and the guide roller sliding seat is provided with a first guide roller and a second guide roller which are arranged at the front and the back;

the double-belt conveyor also comprises a first conveyor belt and a second conveyor belt, wherein the first conveyor belt is sleeved on the first roller set and the first guide roller, and the second conveyor belt is sleeved on the second roller set and the second guide roller;

further comprising:

the first driving mechanism is used for driving the first conveyor belt to transmit;

the second driving mechanism is used for driving the second conveyor belt to transmit, and the second driving mechanism is a variable-speed driving mechanism;

and the third driving mechanism is used for driving the synchronous cutting machine to do reciprocating motion along the conveyor rack, driving the two telescopic roller sets to do telescopic motion along the conveyor rack, and linking the guide roller sliding seats with the second conveyor belt through the first conveyor belt to do reciprocating motion along the conveyor rack.

Adopt the utility model discloses a when cutting separator carries out the operation that will wet base plate cut off and separate in succession, its theory of operation is:

in an initial state, the synchronous cutter is close to the upstream end of the double-belt conveyor, at the moment, the first roller set is in a compressed state, and the second roller set is in an extended state. Under the conveying action of the first conveyor belt and the second conveyor belt, the continuous wet blank plate gradually travels from the first conveyor belt to the second conveyor belt, and when the length of the continuous wet blank plate traveling to the second conveyor belt meets the requirement. Then, the cutting action process is carried out: the synchronous cutting machine starts to move to the downstream end of the double-belt conveyor, meanwhile, the cutting wheel starts to cut the continuous wet blank plate, and the moving speed of the synchronous cutting machine, the conveying speed of the first conveying belt and the conveying speed of the second conveying belt are synchronous, so that the cutting wheel can vertically cut the continuous wet blank plate.

When the cutting is completed, the cut wet web is placed on the second conveyor belt, and the continuous wet web, which is continuously extruded, is placed on the first conveyor belt. Then, the separation action process is carried out: the synchronous cutting machine keeps moving to the downstream end of the double-belt conveyor, the first conveyor belt keeps keeping the original conveying speed, and the second conveyor belt accelerates the conveying speed under the action of a second driving mechanism (the second driving mechanism is a variable-speed driving mechanism), so that the cut wet blank plate is conveyed to the belt conveyor arranged at the downstream end of the double-belt conveyor.

In the cutting and separating process, the first conveyor belt continuously keeps the conveying speed, the synchronous cutting machine always keeps moving to the downstream end of the double-belt conveyor, and the conveying speed of the first conveyor belt and the moving speed of the synchronous cutting machine are synchronous. The cut portion of the continuous wet blank is always maintained at a position between the two telescopic roller sets, and the continuous wet blank is not transferred onto the second conveyor belt and is not dragged. During the cutting and separating process, the two telescopic roller sets are connected with the cutting machine frame of the synchronous cutting machine, so that the first roller set is gradually stretched, and the second roller set is gradually compressed.

In cutting and separation process, because the driven second actuating mechanism of drive second conveyer belt is variable speed actuating mechanism, can realize: when cutting, the conveying speed of the second conveyor belt is synchronous with the conveying speed of the first conveyor belt; and when separating, make the conveying speed of the second conveyer belt accelerate, make its conveying speed and conveying speed of the conveyer belt of the belt conveyor synchronous. The aim of separating the cut wet blanks is achieved by switching the conveying speed of the second conveyor.

When the separation is finished, the synchronous cutting machine moves to a position close to the downstream end of the double-belt conveyor, at the moment, the first roller set is in an extension state, and the second roller set is in a compression state; after the cut wet blank is separated from the second conveyor, the second conveyor is returned to the conveying speed synchronized with that of the first conveyor. Then, the action process of resetting the synchronous cutting machine is carried out: the synchronous cutting machine moves towards the upstream end of the double-belt conveyor more quickly and gradually restores to the initial position; during the resetting of the synchronous cutting machine, the first set of rollers is gradually compressed, while the second set of rollers is gradually stretched, while the continuous wet blanks are gradually moved from the first conveyor belt to the second conveyor belt. After the synchronous cutting machine is reset, the continuous wet blank plates with smaller lengths are moved onto a second conveying belt; and when the length of the continuous wet blank plate which travels to the second conveyor belt meets the requirement, starting the next cutting and separating action process.

In the cutting and separating device, in the whole action process, the first roller set and the second roller set are driven by the third driving mechanism to drive the synchronous cutting machine to move; the conveying of the first conveyor belt is driven by a first driving mechanism; the conveying of the second conveyor belt is driven by a second driving mechanism; the action processes are independent from each other, do not interfere with each other and are organically combined.

In the cutting and separating device of the utility model, in the initial state, the synchronous cutting machine is close to the upstream end of the double-belt conveyor; at this point, the first roller set is in a compressed state, the second roller set is in an extended state, and the guide roller slide is near the downstream end of the dual belt conveyor. In the cutting and separating process, when the synchronous cutting machine moves to the downstream end of the double-belt conveyor, the first roller group is gradually elongated from a compressed state; and the second roller set is gradually compressed from the extension state; the first conveyor belt and the second conveyor belt are linked to lead the guide roller sliding seat to move towards the upstream end of the double-belt conveyor. The synchronous cutter is synchronized so that the first roller set is elongated and the second roller set is compressed; at the moment, the first conveyor belt sleeved on the first roller group is lengthened, so that the second conveyor belt sleeved on the second roller group is shortened, and due to the guide roller sliding seat, the circumferences of the first conveyor belt and the second conveyor belt are basically fixed, the guide roller sliding seat is pulled by the first conveyor belt towards the upstream end of the double-belt conveyor, and the guide roller sliding seat pulls the second conveyor belt towards the upstream end of the double-belt conveyor; the first conveyor belt and the second conveyor belt can keep a tensioning state, and the conveying function of the first conveyor belt and the second conveyor belt is ensured. In the same way, when the synchronous cutting machine is reset, the guide roller sliding seat is pulled towards the downstream end of the double-belt conveyor by the second conveyor belt, and the guide roller sliding seat pulls the first conveyor belt towards the downstream end of the double-belt conveyor; the first conveyor belt and the second conveyor belt can keep a tensioning state, and the conveying function of the first conveyor belt and the second conveyor belt is ensured.

Adopt the utility model discloses a during cutting separator, because the walking of wet base board is always on each conveyer belt, consequently wet base board not with roller direct contact, can avoid the deformation of wet base board. And benefit from the utility model discloses an ingenious design, wet base plate when strideing across different conveyer belts, the transfer rate of conveyer belt keeps synchronous, can not take place to drag the phenomenon because of what different transfer rates lead to. That is, adopt the utility model discloses a cutting separator can realize cutting off the purpose of separation with wet base plate in succession to wet base plate does not with roller direct contact, and wet base plate can not be pulled by the conveyer belt of differential conveying, can avoid the deformation of wet base plate.

Preferably, the telescopic roller set comprises a plurality of rollers, and two ends of each roller are connected through a shear type telescopic chain to form the telescopic roller set. The set of telescoping rollers can be elongated and can also be compressed.

Optionally, 2 first guide rails are arranged at the top of the conveyor frame;

in the first roller group, two ends of the most front roller are assembled on the frame of the conveyor, and two ends of the rest rollers are assembled on the two first guide rails in a sliding manner;

in the second roller group, two ends of the last roller are assembled on the rack of the conveyor, and two ends of the rest rollers are assembled on the two first guide rails in a sliding manner;

the roller both ends of the position at the end of first roller group link to each other through the connecting plate with the roller both ends of the position at the forefront of second roller group, and what the connecting plate was fixed links to each other with the cutting machine frame.

When the specific design is adopted, the third driving mechanism drives the synchronous cutting machine to do reciprocating motion along the conveyor frame, and the purpose of driving the two telescopic roller sets to do telescopic motion along the conveyor frame can be achieved.

Furthermore, a first rear roller and a second front roller are arranged between the first roller group and the second roller group and between the two connecting plates in a front-back position; the first conveyor belt is also sleeved on the first rear roller, and the second conveyor belt is also sleeved on the second front roller; the cutting wheel of the synchronous cutting machine is positioned between the first rear roller and the second front roller.

Further, a first front roller is arranged on the conveyor frame in front of the first roller group, and the first conveyor belt is also sleeved on the first front roller; and a second rear roller is assembled on the conveyor rack behind the second roller group, and the second conveyor belt is also sleeved on the second rear roller.

Optionally, the conveyor frame is provided with 2 second guide rails below the two telescopic roller sets, 2 sliding seats of the guide roller sliding seat are slidably assembled on the two second guide rails, and a first guide roller and a second guide roller of the guide roller sliding seat are assembled between the two sliding seats.

When the specific design is adopted, the third driving mechanism drives the synchronous cutting machine to reciprocate along the conveyor frame, and the purpose of reciprocating along the conveyor frame by the first conveyor belt and the second conveyor belt in linkage with the guide roller sliding seat can be achieved.

Optionally, a third guide roller is assembled on the conveyor rack below the front end of the first roller group, and the first conveyor belt is further sleeved on the third guide roller; and a fourth guide roller is assembled on the conveyor rack below the rear end of the second roller group, and the second conveyor belt is also sleeved on the fourth guide roller.

Optionally, 2 third guide rails are arranged below two sides of the two telescopic roller sets, the cutting machine frame of the synchronous cutting machine is assembled on the two third guide rails in a sliding mode, and the cutting machine frame is driven to reciprocate along the third guide rails through a third driving mechanism.

When the specific design is adopted, the purpose that the synchronous cutting machine reciprocates along the rack of the conveyor can be achieved.

Furthermore, the third driving mechanism comprises a screw-nut pair, a nut of the screw-nut pair is assembled on the cutting machine frame, a screw of the screw-nut pair is rotatably assembled on the transmission machine frame, and the screw is connected with a third motor for driving the screw to rotate.

When the specific design is adopted, the purpose of driving the synchronous cutting machine to do reciprocating motion along the conveyor frame through the third driving mechanism can be achieved.

Optionally, the first driving mechanism comprises a first driving roller assembled on the conveyor frame, the first conveyor belt is further sleeved on the first driving roller, and the first driving roller is connected with a first motor for driving the first driving roller to rotate;

the second driving mechanism comprises a second driving roller assembled on the conveyor rack, the second conveying belt is further sleeved on the second driving roller, the second driving roller is connected with a second motor used for driving the second driving roller to rotate, and the second motor is a variable speed motor.

When the above specific design is adopted, the first motor drives the first driving roller to rotate, and the first conveying belt can be driven to transmit. When the second motor drives the second driving roller to rotate, the second conveying belt can be driven to transmit. The second motor is a variable-speed motor and can realize the purpose of variable-speed transmission of the second conveyor belt.

To sum up, owing to adopted above-mentioned technical scheme, the beneficial effects of the utility model are that:

the utility model discloses a cutting separator for cutting off and separating continuous plate body, the utility model has the advantages that the design is ingenious, when the cutting separator of the utility model is adopted to carry out the operation of cutting off and separating continuous wet blank plates, the walking of the wet blank plates is always on each conveyor belt, therefore, the wet blank plates are not in direct contact with the roller, and the deformation of the wet blank plates can be avoided; when the wet blank plate crosses different conveyor belts, the conveying speeds of the conveyor belts are kept synchronous, and the phenomenon of pulling caused by different conveying speeds is avoided. That is, adopt the utility model discloses a cutting separator can realize cutting off the purpose of separation with wet base plate in succession, and wet base plate transmits on the conveyer belt, can avoid the deformation of wet base plate and guaranteed the stability in the wet base plate transmission course.

Drawings

Fig. 1 is a schematic structural view of the cutting and separating device of the present invention, wherein the synchronous cutter is near the upstream end of the double-belt conveyor;

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

FIG. 3 is a schematic structural view of the cutting and separating device of the present invention, wherein the synchronous cutter is near the downstream end of the double-belt conveyor;

FIG. 4 is an enlarged view at A of FIG. 3;

fig. 5 is an enlarged view of fig. 3 at B.

The labels in the figure are:

100-double belt conveyor, 101-conveyor frame,

110-a first guide rail, 111-a first set of rollers, 112-a second set of rollers, 113-a shear chain, 114-a link plate, 115-a first front roller, 116-a first rear roller, 117-a second front roller, 118-a second rear roller,

120-a second guide rail, 121-a guide roller carriage, 122-a carriage,

130-a third guide rail, 131-a nut, 132-a screw rod, 133-a third motor,

141-a first conveyor, 142-a second conveyor,

151-first drive roller, 152-second drive roller,

161-a first motor, 162-a second motor,

171-a first guide roll, 172-a second guide roll, 173-a third guide roll, 174-a fourth guide roll, 175-a fifth guide roll, 176-a sixth guide roll,

200-synchronous cutter, 201-cutter frame, 202-cutting wheel.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings.

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

As shown in fig. 1 to 5, a cutting and separating apparatus for cutting and separating a continuous plate body according to the present embodiment includes a synchronous conveyor, on which a synchronous cutter 200 is spanned;

the synchronous conveyor is a double-belt conveyor 100 and comprises a conveyor frame 101 and 2 sets of telescopic roller sets assembled at the top of the conveyor frame, a cutting wheel 202 of the synchronous cutting machine 200 is positioned between the two telescopic roller sets, the two telescopic roller sets are connected with a cutting machine frame 201 of the synchronous cutting machine 200, and the two telescopic roller sets are a front roller set 111 and a rear roller set 112 respectively;

the conveyor frame 101 is also provided with a guide roller sliding seat 121 capable of reciprocating along the conveyor frame, and the guide roller sliding seat 121 is provided with a first guide roller 171 and a second guide roller 172 which are positioned in front and back;

the double-belt conveyor 100 further comprises a first conveyor belt 141 and a second conveyor belt 142, wherein the first conveyor belt 141 is sleeved on the first roller set 111 and the first guide roller 171, and the second conveyor belt 142 is sleeved on the second roller set 112 and the second guide roller 172;

further comprising:

the first driving mechanism is used for driving the first conveyor belt to transmit;

the second driving mechanism is used for driving the second conveyor belt to transmit, and the second driving mechanism is a variable-speed driving mechanism;

and the third driving mechanism is used for driving the synchronous cutting machine to do reciprocating motion along the conveyor rack, driving the two telescopic roller sets to do telescopic motion along the conveyor rack, and linking the guide roller sliding seats with the second conveyor belt through the first conveyor belt to do reciprocating motion along the conveyor rack.

Adopt the utility model discloses a when cutting separator carries out the operation that will wet base plate cut off and separate in succession, its theory of operation is:

in an initial state, the synchronous cutter 200 is close to the upstream end of the double belt conveyor 100, at which time the first roller set 111 is in a compressed state and the second roller set 112 is in an extended state, as shown in fig. 1. Under the conveying action of the first conveyor belt 141 and the second conveyor belt 142, the continuous wet blank plate gradually travels from the first conveyor belt 141 to the second conveyor belt 142, and when the length of the continuous wet blank plate traveling to the second conveyor belt 142 meets the requirement. Then, the cutting action process is carried out: the synchronous cutter 200 starts to move toward the downstream end of the double belt conveyor 100, and at the same time, the cutting wheel 202 starts to cut the continuous wet blank plate, and the moving speed of the synchronous cutter 200, the conveying speeds of the first conveyor belt 141 and the second conveyor belt 142 are synchronized, so that the cutting wheel 202 can vertically cut the continuous wet blank plate.

When the cutting is completed, the cut wet slab is positioned on the second conveyor 142, and the continuous wet slab continuously extruded is positioned on the first conveyor 141. Then, the separation action process is carried out: the synchronous cutter 200 continues to move toward the downstream end of the double belt conveyor 100, the first conveyor belt 141 continues to maintain its original conveying speed, and the second conveyor belt 142 accelerates its conveying speed by the action of the second driving mechanism (the second driving mechanism is a variable speed driving mechanism), so that the cut wet blank sheet is conveyed onto the belt conveyor (not shown) disposed at the downstream end of the double belt conveyor 100.

During the cutting and separating process, the first conveyor belt 141 continues to maintain the conveying speed, the synchronous cutter 200 always maintains the movement to the downstream end of the double-belt conveyor 100, and the conveying speed of the first conveyor belt 141 is synchronous with the movement speed of the synchronous cutter 200. The cut portion of the continuous wet blank is always maintained at a position between the two telescopic roller sets, and is not transferred to the second conveyor belt 142, so that the continuous wet blank is not dragged. During the cutting and separating process, since the two telescopic roller sets are connected to the cutter frame 201 of the synchronous cutter 200, the first roller set 111 is gradually stretched and the second roller set 112 is gradually compressed.

In cutting and separation process, because the driven second actuating mechanism of drive second conveyer belt is variable speed actuating mechanism, can realize: at the time of cutting, the conveying speed of the second conveyor belt 142 is synchronized with the conveying speed of the first conveyor belt 141; at the time of separation, the conveying speed of the second conveyor belt 142 is increased to be synchronized with the conveying speed of the conveyor belt of the belt conveyor. The cut wet green sheets are separated by switching the conveying speed of the second conveyor belt 142.

When the separation is completed, the synchronous cutter 200 moves to be close to the downstream end of the double belt conveyor 100, at which time, the first roller set 111 is in an extended state and the second roller set 112 is in a compressed state, as shown in fig. 3; when the cut wet blank is separated from the second conveyor 142, the second conveyor 142 is returned to the conveying speed synchronized with the first conveyor 141. Then, the operation process of resetting the synchronous cutting machine 200 is performed: the synchronous cutter 200 moves towards the upstream end of the double-belt conveyor 100 at a high speed and gradually restores to the initial position; during the resetting of the synchronous cutter 200, the first roller set 111 is gradually compressed, and the second roller set 112 is gradually extended, and the continuous wet blank gradually travels from the first conveyor belt 141 onto the second conveyor belt 142. After the synchronous cutter 200 is reset, the continuous wet blanks of smaller length have traveled onto the second conveyor belt 142; when the continuous wet blank travels to a length that meets the requirements of the second conveyor belt 142, the next cutting and separating process is started.

In the cutting and separating device of the present invention, in the whole operation process, the first roller set 111 and the second roller set 112 are driven by the third driving mechanism to drive the synchronous cutting machine 200 to move; and the conveyance of the first conveyor belt 141 is driven by the first driving mechanism; the conveyance of the second conveyor belt 142 is driven by a second drive mechanism; the action processes are independent from each other, do not interfere with each other and are organically combined.

In the cutting and separating apparatus of the present invention, in the initial state, the synchronous cutter 200 is close to the upstream end of the double belt conveyor 100; at this time, the first roller set 111 is in a compressed state, the second roller set 112 is in an extended state, and the guide roller slide 121 is close to the downstream end of the double belt conveyor 100. In the cutting and separating process, when the synchronous cutter 200 moves to the downstream end of the double belt conveyor 100, the first roller set 111 is gradually elongated from a compressed state; while the second roller set 112 is gradually compressed from the extended state; the guide roller slide 121 is moved to the upstream end of the double belt conveyor 100 by the first conveyor belt 141 and the second conveyor belt 142 in conjunction with each other. The synchronous cutter 200 is synchronized such that the first roller set 111 is elongated and the second roller set 112 is compressed; at this time, the first conveyor belt 141 sleeved on the first roller set 111 is lengthened, so that the second conveyor belt 142 sleeved on the second roller set 112 is shortened, and the guide roller slide 121 is provided, so that the circumferential lengths of the first conveyor belt 141 and the second conveyor belt 142 are substantially fixed, the guide roller slide 121 is pulled by the first conveyor belt 142 toward the upstream end of the double-belt conveyor 100, and the guide roller slide 121 pulls the second conveyor belt 142 toward the upstream end of the double-belt conveyor 100; so that the first and second conveyor belts 141 and 142 can be kept in a tensioned state, and their conveyance function is ensured. Similarly, when the synchronous cutting machine 200 is reset, the guide roller slide 121 is pulled by the second conveyor belt 142 toward the downstream end of the double-belt conveyor 100, and the guide roller slide 121 pulls the first conveyor belt 141 toward the downstream end of the double-belt conveyor 100; so that the first and second conveyor belts 141 and 142 can be kept in a tensioned state, and their conveyance function is ensured.

Adopt the utility model discloses a during cutting separator, because the walking of wet base board is always on each conveyer belt, consequently wet base board not with roller direct contact, can avoid the deformation of wet base board. And benefit from the utility model discloses an ingenious design, wet base plate when strideing across different conveyer belts, the transfer rate of conveyer belt keeps synchronous, can not take place to drag the phenomenon because of what different transfer rates lead to. That is, adopt the utility model discloses a cutting separator can realize cutting off the purpose of separation with wet base plate in succession to wet base plate does not with roller direct contact, and wet base plate can not be pulled by the conveyer belt of differential conveying, can avoid the deformation of wet base plate.

Preferably, in another embodiment, as shown in fig. 1 and 3, the telescopic roller set comprises a plurality of rollers, and two ends of each roller are connected by a shear type telescopic chain 113 to form the telescopic roller set. The set of telescoping rollers can be elongated and can also be compressed. The telescopic roller group adopts a plurality of independent unpowered rollers and a conveyor belt to be connected for use, so that the rollers can be matched with each other in real time according to the problems of inconsistent rotating directions and rotating speeds caused by reasons such as conveyor belt conveying speed, cutting reset and the like in the telescopic process of the conveyor belt.

Alternatively, in one embodiment, as shown in fig. 1, 3 and 4, 2 first guide rails 110 are arranged on the top of the conveyor frame 101;

in the first roller group 111, two ends of the most front roller are assembled on the conveyor frame 101, and two ends of the rest rollers are assembled on the two first guide rails 110 in a sliding manner;

in the second roller group 112, two ends of the roller at the last position are assembled on the conveyor frame 101, and two ends of the other rollers are assembled on the two first guide rails 110 in a sliding manner;

the two ends of the roller at the rearmost position of the first roller group 111 are connected with the two ends of the roller at the foremost position of the second roller group 112 through connecting plates 114, and the connecting plates 114 are fixedly connected with the cutting machine frame 201.

When the specific design is adopted, the third driving mechanism drives the synchronous cutting machine to do reciprocating motion along the conveyor frame, and the purpose of driving the two telescopic roller sets to do telescopic motion along the conveyor frame can be achieved.

Further, in another embodiment, as shown in fig. 1, 3 and 4, a first rear roller 116 and a second front roller 117 are arranged between the first roller set 111 and the second roller set 112 and between the two connecting plates 114 in a front-back position; the first conveyor belt 141 is also sleeved on the first rear roller 116, and the second conveyor belt 142 is also sleeved on the second front roller 117; the cutting wheel 202 of the synchronized cutter is located between the first rear roller 116 and the second front roller 117.

Further, in another embodiment, as shown in fig. 1, a first front roller 115 is mounted on the conveyor frame 101 in front of the first roller set 111, and the first conveyor belt 141 is further sleeved on the first front roller 115; behind the second roller set 112, a second rear roller 118 is fitted on the conveyor frame 101, and a second conveyor belt 142 is also fitted over the second rear roller 118.

Alternatively, in one embodiment, as shown in fig. 1, 3 and 5, the conveyor frame 101 is provided with 2 second guide rails 120 under the two telescopic roller sets, the 2 sliding bases 122 of the guide roller sliding base 121 are slidably mounted on the two second guide rails 121, and the first guide roller 171 and the second guide roller 172 of the guide roller sliding base 121 are mounted between the two sliding bases 122.

When the specific embodiment is adopted, the synchronous cutting machine is driven by the third driving mechanism to reciprocate along the conveyor frame, and the purpose that the guide roller sliding seat reciprocates along the conveyor frame through linkage of the first conveyor belt and the second conveyor belt can be achieved.

Alternatively, in another embodiment, as shown in fig. 1, a third guide roller 173 is mounted on the conveyor frame 101 below the front end of the first roller set 111, and the first conveyor belt 141 is further fitted over the third guide roller 173; below the rear end of the second roller set 112, a fourth guide roller 174 is fitted to the conveyor frame 101, and the second conveyor belt 142 is further fitted over the fourth guide roller 174.

Alternatively, in one embodiment, as shown in fig. 1, 2 and 3, the conveyor frame 101 is provided with 2 third guide rails 130 below two sides of the two telescopic roller sets, the cutter frame 201 of the synchronous cutter is slidably mounted on the two third guide rails 130, and the cutter frame 201 is driven by the third driving mechanism to reciprocate along the third guide rails 130.

By adopting the specific implementation mode, the purpose that the synchronous cutting machine reciprocates along the rack of the conveyor can be achieved.

Further, as shown in fig. 1, 2 and 3, the third driving mechanism includes a screw-nut pair, a nut 131 of the screw-nut pair is assembled on the cutter frame 201, a screw 132 of the screw-nut pair is rotatably assembled on the conveyor frame 101, and the screw 132 is connected with a third motor 133 for driving the screw 132 to rotate. The third motor 133 is mounted on the conveyor frame 101.

When the specific embodiment is adopted, the purpose that the synchronous cutting machine is driven to reciprocate along the conveyor frame by the third driving mechanism can be achieved.

Alternatively, in another embodiment, as shown in fig. 1 and 3, the first driving mechanism includes a first driving roller 151 mounted on the conveyor frame 101, the first conveyor belt 141 is further sleeved on the first driving roller 151, and the first driving roller 151 is connected to a first motor 161 for driving the first driving roller 151 to rotate;

the second driving mechanism includes a second driving roller 152 mounted on the conveyor frame 101, the second conveyor belt 142 is further sleeved on the second driving roller 152, the second driving roller 152 is connected to a second motor 162 for driving the second driving roller 152 to rotate, and the second motor 162 is a variable speed motor.

In the above embodiment, when the first motor 161 drives the first driving roller 151 to rotate, the first conveyor belt 141 can be driven to transmit the rotation. When the second motor 162 drives the second driving roller 152 to rotate, the second belt 142 can be driven to rotate. The second motor 162 is a variable speed motor for the purpose of enabling variable speed transmission of the second belt 142. The first motor 161 and the second motor 162 are mounted on the conveyor frame 101. The first driving roller 151 is located below the front end of the first roller set 111, and the second driving roller 152 is located below the rear end of the second roller set 112.

Further, as shown in fig. 1, a fifth guide roller 175 is provided on the conveyor frame 101 behind the first driving roller 151, and the first conveyor belt 141 is further fitted over the fifth guide roller 175; in front of the second driving roller 152, a sixth guide roller 176 is provided on the conveyor frame 101, and the second conveying belt 142 is further fitted over the sixth guide roller 176.

Preferably, the bottom ends of the first and second guide rollers 171 and 172 are coplanar with the top ends of the fifth and sixth guide rollers 175 and 176.

The utility model discloses in, the axis of each roller and each deflector roll is parallel to each other, and all can be rotatory around self axis.

In conclusion, the cutting and separating device for cutting and separating the continuous plate bodies has the advantages that the design is ingenious, when the cutting and separating device is used for cutting and separating the continuous wet blank plates, the wet blank plates always walk on each conveyor belt, so that the wet blank plates are not in direct contact with the rollers, and the deformation of the wet blank plates can be avoided; when the wet blank plate crosses different conveyor belts, the conveying speeds of the conveyor belts are kept synchronous, and the phenomenon of pulling caused by different conveying speeds is avoided. That is, adopt the utility model discloses a cutting separator can realize cutting off the purpose of separation with wet base plate in succession, and wet base plate transmits on the conveyer belt, can avoid the deformation of wet base plate and guaranteed the stability in the wet base plate transmission course.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A cutting and separating device for cutting and separating continuous plate bodies comprises a synchronous conveyor, wherein a synchronous cutting machine (200) is spanned on the synchronous conveyor; the method is characterized in that:

the synchronous conveyor is a double-belt conveyor (100) and comprises a conveyor rack (101) and 2 sets of telescopic roller sets assembled at the top of the conveyor rack, a cutting wheel (202) of the synchronous cutting machine (200) is positioned between the two telescopic roller sets, the two telescopic roller sets are connected with a cutting machine rack (201) of the synchronous cutting machine (200), and the two telescopic roller sets are a front roller set (111) and a rear roller set (112) respectively;

the conveyor frame (101) is also provided with a guide roller sliding seat (121) which can reciprocate along the conveyor frame, and the guide roller sliding seat (121) is provided with a first guide roller (171) and a second guide roller (172) which are arranged at the front and the back;

the double-belt conveyor (100) further comprises a first conveyor belt (141) and a second conveyor belt (142), wherein the first conveyor belt (141) is sleeved on the first roller set (111) and the first guide roller (171), and the second conveyor belt (142) is sleeved on the second roller set (112) and the second guide roller (172);

further comprising:

the first driving mechanism is used for driving the first conveyor belt to transmit;

the second driving mechanism is used for driving the second conveyor belt to transmit, and the second driving mechanism is a variable-speed driving mechanism;

and the third driving mechanism is used for driving the synchronous cutting machine to do reciprocating motion along the conveyor rack, driving the two telescopic roller sets to do telescopic motion along the conveyor rack, and linking the guide roller sliding seats with the second conveyor belt through the first conveyor belt to do reciprocating motion along the conveyor rack.

2. The cutting and separating device as claimed in claim 1, wherein: the telescopic roller set comprises a plurality of rollers, and two ends of each roller are connected through a shear type telescopic chain (113) to form the telescopic roller set.

3. The cutting and separating device as claimed in claim 1, wherein: the top of the conveyor frame (101) is provided with 2 first guide rails (110);

in the first roller group (111), two ends of the roller at the forefront are assembled on the conveyor frame (101), and two ends of the rest rollers are assembled on two first guide rails (110) in a sliding manner;

in the second roller group (112), two ends of the roller at the last position are assembled on the conveyor frame (101), and two ends of the other rollers are assembled on the two first guide rails (110) in a sliding manner;

the two ends of the roller at the rearmost position of the first roller group (111) are connected with the two ends of the roller at the foremost position of the second roller group (112) through connecting plates (114), and the connecting plates (114) are fixedly connected with the cutting machine frame (201).

4. The cutting and separating device as claimed in claim 3, wherein: a first rear roller (116) and a second front roller (117) are arranged between the first roller group (111) and the second roller group (112) and between the two connecting plates (114) in a front-back position; the first conveyor belt (141) is also sleeved on the first rear roller (116), and the second conveyor belt (142) is also sleeved on the second front roller (117); the cutting wheel (202) of the synchronous cutter is positioned between the first rear roller (116) and the second front roller (117).

5. The cutting and separating device as claimed in claim 1 or 4, wherein: a first front roller (115) is assembled on the conveyor frame (101) in front of the first roller group (111), and the first conveyor belt (141) is also sleeved on the first front roller (115); and a second rear roller (118) is assembled on the conveyor rack (101) behind the second roller group (112), and a second conveyor belt (142) is also sleeved on the second rear roller (118).

6. The cutting and separating device as claimed in claim 1, wherein: below the two telescopic roller sets, the conveyor frame (101) is provided with 2 second guide rails (120), 2 sliding seats (122) of the guide roller sliding seat (121) are assembled on the two second guide rails (120) in a sliding manner, and a first guide roller (171) and a second guide roller (172) of the guide roller sliding seat (121) are assembled between the two sliding seats (122).

7. The cutting and separating device as claimed in claim 1, wherein: a third guide roller (173) is assembled on the conveyor rack (101) below the front end of the first roller group (111), and the first conveyor belt (141) is also sleeved on the third guide roller (173); below the rear end of the second roller group (112), a fourth guide roller (174) is mounted on the conveyor frame (101), and the second conveyor belt (142) is further sleeved on the fourth guide roller (174).

8. The cutting and separating device as claimed in claim 1, wherein: and 2 third guide rails (130) are arranged below two sides of the two telescopic roller groups on the conveyor frame (101), a cutting machine frame (201) of the synchronous cutting machine is assembled on the two third guide rails (130) in a sliding manner, and the cutting machine frame (201) is driven by a third driving mechanism to reciprocate along the third guide rails (130).

9. The cutting and separating device as claimed in claim 1 or 8, wherein: the third driving mechanism comprises a screw-nut pair, a nut (131) of the screw-nut pair is assembled on the cutting machine frame (201), a screw rod (132) of the screw-nut pair is rotatably assembled on the transmission machine frame (101), and the screw rod (132) is connected with a third motor (133) for driving the third motor to rotate.

10. The cutting and separating device as claimed in claim 1, wherein: the first driving mechanism comprises a first driving roller (151) assembled on the conveyor frame (101), the first conveyor belt (141) is further sleeved on the first driving roller (151), and the first driving roller (151) is connected with a first motor (161) for driving the first driving roller to rotate;

the second driving mechanism comprises a second driving roller (152) assembled on the conveyor rack (101), the second conveying belt (142) is further sleeved on the second driving roller (152), the second driving roller (152) is connected with a second motor (162) used for driving the second driving roller to rotate, and the second motor (162) is a variable-speed motor.

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