CN221234917U - Coil stock device and film processing equipment - Google Patents

Abstract

The utility model discloses a coil stock device and film processing equipment, and belongs to the technical field of film processing. The material winding device comprises a material discharging assembly, a material receiving assembly, a driving assembly, a control assembly, a plurality of idler wheels, a first buffer assembly and/or a second buffer assembly, wherein the material receiving assembly comprises a material receiving motor and a material receiving roll; the first buffer assembly and the second buffer assembly comprise an air cylinder, a movable pulley, an inductor and two receivers, wherein the output end of the air cylinder is in transmission connection with the movable pulley and the inductor, and the two receivers are spaced along the displacement direction of the inductor so as to receive the induction signals of the inductor when the two receivers are opposite to the inductor. According to the material winding device provided by the embodiment of the utility model, the radius of the material winding or unwinding roll can be determined in real time, so that the angular speed of the material unwinding motor or the material winding motor during material winding and unwinding can be regulated in real time, the stability of controlling the tension of the film is maintained, and the film is prevented from being excessively loosened/tightened.

Description

Coil stock device and film processing equipment

Technical Field

The utility model belongs to the technical field of film processing, and particularly relates to a coil stock device and film processing equipment.

Background

In the production processes related to film manufacture and processing, the film is usually discharged, processed and wound by a winding device, wherein a processing position is located between a discharging position and a winding position. Since films are typically fed/received in a roll-to-roll fashion, there are several problems during processing due to variations in roll radius:

1. The problems that the unreeling roll is used up and the reeling diameter of the reeling roll is too large directly affect the continuous production process, so that the real-time monitoring of the use state of the roll is important;

2. The change of the tension of the film can cause uncontrollable tension of the film if a motor for controlling the winding and unwinding of the material roll can not adjust the change of the angular speed in real time according to the radius due to the change of the radius of the material roll, so that the film is too loose/too tight to influence the production and processing;

3. the stability of film feeding, because of the radius change of the material roll, the motor for controlling the material roll to be wound and unwound needs to adjust the angular speed of the winding and unwinding motor in real time according to the radius, so that the time consumption for providing the film with the same length each time is equal, and the stability of feeding/receiving is ensured.

At present, the industries related to film manufacture and processing inform the manual film replacement by additionally arranging a mark at the tail end of the film and identifying the mark by a sensor; the structure that a film balancing weight/air cylinder/spring and the like are arranged at the outlet of the unreeling roll is adopted, so that the tension stability of the film is maintained. In addition, an ultrasonic sensor for measuring the coil diameter is additionally arranged to detect the coil diameter of the discharged material in real time, so that the angular speed of a motor is adjusted, the tension of a film is maintained stable, and meanwhile, the ultrasonic sensor is used for monitoring that the coil diameter of the discharged material is used up or the coil diameter of the received material is overlarge, so that manual replacement is reminded. However, the ultrasonic sensor for measuring the coil diameter has low precision, is difficult to meet the fine adjustment, and has relatively high cost.

Disclosure of utility model

Aiming at the defects or improvement demands of the prior art, the utility model provides a coiling device and film processing equipment, which aim at determining the radius of a coiling or uncoiling coil in real time, so as to adjust the angular speed of a uncoiling motor or a coiling motor in real time when coiling and uncoiling the coil, maintain and control the stability of the film tension and avoid the over-loosening/over-tightening of the film; the tension of the film can also be regulated by controlling the force of the air cylinder.

In a first aspect, an embodiment of the present utility model provides a coil stock device, where the coil stock device includes a discharging component, a receiving component, a driving component, a control component, a plurality of idler wheels, a first buffer component and/or a second buffer component, where the driving component, the first buffer component and/or the second buffer component are located between the discharging component and the receiving component;

The discharging assembly comprises a discharging motor and a discharging roll, the discharging motor is used for driving the discharging roll to rotate, the receiving assembly comprises a receiving motor and a receiving roll, the receiving motor is used for driving the receiving roll to rotate, and a film discharged by the discharging roll bypasses the first buffer assembly and/or the second buffer assembly and the driving assembly and is wound on the receiving roll;

the idler wheels are arranged between the discharging motor and the receiving motor at intervals so as to reverse the film transmission;

The first buffer assembly and the second buffer assembly comprise an air cylinder, a movable pulley, an inductor and two receivers, wherein the output end of the air cylinder is in transmission connection with the movable pulley and the inductor, and the two receivers are arranged at intervals along the displacement direction of the inductor and are fixedly arranged so as to receive induction signals of the inductor when the receivers are opposite to the inductor;

The control assembly is electrically connected with the discharging motor, the receiving motor, the driving assembly, the first buffer assembly and/or the cylinder of the second buffer assembly respectively.

Optionally, the driving assembly comprises a driving idler wheel, a driven idler wheel and a driving motor, wherein the driving idler wheel and the driven idler wheel are used for clamping the film, and the driving motor is in transmission connection with the driving idler wheel.

Optionally, the distance between the two receivers is S, and the unreeling length of each unreeling is L, where L > 2S.

Optionally, the distance between the two receivers is S, the radius of the discharging roll or the radius of the receiving roll is R, the time that the two receivers respectively sense the sensing signals of the sensor is t _m and t _n, an encoder is arranged on the discharging motor or the receiving motor, and the encoder records that the rotating angle of the discharging motor or the receiving motor at the time of t _m and t _n is alpha, wherein 2pi×r×a/360 ° = 2*S.

Optionally, the angular speed of the discharging motor or the discharging motor during each discharging or discharging is ω, the distance between the two receivers is S, the radius of the discharging roll or the receiving roll is R, and the time difference between the two receivers respectively sensing the sensing signals of the sensor is Δt, where S/Δt=r×ω.

Optionally, the sensor is an inductive chip, and the receiver is a capacitive, inductive or photoelectric sensor or a limit switch.

Optionally, the cylinder is a rodless cylinder.

In a second aspect, the present utility model provides a film processing apparatus comprising a coil arrangement as described in the first aspect.

The above-mentioned improved technical features can be combined with each other as long as they do not collide with each other.

In general, the above technical solutions conceived by the present utility model have the beneficial effects compared with the prior art including:

According to the winding device provided by the embodiment of the utility model, the arc length of film travelling is converted into the known length by adopting the concept of equidistant conversion, and the radius of a material receiving roll or a material discharging roll can be determined in real time, so that the angular speed of a material discharging motor or a material receiving motor during material receiving and discharging is regulated in real time, the stability of controlling the film tension is maintained, and the film is prevented from being too loose/too tight. The device is simple in structure for calculating the coil diameter, simple in calculation mode and low in price of the cache component for calculating the coil diameter. Meanwhile, the first buffer assembly or the second buffer assembly can greatly improve the stability of periodic film feeding.

Moreover, after the radius of the unreeling roll is calculated, the angular speed of the unreeling motor can be set in real time, so that the travelling speed of the film is controlled, and the film caching is completed within the processing time of the film; the use condition of the film can be accurately judged, and the manual replacement of a new material roll can be conveniently reminded.

Meanwhile, after the radius of the material receiving roll is calculated, the angular speed of the material receiving motor can be set in real time, so that the traveling speed of the film is controlled, the material receiving process of the film is guaranteed to be completed in the processing time of the film, the size of the material receiving roll can be accurately judged, and the manual replacement of a new empty material roll is conveniently reminded.

Drawings

Fig. 1 is a schematic structural diagram of a coil stock device according to an embodiment of the present utility model;

FIG. 2 is a schematic structural diagram of a first cache module according to an embodiment of the present utility model;

FIG. 3 is a schematic diagram of a second cache module according to an embodiment of the present utility model.

Like reference numerals denote like technical features throughout the drawings, in particular:

1. A discharging motor; 2. a material receiving motor; 3. a drive assembly; 4. a first cache component; 41. a cylinder; 42. a movable pulley; 43. an inductor; 44. a receiver; 5. a second cache component; 6. an idler; 100. a film.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model. In addition, the technical features of the embodiments of the present utility model described below may be combined with each other as long as they do not collide with each other.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present utility model.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present utility model, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

In the present utility model, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

Examples:

Fig. 1 is a schematic structural diagram of a coil stock device according to an embodiment of the present utility model, as shown in fig. 1, the coil stock device includes a discharging component, a receiving component, a driving component 3, a control component, a plurality of idler wheels 6, a first buffer component 4 and/or a second buffer component 5, where the driving component 3, the first buffer component 4 and/or the second buffer component 5 are located between the discharging component and the receiving component, the first buffer component 4 is located between the discharging component and the driving component 3, and the second buffer component 5 is located between the driving component 3 and the receiving component.

The discharging assembly comprises a discharging motor 1 and a discharging roll, the discharging motor 1 is used for driving the discharging roll to rotate, the receiving assembly comprises a receiving motor 2 and a receiving roll, the receiving motor 2 is used for driving the receiving roll to rotate, and a film discharged by the discharging roll bypasses the driving assembly 3 and is wound on the receiving roll. Because the coil stock device includes the first buffer memory component 4 and/or the second buffer memory component 5, when including the first buffer memory component 4, the film that the blowing was released still bypasses the first buffer memory component 4 and then bypasses the driving component 3, and when including the second buffer memory component 5, the film still bypasses the second buffer memory component 5 and then bypasses the recovery material and is rolled up.

A plurality of idler wheels 6 are arranged between the discharging motor 1 and the receiving motor 2 at intervals to reverse the film 100 transmission.

Fig. 2 is a schematic structural view of a first buffer assembly provided in an embodiment of the present utility model, and fig. 3 is a schematic structural view of a second buffer assembly 5 provided in an embodiment of the present utility model, as shown in fig. 2 and 3, the first buffer assembly 4 and the second buffer assembly 5 include a cylinder 41, a movable pulley 42, an inductor 43, and two receivers 44, wherein an output end of the cylinder 41 is in transmission connection with the movable pulley 42 and the inductor 43, and the two receivers 44 are spaced and fixedly arranged along a displacement direction of the inductor 43 so as to receive an induction signal of the inductor when the two receivers are opposite to the inductor 43. The displacement direction of the sensor 43 means a direction in which the sensor 43 moves by the driving of the cylinder 41. The control assembly is electrically connected with the discharging motor 1, the receiving motor 2, the driving assembly 3, the first buffer assembly 4 and/or the cylinder 41 of the second buffer assembly 5 respectively. When the film passes around the first buffer assembly 4 and/or the second buffer assembly 5, it means that the film passes around the movable pulleys 42 in the two buffer assemblies.

More specifically, for example, in one case, the first buffer assembly 4 and the second buffer assembly 5 each include a bracket, the cylinder 41 body is fixed on the bracket, the output shaft of the cylinder 41 is connected with one of the movable pulley 42 and the sensor 43, the movable pulley 42 is connected with the sensor 43, the two receivers 44 are fixedly connected on the bracket at a distance S, and when the cylinder 41 drives the movable pulley 42 and the sensor 43 to move along the first direction, the sensor 43 can pass through the positions of the two receivers 44 successively. Further, when the film is wound around the movable pulley 42, the extending direction of the film on both sides of the movable pulley 42 is the same as the displacement direction of the movable pulley 42, and in this case, the process of calculating the winding diameter is the simplest. Of course, the connection relation in the cache module is not limited thereto as long as the corresponding function thereof can be realized.

For the material winding device provided by the embodiment of the utility model, when the film 100 is wound and unwound, firstly, the material winding and unwinding are respectively sleeved on the output ends of the unwinding motor 1 and the material winding motor 2, wherein the film winding is sleeved on the unwinding. Then, the cylinder 41 of the first buffer assembly 4 drives the movable pulley 42 to move upwards, the film roll on the unreeling roll rotates at a certain angular speed, and the film 100 is released (at this time, the driving assembly 3 does not work), so that a section of film 100 is buffered by the first buffer assembly 4. At this time, the discharging motor 1 simultaneously provides reverse torque (and rotates during buffering, and does not rotate any more after buffering is finished), so that the film 100 is in a tensioned state. In this process, the cylinder 41 of the first buffer assembly 4 drives the movable pulley 42 and the inductor 43 to move upwards, the inductor 43 sequentially passes through the two receivers 44, the two receivers 44 respectively receive the induction signals of the inductor 43 and transmit the signals to the control assembly, meanwhile, the control assembly receives the rotating angle of the discharge motor 1 in this time period, the radius of the discharge coil and the corresponding angular speed and other data of the discharge coil are calculated after processing, the control assembly can regulate and control the angular speed of the discharge motor 1 in real time, and the tension of the film 100 in the discharge process is ensured to be constant and the film is controlled to travel at a relatively constant speed (discharge buffer).

Then, the driving component 3 works to drive the film 100 to walk (namely, the film walking stage), at this time, the driving force of the driving component 3 is greater than the force provided by the first buffer component cylinder, the cylinder 41 of the second buffer component 5 drives the corresponding movable pulley 42 to move upwards, and the cylinder 41 of the first buffer component drives the movable pulley 42 to move downwards (the discharging motor 1 and the receiving motor 2 do not rotate), so that the film 100 is buffered to the second buffer component 5 again.

Finally, the take-up motor 2 drives the take-up reel to rotate, so that the film 100 is wound up with a certain tension and speed (at this time, the driving assembly 3 is not operated). At this time, the film 100 pulls the cylinder 41 of the second buffer assembly to move downward, and the buffered film 100 is released and recovered onto the receiving roll. Similarly, in this process, the air cylinder 41 of the second buffer assembly drives the inductor 43 to move downwards, the inductor 43 sequentially passes through the two receivers 44, the two receivers 44 respectively receive the induction signals of the inductor 43 and transmit the signals to the control assembly, meanwhile, the control assembly receives the rotation angle of the discharge motor 1 in this time period, calculates the radius of the discharge coil and the corresponding angular velocity and other data after processing, and the control assembly can regulate and control the angular velocity of the receiving motor 2 in real time, so as to ensure that the tension of the film 100 is constant and the receiving is carried out at a relatively constant speed in the receiving process.

That is, the winding device provided by the embodiment of the utility model can determine the radius of the material receiving roll and/or the material discharging roll in real time, so that the angular speed of the material discharging motor 1 or the material receiving motor 2 during material receiving and discharging is adjusted in real time, the film is ensured to walk/receive at a relatively constant speed and tension, the film tension is maintained to be stable, and the film is prevented from being excessively loosened/tightened.

Similarly, when the coil stock device has only one buffer component, the first buffer component 4 or the second buffer component 5. Specifically, when the first size-reducing component is located between the driving component 3 and the unreeling roll, the radius of the unreeling roll and the corresponding angular speed and other data of the unreeling roll are calculated in the buffer memory in the above manner, so that the angular speed of the unreeling motor 1 when the unreeling roll is regulated in real time, and the description is omitted. When the second buffer assembly 5 is located between the driving assembly 3 and the receiving roll, the radius of the receiving roll and the corresponding angular velocity and other data of the receiving roll are calculated in the above manner, so that the angular velocity and the film tension of the receiving motor 2 are adjusted in real time when the receiving roll is retracted, and the detailed description is omitted. And when the first buffer assembly 4 and the second buffer assembly 5 are both arranged, the radius of the unreeling roll and the reeling roll and the corresponding angular speed and other data can be calculated at the same time, so that the angular speeds of the unreeling motor 1 and the reeling motor 2 during reeling and unreeling of the material rolls are adjusted in real time.

In one implementation of the utility model: calculating the radius of the unreeling roll:

when the sensor 43 on the first buffer assembly 4 passes through the two receivers 44 successively, the sensing signals received by the two receivers 44 are t ₁ and t ₂ respectively, the interval between the two receivers 44 is S ₁ (which is a fixed value), and the radius of the corresponding unreeling roll is R ₁. The discharging motor 1 is provided with an encoder which records that the rotating angle of the discharging motor at the time of t ₁ and t ₂ is alpha, the corresponding rotating arc length is L ₁, namely the buffer length of the film 100 is L ₁ (which is equivalent to 2 times of the distance between the two receivers 44), so that,

L₁＝2*S₁； (1)

2π*R₁*α/360°＝2*S₁； (2)

From formulas (1) and (2), R ₁＝(360°/α)*S₁/pi can be known, so that the radius R ₁ of the unreeling roll is calculated in real time. In the period from t ₁ to t ₂, the discharging motor 1 collects α and transmits the α to the control component, the control component processes and obtains the real-time radius R ₁ of the corresponding discharging roll and the angular velocity of the corresponding discharging motor 1 (the product of the angular velocity of the motor and the radius of the discharging roll is the constant discharging roll linear velocity to be controlled), and the control component regulates and controls the angular velocity of the discharging motor 1 in real time, so that the film linear velocity is constant, and the film movement speed is constant and the tension is stable in the discharging process.

Radius calculation for the receiving rolls:

When the sensor 43 on the second buffer assembly 5 passes through the two receivers 44 successively, the sensing signals received by the two receivers 44 are t ₃ and t ₄ respectively, the interval between the two receivers 44 is S ₂ (which is a fixed value), and the radius of the corresponding material receiving roll is R ₂. The material receiving motor 2 is provided with an encoder which records the rotation angle beta of the material receiving motor 2 in the time of t ₃ and t ₄, and the corresponding rotation arc length is recorded as L ₂, namely the rolling length of the film 100 is L ₂ (which is equivalent to 2 times of the distance between the two receivers 44), so that,

L₂＝2*S₂； (3)

2π*R₂*β/360°＝2*S₂； (4)

From formulas (3) and (4), R ₂＝(360°/β)*S₂/pi can be known, so that the radius R ₂ of the receiving roll can be calculated in real time. In the period from t ₃ to t ₄, β is collected by the receiving motor 2 and is transmitted to the control component, the control component obtains the real-time radius R ₂ of the corresponding receiving roll and the angular velocity of the corresponding receiving motor 2 (the product of the angular velocity of the motor and the radius of the receiving roll is the constant linear velocity of the unreeling roll to be controlled) through processing, and the control component regulates and controls the angular velocity of the receiving motor 2 in real time, so that the linear velocity of the film is constant, thereby ensuring that the moving velocity of the film is constant and the tension is kept stable in the receiving process.

It is easy to understand that by calculating the radius of the unreeling roll and the reeling roll, the angular speed of the unreeling motor 1 and the reeling motor 2 can be controlled in real time, so that the running speed of the film 100 during unreeling of the material roll is controlled, the sizes of the reeling roll and the unreeling roll can be accurately judged, a new material roll can be timely replaced, and stable and continuous feeding and reeling of the film 100 are ensured. In addition, the first buffer assembly 4 and the second buffer assembly 5 buffer through the air cylinder 41, and the tension of the film 100 in the film feeding stage can be precisely controlled by controlling the force of the air cylinder 41, so that the influence on processing caused by the tension change of the film 100 due to the asynchronous motor angular speed is prevented. And through setting up the second buffer memory subassembly, still be convenient for receive the material that the material roll can be even receive, further still be convenient for receive the film that the material roll was retrieved and carry out reuse.

It should be noted that the processing of the film 100 may be performed between the discharging motor 1 and the receiving motor 2. Specifically, the processing of the film 100 is performed by a laser processing device or other processing device on a horizontal film section corresponding to the front or rear of the driving assembly 3, at which time the corresponding film 100 is stationary, and the first buffer assembly buffers the next film 100 while receiving the last film 100. Therefore, it is necessary to ensure that the film 100 is buffered and wound up by the first buffer assembly 4 during the processing of the film 100, and ensure the processing continuity and processing efficiency of the film 100. In addition, the device is suitable for the periodic travel of the film 100, wherein the distance of the periodic travel of the film 100 is not less than twice the distance between the two receivers 44. In addition, during use of the movable pulley, the extending direction of the films 100 on both sides of the movable pulley 42 is the same as the displacement direction of the movable pulley 42.

When the discharge is buffered, the torque applied by the discharge motor 1 is controlled to be larger than the tension (wherein the torque is controlled by current).

In another implementation of the utility model, the radius for the unwind is calculated:

The angular speed of the discharging motor during each discharging is omega ₁, the distance between the two receivers is S ₃, the radius of the discharging roll is R ₃, the time difference that the two receivers respectively sense the sensing signals of the sensors is Deltat ₁, therefore,

v₁＝S₃/△t₁； (5)；

v₁＝R₃*ω₁； (6)；

Wherein v ₁ is the linear speed of the discharge coil, and R ₃＝(S₃/△t₁)/ω₁ is known by formulas (5) - (6), so that the radius R ₃ of the discharge coil and the corresponding angular speed of the discharge motor 1 are calculated in real time. In the period of Δt ₁, the discharging motor 1 collects ω ₁ and transmits the ω ₁ to the control component, the control component obtains the real-time radius R ₃ of the corresponding discharging roll and the angular velocity of the corresponding discharging motor 1 through processing, and the control component regulates and controls the angular velocity of the discharging motor 1 in real time, so that the linear velocity of the film is constant, the film moving speed is constant in the receiving process, and the tension is stable.

Radius calculation for the receiving rolls:

The angular speed of the material receiving motor is omega ₂ when receiving materials each time, the distance between the two receivers is S ₄, the radius of the material receiving roll is R ₄, the time difference that the two receivers respectively sense the sensing signals of the sensors is Deltat ₂, therefore,

v₂＝S₄/△t₂； (7)；

v₂＝R₄*ω₂； (8)；

Wherein v ₂ is the linear speed of the receiving roll, and R ₄＝(S₄/△t₂)/ω₂ is known by formulas (7) - (8), so that the radius R ₃ of the discharging roll and the corresponding angular speed of the receiving motor 2 are calculated in real time. In the period of Δt ₂, the discharging motor 1 collects ω ₂ and transmits the ω ₂ to the control component, the control component processes the ω ₂ to obtain a real-time radius R ₄ of the corresponding discharging roll and an angular speed of the corresponding receiving motor 2, and the control component regulates and controls the angular speed of the receiving motor 2 in real time to make the linear speed of the film constant, thereby ensuring that the film movement speed is constant and the tension is stable in the receiving process.

The cylinder 41 may be a rodless cylinder, for example, which has a small installation space and high accuracy.

In one implementation of the utility model, the drive assembly 3 includes a driving idler, a driven idler, and a drive motor, the driving idler and the driven idler being spaced apart to sandwich the film 100, the drive motor being in driving connection with the driving idler. In the above embodiment, the driving idler is driven by the driving motor to rotate, and the film 100 is driven to walk by the friction force generated by the interposition between the driving idler and the driven idler.

In one implementation of the utility model, the sensor 43 is a sensor pad and the receiver 44 is a capacitive, inductive or photoelectric sensor or limit switch. That is, when the sensing piece moves to the capacitive sensor, the inductive sensor or the photoelectric sensor or the limit switch to sense, the capacitive sensor, the inductive sensor or the photoelectric sensor or the limit switch transmits a time signal corresponding to the time signal to the control component, and the control component receives a rotating angle of the control component through the discharging motor 1 or the receiving motor 2, so that the rotating angle of the discharging motor 1 or the receiving motor 2 in the time period is determined.

The utility model also provides film processing equipment which comprises the coil stock device.

It will be readily appreciated by those skilled in the art that the foregoing description is merely a preferred embodiment of the utility model and is not intended to limit the utility model, but any modifications, equivalents, improvements or alternatives falling within the spirit and principles of the utility model are intended to be included within the scope of the utility model.

Claims (8)

1. The material rolling device is characterized by comprising a material discharging component, a material receiving component, a driving component, a control component, a plurality of idler wheels, a first buffer component and/or a second buffer component, wherein the driving component, the first buffer component and/or the second buffer component are positioned between the material discharging component and the material receiving component;

The discharging assembly comprises a discharging motor and a discharging roll, the discharging motor is used for driving the discharging roll to rotate, the receiving assembly comprises a receiving motor and a receiving roll, the receiving motor is used for driving the receiving roll to rotate, and a film discharged by the discharging roll bypasses the first buffer assembly and/or the second buffer assembly and the driving assembly and is wound on the receiving roll;

the idler wheels are arranged between the discharging motor and the receiving motor at intervals so as to reverse the film transmission;

The first buffer assembly and the second buffer assembly comprise an air cylinder, a movable pulley, an inductor and two receivers, wherein the output end of the air cylinder is in transmission connection with the movable pulley and the inductor, and the two receivers are arranged at intervals along the displacement direction of the inductor and are fixedly arranged so as to receive induction signals of the inductor when the receivers are opposite to the inductor;

The control assembly is electrically connected with the discharging motor, the receiving motor, the driving assembly, the first buffer assembly and/or the cylinder of the second buffer assembly respectively.

2. A roll device according to claim 1, wherein the drive assembly comprises a driving idler, a driven idler and a drive motor, the driving idler and the driven idler being adapted to grip a film, the drive motor being in driving connection with the driving idler.

3. A roll arrangement according to claim 1, characterized in that the distance between two of the receptacles is S, the length of each unreel of the unreel being L, wherein L > 2S.

4. A coiling device as claimed in claim 3 wherein the radius of the uncoiling coil or the receiving coil is R, the time when the two receivers sense the sensing signals of the sensors is t _m and t _n respectively, an encoder is arranged on the uncoiling motor or the receiving motor, and the encoder records that the rotation angle of the uncoiling motor or the receiving motor in the time of t _m and t _n is alpha, wherein 2pi R is a/360 ° = 2*S.

5. A coil arrangement according to claim 3, wherein the angular speed of the discharge motor or the collection motor is ω, the radius of the discharge coil or the collection coil is R, and the time difference between the two receivers respectively sensing the sensing signals of the sensors is Δt, wherein S/Δt = R ω.

6. A roll device according to any one of claims 1-5, characterized in that the sensor is a sensor chip and the receiver is a capacitive, inductive or photoelectric sensor or limit switch.

7. A coil arrangement according to any one of claims 1-5, characterized in that the cylinder is a rodless cylinder.

8. A film processing apparatus comprising a coil arrangement as claimed in any one of claims 1 to 7.