CN114619707A

CN114619707A - Speed ratio bag making machine

Info

Publication number: CN114619707A
Application number: CN202210269738.2A
Authority: CN
Inventors: 张一清; 蔡君丞; 黄峰
Original assignee: Hangzhou Sotry Automatic Control Tech Co ltd
Current assignee: Hangzhou Sotry Automatic Control Tech Co ltd
Priority date: 2022-03-18
Filing date: 2022-03-18
Publication date: 2022-06-14
Anticipated expiration: 2042-03-18
Also published as: CN114619707B

Abstract

The invention discloses a speed ratio bag making machine. The present invention includes a heat-seal land for the low-speed portion and a cut-out land for the high-speed portion. The cutting area comprises a third traction roller, a fourth traction roller, a material storage roller, an adjusting roller and a cutter, the material storage roller is arranged between the second traction roller and the third traction roller, the adjusting roller is arranged between the third traction roller and the fourth traction roller, and the cutter is positioned behind the fourth traction roller; the ratio of the up-and-down movement rhythm of the cutter of the cutting area to the heat-sealing up-and-down movement rhythm of the heat-sealing area is 2-n: 1, and the length ratio of the single-time traction material of the heat-sealing area to the cutting area is 2-n: 1. The invention utilizes the mutual combination of electric control and mechanical structure, and provides a mode of forming multiple frequencies by front and rear sections of asynchronous traction, cutter and ironing pressure under the condition that the running linear speed of the heat-sealing material is kept the same, thereby reducing the running speed of the dragging part of the main machine and reducing impact and abrasion on the premise of improving the cutting speed.

Description

Speed ratio bag making machine

Technical Field

The invention relates to the field of bag making equipment on a flexible package production line, in particular to a speed ratio bag making machine.

Background

In the flexible packaging industry, the existing bag making equipment, no matter a 600-type three-edge sealing bag or a 350-type middle sealing bag making machine, is to spread a coiled heat-sealing material (such as a plastic film) through a continuous feeding mechanism and feed a swing roller for transition, and then enter a middle heat-sealing hot-pressing part; according to the characteristics of the made bag shape, a plurality of groups of traction materials (horizontal movement) are matched with a mechanical structure (vertical movement) for longitudinal heat sealing and transverse heat sealing for forming, and finally, a cutter executes a cutting function to realize the processing of the finished bag.

The structure of the existing bag making machine is shown in fig. 1a and 1b, a heat-sealing material 1 firstly enters a first drawing roller 7-1 through the hot pressing of a longitudinal heat seal 2, then enters the hot pressing of a transverse heat seal 3 through a synchronous floating roller 6, then reaches a second drawing roller 7-2, and finally is cut by a cutter 8 to be made into individual bags.

According to the bag making machine shown in fig. 1a and 1b, in order to adapt to the characteristics that the film material is elastic and easy to stretch and deform and the phenomenon that the slippage is easy to generate due to small friction coefficient during traction, servo traction is mostly adopted; the intermittent motion mode is that the heat-sealing material is horizontally moved forward and the host drives the up-and-down motion of heat-sealing ironing to be combined. The duty ratio of the traction and the ironing is 50 percent respectively, so that parameters such as ironing pressure, heating temperature, traction tension and the like are kept relatively stable during heat synthesis molding, the disturbance of the factors is reduced, and the finished product rate of the bag is ensured.

Based on the above traditional mechanical structure, the currently mainstream bag making machine operates stably and well when the maximum beat is 200 times/minute. However, in order to improve the production efficiency of enterprises and reduce the use cost of personnel, the equipment developed in the future is expected to operate at a speed of at least 300 times/min. At present, a plurality of high-speed bag making apparatuses are tried out and popularized by users (such as the WSD600B + type high-speed bag making machine of Huiyun City Fuhui packaging machinery Co., Ltd.), and all of them are products which continuously utilize the original design technology, namely, the mechanical structure device shown in FIGS. 1a and 1 b. Obviously, when the whole machine reaches 300 times/minute, the speed of a main motor driving the transverse sealing heat sealing and the longitudinal sealing heat sealing (such as the rated rotating speed of 3000 revolutions/minute and the speed ratio of 1: 8) can be operated at 2400 revolutions/minute; the motion striking between the sword group that scalds about, the mechanical wear of transmission part and bearing etc. department, the friction between rubber roll, the deflector roll during drawing is all very serious, is in anti fatigue test always just as equipment, is very big unfavorable to mechanical durability.

Meanwhile, in order to ensure the bag making quality and ensure that the firmness and the appearance of the bag are not changed, the whole machine is accelerated by using the original design, and the performance (such as thickness and rigidity) of mechanical materials or the number of hot knife sets is inevitably required to be enhanced to meet the hot pressing strength and the hot pressing time; the inertia of the whole equipment, particularly the ironing set, under high-speed up-and-down impact is increased, and the noise is increased; the horizontal traction time of the whole machine in high-speed operation is shortened, the difficulty of material tension control is improved by frequently starting and stopping the driving part at high speed, the stretching and slipping of the film are serious, and the bag yield is reduced.

In addition, the bag making machine which runs at the speed of less than 200 times/minute is suitable and controllable in cost compared with a matched electric system, such as a servo for dragging the hot knife to move or pulling the film. However, when the speed reaches more than 300 times/min, not only the driving power of each link of the electric system is increased to double the manufacturing cost, but also the speed increase of the whole machine requires that the materials and parts of the transmission part meet the high performance indexes such as wear resistance and heat resistance, and the like, and the popularization or the practicability of the market is obviously insufficient.

Disclosure of Invention

The invention provides a speed ratio bag making machine aiming at the defects of the prior art.

In order to solve the technical problems, the invention adopts the following technical scheme:

a speed ratio bag machine includes a heat seal area for a low speed portion and a cutting area for a high speed portion.

The heat-sealing area comprises a first traction roller, a second traction roller, and transverse heat sealing and longitudinal heat sealing which are arranged between the first traction roller and the second traction roller;

the cutting area comprises a third traction roller, a fourth traction roller, a material storage roller, an adjusting roller and a cutter, the material storage roller is arranged between the second traction roller and the third traction roller, the adjusting roller is arranged between the third traction roller and the fourth traction roller, and the cutter is positioned behind the fourth traction roller;

the ratio of the up-and-down movement rhythm of the cutter of the cutting area to the heat-sealing up-and-down movement rhythm of the heat-sealing area is 2-n: 1, the length ratio of the single-time traction material of the heat-sealing area to the cutting area is 2-n: 1, and n is a positive integer greater than 2.

Further, the device also comprises a synchronous floating roller arranged between the first traction roller and the transverse heat seal, wherein the synchronous floating roller is provided with a first position sensor and is used for compensating the traction distance of the first traction roller.

Furthermore, a first positioning sensor is arranged between the transverse heat seal and the second drawing roller and used for compensating the drawing distance of the second drawing roller.

Furthermore, the adjusting roller is provided with a second position sensor which is used for compensating the traction distance of the third traction roller.

Furthermore, a second positioning sensor is arranged between the adjusting roller and the cutter and is used for ensuring the cutting length of the cutter.

Further, the maximum value of n is 20.

The invention has the beneficial effects that: the invention utilizes the mutual combination of electric control and mechanical structure, and provides a mode of forming multiple frequencies by front and rear sections of asynchronous traction, cutter and ironing pressure under the condition that the running linear speed of the heat-sealing material is kept the same, thereby reducing the running speed of the dragging part of the main machine and reducing impact and abrasion on the premise of improving the cutting speed. The top speed of 300 times/min and the forward-backward speed ratio of 2:1 are taken as examples, the front section cutter is operated at 300 times/min, and the rear section main machine for controlling the heat sealing part is operated at 300 × 1/2=150 times/min. Not only greatly reducing mechanical impact and abrasion, but also prolonging the service life of the whole machine; meanwhile, the electromechanical cost for producing high-speed bag making equipment is saved, and the upgrading and the reconstruction of the existing equipment for less than 200 times/minute are facilitated, so that the economic benefit and the social benefit generated by the invention are obvious, and the method is worthy of being widely popularized in the light industry and packaging industry.

Drawings

FIG. 1a is a three-dimensional schematic view of a mechanical structure of a conventional bag machine;

FIG. 1b is a two-dimensional schematic view of a mechanical structure of a conventional bag machine;

FIG. 2a is a three-dimensional schematic view of the mechanical structure of the bag machine of the present invention;

FIG. 2b is a two-dimensional schematic view of the mechanical structure of the bag machine of the present invention;

FIG. 3a is a graph of the relationship of the pulling action of the fourth pull roll and the second pull roll showing a speed ratio of 2: 1;

FIG. 3b is a drawing action relationship curve of the fourth drawing roll and the second drawing roll with a speed ratio of 3: 1.

Detailed Description

The invention is further described below with reference to the accompanying drawings.

The invention realizes high-speed bag making by adding the traction group between the cutting knife and the second traction of the graph 1a and the graph 1b and changing the original action time sequence and the feeding form of the film, thereby providing a structural device for high-speed bag making, namely a speed ratio bag making machine.

As shown in FIGS. 2a and 2b, the machine of the present invention adds a high speed configuration to the original configuration of the back end bag machine (low speed section) using both transverse and longitudinal heat seals, including two sets of draw rolls (third and fourth draw rolls) and two oscillating rolls (stock and dancer rolls), and a position sensor. In the aspect of electrical control, the front section (high-speed section) adopts a traction length of one bag length (counted as L), and the traction frequency is the frequency multiplication frequency (2N, 3N … …) of the rear section (low-speed section); the traction length of the rear section is an integral multiple of one bag length (2L and 3L … … is calculated), the traction frequency is a single frequency (N), namely the total traction length of the front section and the rear section in a certain period is kept equal. The transverse heat sealing and the longitudinal heat sealing driven by the main machine can run up and down in a low-speed state, and meanwhile, the cutter runs up and down in a rhythm of integral multiple of the rear sections of 2:1, 3:1 … … n:1 and the like, and the speed ratio condition of the cutter is consistent with that of corresponding traction. Generally, an integer of N less than or equal to 20 is the best, and the beat refers to the frequency N of movement per minute.

According to the technical conception, the design structure of the invention is as follows:

the third traction roller 7-3, the fourth traction roller 7-4, the second positioning sensor 10-2, the storage roller 11, the adjusting roller 12 and the cutter 8 form a front section (a cutting area of a high-speed part), and the first traction roller 7-1, the second traction roller 7-2, the first positioning sensor 10-1, the transverse heat seal 3, the longitudinal heat seal 2, the main machine M, the synchronous floating roller 6 and other parts form a rear section (a heat sealing area of a low-speed part). Taking the front-back speed ratio of 2:1 as an example, assuming that the drawing length of the back section is 2L and the tempo is N, the first drawing roller and the second drawing roller both act according to the tempo of N, and draw out the length based on 2L each time. In order to reduce the influence of stretching or slipping factors on the material during operation and keep the tension constant to increase the yield, the first traction roller comprises a partial compensation function, and a compensation signal is from a first position sensor 9-1 for detecting the synchronous floating roller, so that the first traction roller is superposed and compensated on the basis of the set length 2L, and the position of the synchronous floating roller is kept basically unchanged. The distance between 3 boiling hot knife tackle of adjustment horizontal heat-seal is the integral multiple of 2L, and first positioning sensor is responsible for the second carry over pinch rolls according to setting for length 2L and carries out accurate positioning (generally set for length within 1000mm, can be accurate to the back two-bit of decimal point) according to the color mark (for short the color scale) on the film material, makes the film material of dragging out just in time be 2 complete printing width lengths.

The film material after heat sealing passes through the storage roller and then reaches the third traction roller, and then passes through the adjusting roller and then reaches the fourth traction roller and the cutter, thus completing a material feeding route for bag forming. When the first traction roller and the second traction roller finish the action, the host machine drives the rear section ironing knife to move up and down so as to be in contact with the transverse bottom plate 5 and the longitudinal bottom plate 4 to iron and press the film material. The third pull roll is operated at a substantially constant speed and also includes a partial compensation function, and a compensation signal is sent from a second position sensor 9-2 for detecting the adjustment roll so that the third pull roll adds the compensation speed to the set linear speed (linear speed = length 2L × beat N) to keep the position of the adjustment roll substantially constant. The fourth drawing roll was drawn 2 times as fast as the second drawing roll at 2N times/min and the length of the draw was L. Likewise, the knife action responsible for the cut is 2N times per minute. I.e. the fourth drawing roll completes one drawing and the cutter must complete one cutting, all within a respective 50% duty cycle. The second positioning sensor is responsible for the accurate positioning of the fourth traction roller according to the length L according to the color marks on the film material, so that the drawn film material is 1 complete printing width, namely, exactly one bag is cut each time.

As shown in fig. 3a and 3b, the servo motion curves of the fourth and second drawing rolls are respectively given at speed ratios 2:1 and 3:1, with the abscissa representing the time t and the ordinate representing the pulse frequency f of the servo, corresponding to the servo speed. The area of the shaded portion in the figure is the length of the material dragging of each servo. Taking the front-back speed ratio of 2:1 as an example, the curve of the second drawing roller (the shaded part is hereinafter referred to as a large trapezoid) is marked on the upper half part by 2L/N, the curve of the fourth drawing roller (the shaded part is hereinafter referred to as a small trapezoid) is marked on the lower half part by L/2N, and the heights of the large and small trapezoids are consistent. From the two upper and lower graphs, the following relationship can be seen: the length of the bottom side of the large trapezoid is 2 times that of the small trapezoid because the bottom side of the large trapezoid is from the coordinate origin to t1, the bottom side of the small trapezoid is from the coordinate origin to t0, and t0, t1 and t2. Similarly, the length of the upper bottom edge of the large trapezoid is 2 times that of the small trapezoid, and the heights of the two trapezoids are consistent, so that the area of the large trapezoid is 2 times that of the small trapezoid, the length of one-time dragging and discharging of the second traction roller is 2 times that of the fourth traction roller, and the lengths are respectively expressed as 2L and L. On the abscissa, during a period of a large trapezoid (from the origin of the coordinates to t 3), the second traction roller stops once, while the fourth traction roller stops 2 times, 2 times the traction, respectively denoted N and 2N, but for a total length of 2L N = L N2N. As can be seen from the time sequence in the figure, the second traction roller and the fourth traction roller start at the origin at the same time, when the second traction roller reaches half the length, the fourth traction roller finishes one traction, and the two tractions have the same length and are L. The second traction roller continues to drag materials, the fourth traction roller enters a stop state, and the cutter (continuously operates all the time and keeps beat synchronization) enters a cutting state. When the second traction roller finishes traction and enters a heat-sealing ironing state at the time point of t1 (the second traction roller finishes ironing after the time point of t 3), the fourth traction roller starts traction again, the cutter enters a cutting state again when the length L traction is finished at t2, the two traction rollers t2-t3 stop moving, the next cycle of operation is started at the time point of t3, and the bag making process is repeatedly finished.

According to the structure and the control mode, the invention not only meets the requirement of high-speed operation of users (trial operation shows that the speed ratio bag making machine has good effect under the beat of 350 times/min), but also adapts to the popularization of the market under the condition of increasing less cost, and ensures that equipment which accounts for less than 99 percent of the bag making machine in the existing plastic color printing factories or film packaging users can improve the production efficiency of 300 times/min, so that the practicability is not comparable to the bag making machine designed by accelerating the whole machine to 300 times/min according to the prior art.

The invention is finished by using a set of servo motor rotary motion control system with a certain rule and a programmable controller or a singlechip as an inner core, and a sensor for detecting the position correspondingly. Two sets of traction servo and two sets of swing rollers can be added in the original bag making machine (such as SBR-600S type three-edge sealing machine of Shanghai Seibell packaging machinery Co., Ltd.) mechanically, so that the tension in the material dragging process is changed minimally, and a set of control software algorithm for the beat distribution movement of the front traction motor, the middle continuous traction motor and the rear traction motor is formed by utilizing the technical concept.

The power source of the invention is a set of corresponding servo motor, matched driver and material conveying device for realizing conversion of different dragging lengths. The invention is not limited by the type of the controller, and a singlechip, a PLC, a motion controller and an industrial personal computer all belong to the scope of the invention, and the bag making mode that the front section and the rear section move in the way of the frequency of multiples of L length 2N, 3N … … and the like of the front section traction motor, the middle continuous traction motor and the rear section traction motor move in the way of the frequency of multiples of N length 2L, 3L … … and the like and the speed ratio of the front section to the rear section is 2:1, 3:1 … … N:1 and the like is the essence of the invention.

While the preferred embodiments and principles of this invention have been described in detail, it will be apparent to those skilled in the art that variations may be made in the embodiments based on the teachings of the invention and such variations are considered to be within the scope of the invention.

Claims

1. A speed ratio bag machine, includes the heat-seal district of low-speed part and the cutting area of high-speed part, its characterized in that:

2. The speed ratio bag machine of claim 1, wherein: the device also comprises a synchronous floating roller arranged between the first traction roller and the transverse heat seal, wherein the synchronous floating roller is provided with a first position sensor for compensating the traction distance of the first traction roller.

3. The speed ratio bag machine of claim 1, wherein: and a first positioning sensor is arranged between the transverse heat seal and the second traction roller and is used for compensating the traction distance of the second traction roller.

4. The speed ratio bag machine of claim 1, wherein: the adjusting roller is provided with a second position sensor which is used for compensating the traction distance of the third traction roller.

5. The speed ratio bag machine of claim 1, wherein: and a second positioning sensor is arranged between the adjusting roller and the cutter and is used for ensuring the cutting length of the cutter.

6. The speed ratio bag machine of any one of claims 1-5, wherein: the maximum value of n is 20.