CN113997556A - Production equipment and method for preparing oxford fabric based on polyurethane solid waste - Google Patents

Abstract

The invention relates to production equipment for preparing oxford fabric based on polyurethane solid waste, which comprises a base, and a cloth unwinding unit, a laminating mechanism, a drying mechanism and a winding unit which are sequentially arranged on the base, and is characterized in that: a cleaning unit is arranged between the square roll unit and the film covering mechanism; the cleaning unit includes: the cloth shaking module and the dust collection module; the dust collection module is provided with a side, far away from the unreeling unit, of the cloth shaking module, and the longitudinal height of the cloth shaking module is higher than that of the cloth shaking module. The invention has strong practicability and is easy to popularize.

Description

Production equipment and method for preparing oxford fabric based on polyurethane solid waste

Technical Field

The invention relates to the technical field, in particular to production equipment and a method for preparing oxford fabric based on polyurethane solid waste.

Background

The fabric is called oxford, and the multi-purpose terylene polyester cotton blended yarn is interwoven with cotton yarn by adopting weft weight flat square weave. Has the characteristics of easy washing and quick drying, soft hand feeling, good moisture absorption, comfortable wearing and the like. The appearance looks like colored woven cloth. The cotton cloth was named because the student uniform shirt of the earliest oxford university was named using this cotton cloth. In the 1900 s, in order to resist the luxurious fashion and fashion, a small set of specially independent students in Oxford university automatically adopt the combed cotton fabric for design and processing, and the fabric has a two-color effect, is harmonious and calm in color and luster, good in air permeability, comfortable and natural. Therefore, the fabric becomes special for the university uniform of oxford, and is called oxford spinning in the world of European and American centuries.

Common oxford cloth on the market at the present stage generally has a waterproof function, and a layer of waterproof composite membrane is added on the surface of the common woven oxford cloth through a membrane covering structure;

in order to respond to the national call of 'sustainable development', 'green production'; at present, when the composite membrane of the oxford fabric is prepared, pvc sheet bodies, polyurethane solid waste materials and the like on the market are generally recycled as raw materials for preparing the oxford fabric;

by adopting the raw materials, the PVC sheet and the polyurethane solid waste are recycled, the problem of environmental pollution caused by long-term landfill accumulation of the waste is avoided, and a realistic idea is provided for the environment-friendly idea of the industry;

at the present stage, in the preparation process, because the raw material cloth is stored for a long time, dust can be deposited on the surface of the cloth, the roughness of the film can be reduced due to the dust deposition during film coating, and in addition, in the transportation process, the transportation roller can rub against the cloth to generate static electricity, so that the dust deposition phenomenon is easy to occur on the surface of the cloth before film coating, and therefore the cloth needs to be treated.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide production equipment and a method for preparing oxford fabric based on polyurethane solid waste.

The technical scheme of the invention is realized as follows: the utility model provides a production facility based on polyurethane solid waste preparation oxford, includes the base, installs cloth unwinding unit, tectorial membrane mechanism, stoving mechanism and rolling unit on the base in proper order, its characterized in that: a cleaning unit is arranged between the rolling unit and the film covering mechanism; the cleaning unit includes: the cloth shaking module and the dust collection module;

the dust collection module is provided with a cloth shaking module, wherein the cloth shaking module is far away from one side of the unreeling unit and is higher than the dust collection unit.

By adopting the technical scheme, the invention has the beneficial effects that:

before the oxford fabric is coated with the film, the surface of the raw material cloth is cleaned by using the dust absorption module and the cloth shaking module, and dust attracted by static electricity generated by front friction on the surface of the cloth is treated under the action of shaking and dust absorption, so that the subsequent film coating effect is improved, and the film coating quality is improved to avoid the phenomenon of unevenness of the film;

in addition, the cleaning mode mainly adopts the mode of shaking, impacting and flapping the cloth firstly, so that the dust adsorbed on the surface of the raw material cloth due to static electricity floats, and then the fluctuant dust is adsorbed by the adsorption unit with high-voltage load, thereby achieving the effect of cleaning the dust on the surface of an object;

preferably: the cloth shaking module comprises two shaking mechanisms, a first sliding rail and a driving mechanism;

the first sliding rail is fixedly arranged above the cloth; the shaking mechanisms are all slidably mounted on the first sliding rails, the driving mechanism is mounted on the base through a support, and the driving mechanism drives the two shaking mechanisms to slide on the first sliding rails close to or away from each other.

By adopting the technical scheme, the invention has the beneficial effects that:

the shaking module is set into a shaking mechanism which can drive the first slide rail to slide close to or away from each other through a driving mechanism;

when the vibration absorbing mechanism is actually used, a worker can adjust the action position of the driving structure according to the width size of the oxford cloth in a production batch, so that the whole quick-reading size of the oxford cloth can be covered when the vibration absorbing mechanism is used as a seismic source, the dust can be vibrated and fluctuated comprehensively, and the subsequent dust absorbing and cleaning effect is improved;

in addition, because the mechanism is provided with two shaking mechanisms which work independently, when one of the shaking mechanisms is damaged, the other shaking mechanism still can work, so that the problem that when the worker cannot find the damage in time, the worker still can shake the cloth locally is avoided, and the adsorption effect can still be improved due to the mode that rubber is directly adsorbed by the dust absorption structure.

Preferably: the drive mechanism includes: the device comprises a first cylinder, a second slide rail, a mounting plate, an upper rack, a lower rack and a gear;

wherein the first cylinder is mounted on the mounting bracket; the second sliding rail is arranged on the bracket and is parallel to the first sliding rail; the mounting plate is slidably mounted on the second slide rail through a slide block; the lower rack is arranged on the mounting plate; the lower end of one of the shaking mechanisms is provided with the upper rack; the lower end of the other shaking mechanism is fixedly connected with the mounting plate; the gear is meshed between the upper rack and the lower rack; the first cylinder drives the mounting plate to slide on the second slide rail.

By adopting the technical scheme, the invention has the beneficial effects that:

by arranging the driving mechanism into the structure, the structure can realize that one driving cylinder drives two shaking mechanisms to relatively move away or approach by using a gear relative transmission mode,

the driving mode can ensure that when in use, the width center line of the raw material cloth is taken as the center, the two sides of the relative force move in a reciprocating way, so that the accurate control movement can be directly carried out according to the required moving distance, the distance between the shaking structure and the two sides of the cloth is kept the same, and the better control of the vibration source area is realized;

meanwhile, the moving process is driven by a gear, so that the operation is smooth.

Preferably: the shaking mechanism comprises: the head shaking device comprises a machine body, a controller, a driving motor, a head support frame and a shaking head, wherein the machine body is internally provided with a first inner cavity;

the head support frame comprises a shell with a second inner cavity and a moving plate installed in the second inner cavity, and a through hole penetrating into the second inner cavity is formed in the shell.

The machine body is arranged on the first sliding rail in a sliding mode; the driving motor is arranged in a first inner cavity of the machine body, the head support frame is arranged on the machine body, one side of a moving plate in the second inner cavity is jointed with one side of the second inner cavity, which is far away from the through hole, through a pivot, and the moving plate is rotatably and obliquely arranged on the pivot; an inclined shaft is installed at the output shaft end of the driving motor; the free end of the inclined shaft is connected to the moving plate; the shaking head is arranged on the moving plate through a buffer buckle;

the buffer buckle comprises a bottom plate, a flexible sleeve and a positioning ring;

the bottom plate is detachably mounted on the moving plate, one end of the flexible sleeve is fixedly mounted on the bottom plate, the positioning ring is sleeved on the flexible sleeve, the bottom of the positioning ring is fixedly connected with the bottom plate, and the length L1 of the positioning ring is smaller than the length L2 of the flexible sleeve; the jitter head is mounted inside the flexible sleeve.

By adopting the technical scheme, the invention has the beneficial effects that:

by arranging the shaking mechanism in the structure, the driving motor rotates and the output end of the driving motor is arranged in the shape of the inclined shaft, so that the moving plate arranged on the inclined shaft can be controlled to reciprocate close to and far away from the raw material cloth in the rotating process of the driving motor;

during the movement, the shaking head arranged on the mounting head can periodically carry out discontinuous beating on the cloth, so that an oscillation frequency is generated, and when the shaking head is used, the oscillation frequency can be adjusted according to the tightness of the cloth material, so that the cloth can be beaten at high speed and high temperature, and the oscillation effect required by the cloth is ensured;

in the process of driving the inclined shaft to rotate by the driving motor, the inclined shaft can drive the bottom plate to twist by taking the pivot as the center, so that the shaking head can strike cloth by different action points, the phenomenon of local consumption of the shaking head caused by long-time striking at a single position is avoided, the striking part in each area can strike the cloth, and the striking effect is guaranteed.

In addition, the shaking head is connected through the buffer buckle, and the buffer buckle can play a role in buffering in the shaking process of the shaking head, so that the phenomenon that the shaking head collides with the four walls to generate damage in the running process is avoided; the concrete points are as follows:

the buffer buckle mainly adopts a rubber product-a flexible sleeve inside; in addition, because the positioning ring which is just washed is sleeved below the outer part of the flexible sleeve, the rigid positioning ring can ensure that the base of the shaking head can not fall off a designated area and the shaking head can reset along with the inclination of the flexible sleeve;

the rigid ring can stabilize the position of the shaking head while playing a buffering role, so that the seismic source is limited, and the shaking head is ensured to be perfectly reset.

Preferably: a high-temperature disinfection unit is also arranged between the cleaning unit and the unreeling unit; the high-temperature disinfection unit comprises a fan, an air supply pipe and a heat supply module;

the fan is arranged below the cloth, and the output end of the fan vertically faces the cloth upwards through the air supply pipe; the heat supply module is used for heating the air supply pipe.

By adopting the technical scheme, the invention has the beneficial effects that:

the high-temperature disinfection unit is mainly used for disinfecting the cloth through hot air blowing, so that bacteria generated on the cloth which is compared for a long time are disinfected, and the oxford cloth which leaves a factory is clean and sanitary and can be directly used;

it should be noted that the cloth is blown from bottom to top by high-temperature hot air, so that the cloth becomes dry, and the ash floating effect in the subsequent shaking process is improved;

in addition, it should be noted that after the raw material cloth is blown by hot air, the cloth becomes soft, the weaving gaps are kept smooth, and meanwhile, the surface flocks are raised by the hot air, so that the coating slurry is tightly adhered to the cloth during subsequent coating.

Preferably: the heat supply module comprises a Laval pipe, a transmission turbine, a heat absorption pipe, a heat exchange cylinder and a driver for driving the transmission turbine to rotate;

the drying mechanism comprises a drying mechanism, a control device and a control device, wherein the drying mechanism is arranged in a drying room, the drying mechanism is arranged in the drying room, the drying room is arranged in the drying room, and the drying room is arranged in the drying room; the heat absorption pipe is spirally arranged in the Laval pipe, and two ends of the heat absorption pipe penetrate out along one side of the Laval pipe, which is far away from the drying mechanism, and are communicated to the inside of the heat exchange cylinder; the transmission turbine is arranged in the throat of the Laval pipe; and rotated inside the Laval tube by a driver;

wherein, during the actual use, the air feed pipe is wound on the heat exchange cylinder.

By adopting the technical scheme, the invention has the beneficial effects that:

the hot air is used for disinfecting the disinfected raw material cloth, wherein the heat is mainly recovered by recovering the heat discharged by the drying mechanism, so that the heat can be recovered and reused, and the energy-saving effect is improved;

specifically, the method comprises the following steps: the heat discharged by the drying mechanism is recovered through the heating pipe arranged in the Laval pipe, and meanwhile, the drive turbine is driven by the driver, so that negative pressure can be generated at the turbine, the negative pressure can improve the air inlet efficiency, and the heat discharged by the dryer can be recovered to the maximum extent.

Preferably: the input end of the Laval tube is provided with a water absorption module; the water absorption module comprises a mounting bracket, a plurality of water absorption rollers and a paper ring;

the water suction rollers are alternately arranged on the mounting bracket at intervals along the longitudinal direction, and air passing gaps are formed between the adjacent water suction rollers; the paper ring is detachably arranged on the water suction roller.

By adopting the technical scheme, the invention has the beneficial effects that:

the water absorption roller group is used for absorbing water and only supplying heat to pass so as to avoid corrosion caused by long-time exposure of the heat absorption pipe in water vapor;

secondly, still absorb water the roller and adopt vertical alternate interval to set up, can the time steam by the separation many times, guarantee that more water stain is absorbed, improve the efficiency of absorbing water.

Compared with the prior art, the invention has the following beneficial effects:

1. before the oxford fabric is coated with the film, the surface of the raw material cloth is cleaned by using the dust absorption module and the cloth shaking module, and dust attracted by static electricity generated by front friction on the surface of the cloth is treated under the action of shaking and dust absorption, so that the subsequent film coating effect is improved, and the film coating quality is improved to avoid the phenomenon of unevenness of the film;

in addition, the mode of this clearance, mainly adopt earlier to carry out shake, striking, the mode of patting to cloth, make because of the static adsorbs the dust on raw materials cloth surface and float, and then, through the adsorption element of high-voltage load, adsorb the dust of undulation to this reaches the effect with the dust clean up on object surface.

2. The shaking module is set into a shaking mechanism which can drive the first slide rail to slide close to or away from each other through a driving mechanism;

when the vibration absorbing mechanism is actually used, a worker can adjust the action position of the driving structure according to the width size of the oxford cloth in a production batch, so that the whole quick-reading size of the oxford cloth can be covered when the vibration absorbing mechanism is used as a seismic source, the dust can be vibrated and fluctuated comprehensively, and the subsequent dust absorbing and cleaning effect is improved;

in addition, because the mechanism is provided with two shaking mechanisms which work independently, when one of the shaking mechanisms is damaged, the other shaking mechanism can still work, so that the phenomenon that when the worker cannot find the damage in time, the worker can still continue to shake the cloth locally is avoided, and the adsorption effect can still be improved in a mode that rubber is directly adsorbed by a dust absorption structure;

3. by arranging the driving mechanism into the structure, the structure can realize that one driving cylinder drives two shaking mechanisms to relatively move away or approach by using a gear relative transmission mode,

the driving mode can ensure that when in use, the width center line of the raw material cloth is taken as the center, the two sides of the relative force move in a reciprocating way, so that the accurate control movement can be directly carried out according to the required moving distance, the distance between the shaking structure and the two sides of the cloth is kept the same, and the better control of the vibration source area is realized;

meanwhile, the moving process is driven by a gear, so that the operation is stable;

4. by arranging the shaking mechanism in the structure, the driving motor rotates and the output end of the driving motor is arranged in the shape of the inclined shaft, so that the moving plate arranged on the inclined shaft can be controlled to reciprocate close to and far away from the raw material cloth in the rotating process of the driving motor;

during the movement, the shaking head arranged on the mounting head can periodically carry out discontinuous beating on the cloth, so that an oscillation frequency is generated, and when the shaking head is used, the oscillation frequency can be adjusted according to the tightness of the cloth material, so that the cloth can be beaten at high speed and high temperature, and the oscillation effect required by the cloth is ensured;

in the process of driving the inclined shaft to rotate by the driving motor, the inclined shaft can drive the bottom plate to twist by taking the pivot as the center, so that the shaking head can strike cloth by different action points, the phenomenon of local consumption of the shaking head caused by long-time striking at a single position is avoided, the striking part in each area can strike the cloth, and the striking effect is guaranteed.

In addition, the shaking head is connected through the buffer buckle, and the buffer buckle can play a role in buffering in the shaking process of the shaking head, so that the phenomenon that the shaking head collides with the four walls to generate damage in the running process is avoided; the concrete points are as follows:

the buffer buckle mainly adopts a rubber product-a flexible sleeve inside; in addition, because the positioning ring which is just washed is sleeved below the outer part of the flexible sleeve, the rigid positioning ring can ensure that the base of the shaking head can not fall off a designated area and the shaking head can reset along with the inclination of the flexible sleeve;

the rigid ring can stabilize the position of the shaking head while playing a buffering role, so that the seismic source is limited, and the shaking head is ensured to be perfectly reset.

5. The high-temperature disinfection unit is mainly used for disinfecting the cloth through hot air blowing, so that bacteria generated on the cloth which is compared for a long time are disinfected, and the oxford cloth which leaves a factory is clean and sanitary and can be directly used;

it should be noted that the cloth is blown from bottom to top by high-temperature hot air, so that the cloth becomes dry, and the ash floating effect in the subsequent shaking process is improved;

in addition, it should be noted that after the raw material cloth is blown by hot air, the cloth becomes soft, the weaving gaps are kept smooth, and meanwhile, the surface flocks are raised by the hot air, so that the coating slurry is tightly adhered to the cloth during subsequent coating.

6. The hot air is used for disinfecting the disinfected raw material cloth, wherein the heat is mainly recovered by recovering the heat discharged by the drying mechanism, so that the heat can be recovered and reused, and the energy-saving effect is improved;

specifically, the method comprises the following steps: the heat discharged by the drying mechanism is recovered through the heating pipe arranged in the Laval pipe, and meanwhile, the drive turbine is driven by the driver, so that negative pressure can be generated at the turbine, the negative pressure can improve the air inlet efficiency, and the heat discharged by the dryer can be recovered to the maximum extent.

In addition, the invention also discloses a production method for preparing oxford based on polyurethane solid waste, which is suitable for the production equipment and is characterized in that:

a1 preparing raw materials of polyurethane solid waste, a flame retardant and a woven base fabric arranged on an unwinding mechanism;

a2, preparing polyurethane solid waste and a flame retardant into film-coated slurry by an extruder of a film-coating mechanism;

a3, starting a traction roller to convey the woven base fabric on the unwinding mechanism to the front end;

a4 starting a high-temperature disinfection module, and blowing the cloth in a penetrating manner from bottom to top by hot air;

a5 starting a cloth shaking module of the cleaning unit to vibrate and shake the cloth blown by hot air;

a6, starting a dust suction module of the cleaning unit to suck dust generated by shaking;

a7, starting a film covering unit, and conveying film covering slurry in an extruder to the surface of the bottom of the woven fabric for film covering by the film covering unit;

a8, cooling and drying the oxford fabric after the film covering is finished to obtain a finished oxford fabric;

and A9 rolling.

Preferably: comprises a high-temperature cloth disinfection method, which comprises the following steps:

b1 starting the fan to send the hot air into the air supply pipe;

b2 starting a heater in the heat exchange cylinder to heat the internal water source;

b3, the air supply pipe is wound on the outer wall of the heat-melting cylinder for multiple times until the temperature of the internal air is raised, and then the air is blown to longitudinally penetrate and blow the cloth;

b4 starting the lifting device of the heating module, and sending one end of the Laval pipe to the exhaust end of the drying mechanism;

b5 stopping the heater and starting a driver of the heat supply module to drive the transmission turbine to rotate;

b6 forming negative pressure inside the Laval tube through the rotation of the turbine, leading the gas at the exhaust end to enter the Laval tube, and heating the heat absorption tube inside the Laval tube;

the water inside the B7 heat exchange cylinder can circularly flow through the heat absorption pipe to realize heat absorption and continuously heat the air supply pipe.

Preferably: comprises a cloth cleaning method, which comprises the following steps:

c1 drives the first cylinder to drive the two shaking mechanisms to move the middle part of the cloth to two sides according to the width L1 of the cloth;

the distance L2 between the two C2 shaking mechanisms is 1/2 of the cloth width L1; the controller of the shaking mechanism controls the driving motor to operate, and drives the moving plate to do inclined rotating movement by taking the pivot as a midpoint;

the controller of the C3 shaking mechanism controls the driving motor to operate, and drives the moving plate to do inclined rotation movement by taking the pivot as a midpoint;

the shaking head on the C4 pivot rapidly and continuously changes the area of the impact cloth under the action of the moving plate, so that the cloth shakes;

c5 activates the suction unit, which sucks the dust generated by shaking.

Compared with the prior art, the invention has the following beneficial effects:

1. before film covering, the cloth is disinfected by the high-temperature disinfection module, so that bacteria on the cloth can be eliminated, and the cleanliness of the cloth is improved;

in addition, the cloth is sterilized mainly by vertically penetrating and blowing the cloth by high-temperature hot air, so that the cloth can be blown to be soft and dry; when the subsequent shaking mechanism and the dust collection module are used for cleaning the cloth, the effect of cleaning dust on the surface is achieved;

meanwhile, the weaving line clearance of the cloth can be realized through the blowing mode, and meanwhile, the fluff on the surface of the cloth is erected, so that the contact area between the film and the cloth is increased in the film covering process, and the film and the cloth are better combined.

2. When dust is cleaned, the method comprises shaking the cloth and also comprises a dust collection mode for the cloth, and as static electricity is generated due to friction between the cloth and a transport roller in the transport process, the dust is adsorbed on the surface of the cloth and is not easy to clean, so that a vibration source is generated by shaking the cloth, the vibration can separate the dust from the cloth, and the subsequent dust collection effect is improved;

in addition, set up the clearance before the tectorial membrane, can make raw materials cloth handle totally, compare in the mode of clearing up after traditional paper cup is accomplished, the cleanliness factor of improvement product that can be better.

3. The hot air for blowing the cloth mainly takes waste air discharged by the drying mechanism as a heat source, so that the effect of heat recovery is realized;

in addition, the reason that the hot air in the drying structure is not directly blown to the cloth is to avoid the wet cloth caused by the hot air with high humidity and influence the subsequent dust removal effect;

when the heat is recovered, the negative pressure effect of the Laval pipe is mainly adopted as a hot air collecting mode, and hot air can pass through the heat absorbing pipe as much as possible under the action of the negative pressure;

meanwhile, the flow velocity at two ends of the Laval tube is relatively slow, so that the heat recovery effect can be improved;

in addition, the air inlet can be better assisted by adopting a turbine auxiliary air inlet mode when the humidity and the viscosity of hot air are high.

4. When the cloth is oscillated, the two shaking mechanisms are driven to be relatively far away or close by one driving cylinder in a gear relative transmission mode, the driving mode can ensure the effect that the two sides of the relative force reciprocate by taking the width central line of the raw material cloth as the center when the cloth is used,

therefore, according to the actual width of the cloth, the shaking head can be moved to a proper position, so that the vibration sources thrown by shaking can be completely distributed on the whole cloth, the vibration effect is improved, and the required dust collection effect is improved;

in practical use, the distance L2 between the two shaking mechanisms is 1/2 of the width L1 of the cloth, so that the whole cloth can be distributed to the maximum extent, and the vibration effect is good;

meanwhile, the moving process is driven by a gear, so that the operation is stable;

in addition, when in actual use, the vibration level of the shaking head can be controlled so as to adapt to cloth with different widths and thick sizes; .

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic structural view of a driving mechanism;

FIG. 3 is a schematic structural diagram of a dithering mechanism;

FIG. 4 is a cross-sectional view of the dithering mechanism;

FIG. 5 is a schematic view of a buffer buckle;

FIG. 6 is a schematic view of a lint picker;

FIG. 7 is a schematic structural diagram of a heating module;

fig. 8 is a schematic structural view of the water absorption module.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

As shown in fig. 1-7, the invention discloses a production device for preparing oxford based on polyurethane solid waste, which comprises a base 1, and a cloth unwinding unit 2, a film coating mechanism 3, a drying mechanism 4 and a winding unit 5 which are sequentially arranged on the base 1, wherein in the specific embodiment of the invention, a cleaning unit 6 is arranged between the square winding unit 2 and the film coating mechanism 3; the cleaning unit 6 includes:

a cloth shaking module 61 and a dust suction module 62;

the dust collection module 62 is arranged on one side of the cloth shaking module 61 far away from the unreeling unit 2, and the longitudinal height of the dust collection module is higher than that of the cloth shaking module 61.

After the cloth is discharged from the unwinding unit, the cloth is shaken by the shaking unit to float dust on the surface of the cloth, and then the dust collection module is started to quickly and thoroughly collect dust;

the dust collection module is mainly a dust collector with a dust collection port, and an output port of the dust collector faces the surface of the cloth.

Example 2, the difference from example 1 is:

as shown in fig. 2, in an embodiment of the present invention, the cloth shaking module 61 includes: two shaking mechanisms 611, a first slide rail 612 and a driving mechanism 613;

wherein, the first slide rail 612 is fixedly arranged above the cloth; the shaking mechanisms 611 are slidably mounted on the first sliding rail 612, the driving mechanism 613 is mounted on the base 1 through a mounting bracket 614, and the driving mechanism 613 drives the two shaking mechanisms 611 to slide on the first sliding rail 612 in a manner of approaching or separating from each other.

In the embodiment of the present invention, the driving mechanism 613 includes a first cylinder 613a, a second slide rail 613b, a mounting plate 613c, an upper rack 613d, a lower rack 613e, and a gear 613 f;

wherein the first cylinder 613a is mounted on the mounting bracket 614; the second slide rail 613b is mounted on the mounting bracket 614 and arranged parallel to the first slide rail 612; the mounting plate 613c is slidably mounted on the second slide rail 613b by a slider; the lower rack 613e is mounted on the mounting plate 613 c; the upper rack 613d is mounted at the lower end of one of the shaking mechanisms 611; the lower end of the other shaking mechanism 611 is fixedly connected with the mounting plate 613 c; the gear 613f is engaged between the upper rack 613d and the lower rack 613 e; the first cylinder 613a drives the mounting plate to slide on the second rail 613 b.

Before work, a worker drives a first air cylinder to perform telescopic operation in advance according to the size of cloth, the first air cylinder actively drives a first shaking mechanism at an output end to move, a mounting plate at the bottom of the first shaking mechanism moves together, and power is transmitted to a second shaking mechanism to move through a gear transmission part consisting of an upper rack 613d, a lower rack 613e and a gear 613f, so that linkage is realized;

example 3, the difference from example 2 is:

as shown in fig. 3, in an embodiment of the present invention, the shaking mechanism 611 includes: a machine body 611a with a first inner cavity inside, a controller 611b and a driving motor 611 c; a head holder 611d, and a shaking head 611 h;

the head holder 611d includes a housing having a second inner cavity 611d-1 and a moving plate 611f installed in the second inner cavity 611d-1, and the housing is provided with a through hole penetrating the second inner cavity 611 d-1;

the body 611a is slidably disposed on the first slide rail 613 b; the driving motor 611c is installed in the first inner cavity of the body 611a, the head holder 611d is installed on the body 611a, and one side of the moving plate 611f inside the second inner cavity 611d-1 is engaged with one side of the second inner cavity away from the through hole through a pivot 611j, the moving plate 611f is rotatably and inclinedly disposed on the pivot 611 j; an inclined shaft 611k is mounted at the output shaft end of the driving motor 611 c; the free end of the inclined shaft 611k is connected to the moving plate 611 f; the shaking head 611h is mounted on the moving plate 611f through a buffer catch 60;

the buffer buckle comprises a bottom plate 601, a flexible sleeve 602 and a positioning ring 603;

the bottom plate 601 is detachably mounted on the moving plate 611f, one end of the flexible sleeve 602 is fixedly mounted on the bottom plate 601, the positioning ring 603 is sleeved on the flexible sleeve 602, and the bottom of the flexible sleeve is fixedly connected with the bottom plate 601, wherein the length L1 of the positioning ring 603 is smaller than the length L2 of the flexible sleeve 602; the jitter head 611h is mounted inside the flexible sleeve 602.

It should be noted that: the shaking head comprises a cylinder body and bristles uniformly arranged along the outer ring of the cylinder body, wherein the head part of the cylinder body is provided with an elastic impact head in a hollow way;

when the shaking head impacts the cloth in the use process, the impact head can partially shrink towards the column body, so that the buffering effect is achieved, the phenomena that the cloth is damaged and marks are left due to overlarge impact force are avoided, and the impact head resets after the shaking head leaves the cloth;

and, when the impact head can be partly to the cylinder shrink, the brush hair can be direct and cloth contact each other, consequently cloth can produce the friction with the brush hair owing to the effect of transmission roller, the brush hair can be with the brush of the part batting on the cloth this moment, the perk, during the tectorial membrane, thick liquids can contact with the batting, part batting can be inserted in the tectorial membrane thick liquids, along with the sclerosis of thick liquids, the batting can be fixed in the tectorial membrane to this improves the fastness of tectorial membrane, simultaneously because the batting length of batting raw materials cloth is far less than the thickness of tectorial membrane, consequently can not influence the quality of tectorial membrane.

In addition, a lint scraper 100 is further provided on the support 611 d; the lint scraping device 100 comprises a plurality of spring rings 101 arranged on a support frame, and the spring rings 101 are connected through a plurality of connecting rods, wherein the connecting rods comprise a rigid rod 102 and a spring rod 103; one end of the rigid rod 102 is connected with the support frame 611d, and the other end is connected with the spring ring 101 through the spring rod 103;

when cloth transports, the spring coil 101 can scrape the cloth surface, further scrapes the batting on cloth surface, simultaneously with because spring coil 101 itself has elasticity, consequently can not cause the resistance of beating to cloth transports, can not cause cloth surface damage simultaneously, influences the quality of cloth.

Example 4, the difference from example 3 is:

in the specific embodiment of the invention, a high-temperature disinfection unit 7 is further arranged between the cleaning unit 6 and the unreeling unit 2; the high temperature sterilization unit 7 includes: a blower 71, an air supply pipe 72, and a heat supply module 73;

the fan 71 is arranged below the cloth, and the output end of the fan is vertically upward towards the cloth through the air supply pipe 72; the heat supply module 73 is used for heating the air supply pipe 73.

In an embodiment of the present invention, the heat supply module 73 includes: a Laval pipe 731, a transmission turbine 732, a heat absorption pipe 733 and a heat exchange cylinder 734; and a driver 735, the driver 735 being adapted to drive the drive turbine 732 in rotation;

the laval pipe 731 is mounted on one side of the exhaust port of the drying mechanism 4 through a lifting support device 8, and the damp-heat gas at the exhaust port is discharged into the laval pipe 731; the heat absorption pipe 733 is spirally installed in the Laval pipe 731, and two ends of the heat absorption pipe penetrate out along one side of the Laval pipe 731 far away from the drying mechanism 4 and are communicated to the inside of the heat exchange cylinder 734; the drive turbine 732 is mounted within the throat of the Laval tube 731; and rotated inside the laval tube 731 by driver 735;

wherein, in actual use, the air supply pipe 72 is wound on the heat exchange tube 734.

In the specific embodiment of the present invention, a water absorption module 9 is installed at the input end of the laval pipe 731; the water absorption module 9 comprises a mounting bracket 91, a plurality of water absorption rollers 92 and a paper ring 93;

the water suction rollers 92 are alternately arranged on the mounting bracket 91 at intervals along the longitudinal direction, and air passing gaps are arranged between the adjacent water suction rollers 92; the paper ring 93 is detachably arranged on the water suction roller 92;

the water absorption roller group is used for absorbing water and only supplying heat to pass so as to avoid corrosion caused by long-time exposure of the heat absorption pipe in water vapor;

secondly, the water absorbing rollers are arranged at intervals in a longitudinal alternating mode, so that water vapor can be blocked for multiple times, more water stains are absorbed, and the water absorbing efficiency is improved.

After the paper ring absorbs moisture for a certain time, the paper ring can be replaced, in addition, the paper ring comprises an inner layer and an outer layer, and ultrahigh molecular resin particles are filled between the inner side and the outer side, so that the water absorption effect is improved.

By adopting the technical scheme, the invention has the beneficial effects that:

the hot air is used for disinfecting the disinfected raw material cloth, wherein the heat is mainly recovered by recovering the heat discharged by the drying mechanism, so that the heat can be recovered and reused, and the energy-saving effect is improved;

specifically, the method comprises the following steps: the heat discharged by the drying mechanism is recovered through the heating pipe arranged in the Laval pipe, and meanwhile, the drive turbine is driven by the driver, so that negative pressure can be generated at the turbine, the negative pressure can improve the air inlet efficiency, and the heat discharged by the dryer can be recovered to the maximum extent.

Example 5

In addition, the invention also discloses a production method for preparing oxford based on polyurethane solid waste, which is suitable for the production equipment and is characterized in that:

a1 preparing raw materials of polyurethane solid waste, a flame retardant and a woven base fabric arranged on an unwinding mechanism;

a2, preparing polyurethane solid waste and a flame retardant into film-coated slurry by an extruder of a film-coating mechanism;

a3, starting a traction roller to convey the woven base fabric on the unwinding mechanism to the front end;

a4 starting a high-temperature disinfection module, and blowing the cloth in a penetrating manner from bottom to top by hot air;

a5 starting a cloth shaking module of the cleaning unit to vibrate and shake the cloth blown by hot air;

a6, starting a dust suction module of the cleaning unit to suck dust generated by shaking;

a7, starting a film covering unit, and conveying film covering slurry in an extruder to the surface of the bottom of the woven fabric for film covering by the film covering unit;

a8, cooling and drying the oxford fabric after the film covering is finished to obtain a finished oxford fabric;

and A9 rolling.

In one embodiment of the present invention, a method for sterilizing cloth at high temperature is provided, which comprises the following steps:

b1 starting the fan to send the hot air into the air supply pipe;

b2 starting a heater in the heat exchange cylinder to heat the internal water source;

b3, the air supply pipe is wound on the outer wall of the heat-melting cylinder for multiple times until the temperature of the internal air is raised, and then the air is blown to longitudinally penetrate and blow the cloth;

b4 starting the lifting device of the heating module, and sending one end of the Laval pipe to the exhaust end of the drying mechanism;

b5 stopping the heater and starting a driver of the heat supply module to drive the transmission turbine to rotate;

b6 forming negative pressure inside the Laval tube through the rotation of the turbine, leading the gas at the exhaust end to enter the Laval tube, and heating the heat absorption tube inside the Laval tube;

the water inside the B7 heat exchange cylinder can circularly flow through the heat absorption pipe to realize heat absorption and continuously heat the air supply pipe.

In a particular embodiment of the invention, a method of cleaning a piece of cloth is included, comprising the steps of:

c1 drives the first cylinder to drive the two shaking mechanisms to move the middle part of the cloth to two sides according to the width L1 of the cloth;

the distance L2 between the two C2 shaking mechanisms is 1/2 of the cloth width L1; the controller of the shaking mechanism controls the driving motor to operate, and drives the moving plate to do inclined rotating movement by taking the pivot as a midpoint;

the controller of the C3 shaking mechanism controls the driving motor to operate, and drives the moving plate to do inclined rotation movement by taking the pivot as a midpoint;

the shaking head on the C4 pivot rapidly and continuously changes the area of the impact cloth under the action of the moving plate, so that the cloth shakes;

c5 activates the suction unit, which sucks the dust generated by shaking.

In addition, the invention also discloses a method for scraping the batting for coating oxford fabric, which comprises the following steps:

d1, starting the fan 71 to blow the cloth dry and loose;

d2 starting the first cylinder to push the shaking head to a proper position, wherein the spring ring on the lint scraping piece and the cloth at the set position are extruded mutually, and when the cloth is transported under the action of the transport roller, the spring ring scrapes the cloth to scrape the lint;

d3 starting a driving motor, and driving the driving motor to shake or extrude the head to impact the cloth;

d4 when the shaking head impacts the cloth, the impact head will partially contract towards the column, the brush hair contacts with the cloth, part of the catkin on the cloth is brushed and tilted, when the film is coated, the slurry will contact with the catkin, part of the catkin will be inserted into the slurry for coating, and with the hardening of the slurry;

by the brushing method, the coating film and the bottom of the produced oxford fabric can be better combined together, and meanwhile, the brushing method is directly combined with the shaking method, so that the oxford fabric is convenient to use, does not need to increase or decrease the preparation cost, and is easy to popularize and popularize.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (10)

1. The utility model provides a production facility based on polyurethane solid waste preparation oxford, includes base (1), installs cloth on base (1) in proper order and unreels unit (2), tectorial membrane mechanism (3), stoving mechanism (4) and rolling unit (5), its characterized in that: a cleaning unit (6) is arranged between the square roll unit (2) and the film covering mechanism (3); the cleaning unit (6) comprises:

a cloth shaking module (61);

and a dust suction module (62);

the dust collection module (62) is provided with one side, away from the unreeling unit (2), of the cloth shaking module (61), and the longitudinal height of the cloth shaking module (61) is higher than that of the cloth shaking module.

2. The production equipment for preparing oxford based on polyurethane solid waste according to claim 1, characterized in that: the cloth shaking module (61) comprises:

two dithering mechanisms (611);

a first slide rail (612);

and a drive mechanism (613);

wherein the first sliding rail (612) is fixedly arranged above the cloth; the shaking mechanisms (611) are all slidably mounted on the first sliding rail (612), the driving mechanism (613) is mounted on the base (1) through a mounting bracket (614), and the driving mechanism (613) drives the two shaking mechanisms (611) to slide on the first sliding rail (612) in a manner of approaching to or separating from each other.

3. The production equipment for preparing oxford based on polyurethane solid waste according to claim 1, characterized in that: the drive mechanism (613) comprises:

a first cylinder (613 a);

a second slide rail (613 b);

a mounting plate (613 c);

an upper rack (613 d);

a lower rack (613 e);

and a gear (613 f);

wherein the first cylinder (613a) is mounted on the mounting bracket (614); the second sliding rail (613b) is installed on the installation bracket (614) and is arranged in parallel with the first sliding rail (612); the mounting plate (613c) is slidably mounted on the second slide rail (613b) through a slider; the lower rack ((613e)) is mounted on a mounting plate (613 c); the lower end of one shaking mechanism (611) is provided with the upper rack (613 d); the lower end of the other shaking mechanism (611) is fixedly connected with the mounting plate (613 c); the gear (613f) is arranged between the upper rack (613d) and the lower rack (613e) in a meshed manner; the first cylinder (613a) drives the mounting plate to slide on the second slide rail (613 b).

4. The production equipment for preparing oxford based on polyurethane solid waste according to claim 2 or 3, characterized in that: the shaking mechanism (611) comprises:

a body (611a) having a first inner cavity therein;

a controller (611 b);

a drive motor (611 c);

the head support frame (611d) comprises a shell with a second inner cavity (611d-1) and a moving plate (611f) installed in the second inner cavity (611d-1), and the shell is provided with a through hole penetrating into the second inner cavity (611 d-1);

and a shaking head (611 h);

wherein the body (611a) is slidably disposed on a first slide rail (613 b); the driving motor (611c) is installed in the first inner cavity of the machine body (611a), the head support (611d) is installed on the machine body (611a), one side of the moving plate (611f) in the second inner cavity (611d-1) is jointed with one side of the second inner cavity far away from the through hole through a pivot (611j), and the moving plate (611f) is rotatably and slantwise arranged on the pivot (611 j); an inclined shaft (611k) is mounted at the output shaft end of the driving motor (611 c); the free end of the tilting shaft (611k) is connected to the moving plate (611 f); the shaking head (611h) is arranged on the moving plate (611f) through a buffer buckle (60);

the buffer buckle comprises a bottom plate (601), a flexible sleeve (602) and a positioning ring (603);

the bottom plate (601) is detachably mounted on the moving plate (611f), one end of the flexible sleeve (602) is fixedly mounted on the bottom plate (601), the positioning ring (603) is sleeved on the flexible sleeve (602) and the bottom of the flexible sleeve is fixedly connected with the bottom plate (601), wherein the length L1 of the positioning ring (603) is smaller than the length L2 of the flexible sleeve (602); the jitter head (611h) is mounted inside the flexible sleeve (602).

5. The production equipment for preparing oxford based on polyurethane solid waste according to claim 4, characterized in that: a high-temperature disinfection unit (7) is also arranged between the cleaning unit (6) and the unreeling unit (2); the thermal sterilisation unit (7) comprising:

a fan (71);

an air supply duct (72);

and a heating module (73);

the fan (71) is arranged below the cloth, and the output end of the fan is vertically upward towards the cloth through the air supply pipe (72); the heat supply module (73) is used for heating the air supply pipe (73).

6. The production equipment for preparing oxford based on polyurethane solid waste according to claim 5, wherein the production equipment comprises: the heating module (73) comprises:

a Laval tube (731);

a drive turbine (732);

a heat absorbing tube (733);

a heat exchange tube (734);

and a driver (735) for driving the drive turbine (732) in rotation;

the Laval pipe (731) is arranged on one side of an exhaust port of the drying mechanism (4) through a lifting support device (8), and humid heat gas of the exhaust port is discharged into the Laval pipe (731); the heat absorption pipe (733) is spirally arranged in the Laval pipe (731), and two ends of the heat absorption pipe penetrate out along one side of the Laval pipe (731) far away from the drying mechanism (4) and are communicated to the inside of the heat exchange cylinder (734); the drive turbine (732) is mounted within the throat of the Laval tube (731); and rotated inside the laval tube (731) by a driver (735);

wherein, during actual use, the air supply pipe (72) is wound on the heat exchange cylinder (734).

7. The production equipment for preparing oxford based on polyurethane solid waste according to claim 4, characterized in that: the input end of the Laval pipe (731) is provided with a water absorption module (9); the water absorption module (9) comprises:

mounting bracket (91):

a plurality of suction rolls (92);

and a paper ring (93);

the water suction rollers (92) are alternately arranged on the mounting bracket (91) at intervals along the longitudinal direction, and air passing gaps are formed between the adjacent water suction rollers (92); the paper ring (93) is detachably arranged on the water suction roller (92).

8. A production method for preparing oxford based on polyurethane solid waste is suitable for the production equipment and is characterized in that:

a1 preparing raw materials of polyurethane solid waste, a flame retardant and a woven base fabric arranged on an unwinding mechanism;

a2, preparing polyurethane solid waste and a flame retardant into film-coated slurry by an extruder of a film-coating mechanism;

a3, starting a traction roller to convey the woven base fabric on the unwinding mechanism to the front end;

a4 starting a high-temperature disinfection module, and blowing the cloth in a penetrating manner from bottom to top by hot air;

a5 starting a cloth shaking module of the cleaning unit to vibrate and shake the cloth blown by hot air;

a6, starting a dust suction module of the cleaning unit to suck dust generated by shaking;

a7, starting a film covering unit, and conveying film covering slurry in an extruder to the surface of the bottom of the woven fabric for film covering by the film covering unit;

a8, cooling and drying the oxford fabric after the film covering is finished to obtain a finished oxford fabric;

and A9 rolling.

9. The production method for preparing oxford fabric based on polyurethane solid waste according to claim 8, wherein the production method comprises the following steps: comprises a high-temperature cloth disinfection method, which comprises the following steps:

b1 starting the fan to send the hot air into the air supply pipe;

b2 starting a heater in the heat exchange cylinder to heat the internal water source;

b3, the air supply pipe is wound on the outer wall of the heat-melting cylinder for multiple times until the temperature of the internal air is raised, and then the air is blown to longitudinally penetrate and blow the cloth;

b4 starting the lifting device of the heating module, and sending one end of the Laval pipe to the exhaust end of the drying mechanism;

b5 stopping the heater and starting a driver of the heat supply module to drive the transmission turbine to rotate;

b6 forming negative pressure inside the Laval tube through the rotation of the turbine, leading the gas at the exhaust end to enter the Laval tube, and heating the heat absorption tube inside the Laval tube;

the water inside the B7 heat exchange cylinder can circularly flow through the heat absorption pipe to realize heat absorption and continuously heat the air supply pipe.

10. The production method for preparing oxford fabric based on polyurethane solid waste according to claim 9, characterized in that: comprises a cloth cleaning method, which comprises the following steps:

c1 drives the first cylinder to drive the two shaking mechanisms to move the middle part of the cloth to two sides according to the width L1 of the cloth;

the distance L2 between the two C2 shaking mechanisms is 1/2 of the cloth width L1; the controller of the shaking mechanism controls the driving motor to operate, and drives the moving plate to do inclined rotating movement by taking the pivot as a midpoint;

the controller of the C3 shaking mechanism controls the driving motor to operate, and drives the moving plate to do inclined rotation movement by taking the pivot as a midpoint;

the shaking head on the C4 pivot rapidly and continuously changes the area of the impact cloth under the action of the moving plate, so that the cloth shakes;

c5 activates the suction unit, which sucks the dust generated by shaking.

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