CN211616928U - Asphalt waterproof coiled material production line - Google Patents

Abstract

The utility model relates to a pitch waterproofing membrane production facility technical field discloses a pitch waterproofing membrane production line, the production line is at least including child base drying system, pitch preimpregnation system, preimpregnation back drying system, pitch system of covering, tectorial membrane and/or sanding system, coiled material rolling system that the order set up, each system has independent actuating mechanism respectively and pulls child base coiled material. The utility model pulls the base/coiled material passing through the system in each system through the independent driving mechanism, thereby effectively preventing the base/coiled material from being pulled mutually between different systems, thereby reducing the possibility that the base/coiled material is stretched and effectively reducing the shrinkage deformation; the independent drive mechanisms employed in each system ensure the speed of travel of the base/web in each system, thereby increasing the synchronization rate of each system in the production line.

Description

Asphalt waterproof coiled material production line

Technical Field

The utility model relates to a pitch waterproofing membrane production facility technical field, more specifically relates to a pitch waterproofing membrane production line.

Background

The asphalt waterproof coiled material is a coiled material made of asphalt material, base material and surface spreading anti-sticking material, also called asphalt felt, and is commonly used for a pasting type waterproof layer. The asphalt waterproof coiled material comprises a filled coiled material and a non-filled coiled material. The roll-shaped material is made by impregnating base materials such as thick paper or glass fiber cloth, asbestos cloth, cotton and linen fabrics and the like with petroleum asphalt and is called as a base coiled material; asbestos, rubber powder, etc. are mixed into asphalt material, and the rolled material is called rolled coiled material, i.e. tubeless coiled material.

The modified asphalt waterproof coiled material is commonly called modified asphalt felt, and is a curlable sheet-like waterproof material which is prepared by taking a glass fiber felt, a polyester felt, a jute cloth, a polyethylene film, a polyester non-woven fabric, a metal foil or two composite materials as a base, taking synthetic high molecular polymer modified asphalt and oxidized asphalt with the mixing amount of not less than 10% as dip-coating materials and taking powder, sheet and granular mineral materials, synthetic high molecular films and metal films as covering materials. Due to inherent disadvantages of low softening point, high penetration and low temperature brittleness of asphalt itself, the application range of the asphalt is limited when the asphalt is used as a waterproof material. After the asphalt is modified by adding the high molecular polymer, the performances are greatly improved, the weather resistance, the temperature sensitivity (high-temperature characteristic and low-temperature flexibility) and the adaptability to substrate cracking are obviously improved, and the waterproof material prepared by using the modified asphalt is realistic and possible from the traditional 'heavy, thick, long and big' era to the 'light, thin, short and small' industrialized era.

The production process of the waterproof roll material is to dip-coat asphalt on a base such as non-woven fabric, then extrude the base with the dipped asphalt to tamp the asphalt on the base to form a semi-finished roll material, then sand-coat or film-coat and emboss to form a finished roll material, and finally roll up. The base has a certain elastic deformation space, once pulled, the base can shrink and deform, and stress is formed after asphalt is coated; particularly, when and after asphalt is coated, because the asphalt has certain viscosity, a larger acting force is generated between the base coated with the asphalt and the extrusion mechanism due to the adhesion effect, so that the base and the asphalt layer are contracted and deformed to a greater extent, stress is generated, the width of a coiled material is reduced, and more importantly, the low synchronization rate of the existing production line is often caused.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model discloses an overcome above-mentioned prior art at least not enough, provide an asphalt waterproofing membrane production line, solve the not high, child base of asphalt coiled material line synchronization rate or the higher technical problem of coiled material shrinkage factor.

In order to solve the technical problem, the utility model adopts the following technical scheme:

the utility model provides an asphalt waterproofing membrane production line, the production line is at least including base of a tyre drying system, pitch preimpregnation system, drying system, pitch system of covering, tectorial membrane and/or sanding system, coiled material rolling system after preimpregnation that set up in proper order, and each system has independent actuating mechanism to pull base of a tyre/coiled material respectively.

The utility model pulls the base/coiled material passing through the system in each system through the independent driving mechanism, thereby effectively preventing the base/coiled material from being pulled mutually between different systems, thereby reducing the possibility that the base/coiled material is stretched and effectively reducing the shrinkage deformation; the independent drive mechanisms employed in each system ensure the speed of travel of the base/web in each system, thereby increasing the synchronization rate of each system in the production line.

Because the asphalt has viscosity, the coiled material coated with the asphalt also has viscosity, huge adhesion force is generated between the coiled material and working mechanisms in direct contact with an asphalt pre-soaking system, a pre-soaking drying system, an asphalt coating system, a film covering system and/or a sanding system, and especially in a system adopting high-temperature extrusion, the adhesion force is increased sharply, so that large deformation and shrinkage are caused. For this purpose, the tire base drying system, the asphalt pre-soaking system, the post-pre-soaking drying system, the asphalt coating system, the film covering and/or sanding system and the coil winding system respectively have a traction speed, and the traction speeds of the tire base drying system, the asphalt pre-soaking system, the post-pre-soaking drying system, the film covering and/or sanding system and the coil winding system are all based on the traction speed of the asphalt coating system. Taking the asphalt coating system as a reference, the asphalt coating system, the asphalt pre-soaking system and the post-pre-soaking drying system which are carried out before the asphalt coating system are collectively called as the first half section of the production line, and the film covering and/or sanding system and the coiled material winding system which are carried out after the asphalt coating system are collectively called as the second half section of the production line; the first half is the preparation of coating pitch and carries on the stage, and this stage is to base of a tyre/coiled material formation tension the most serious stage, especially pitch is scribbled and is covered the system, and its tension to the coiled material has reached the biggest in the whole production line, the utility model discloses well production line's traction speed is mainly scribbled the system with pitch, is assisted with base of a tyre drying system, pitch preimpregnation system, preimpregnation post-drying system, tectorial membrane and/or sanding system, coiled material rolling system, greatly reduced tension control's the degree of difficulty, further improved the synchronous rate of each system in the production line for the synchronous rate of production can reach 99.7%

Specifically, when the base/coiled material in the production line is stretched or piled, the traction speed of the base drying system, the asphalt pre-soaking system, the post-pre-soaking drying system, the laminating and/or sanding system and the coiled material winding system is adjusted by taking the traction speed of the asphalt coating system as a reference. And the traction speeds of the tire base drying system, the asphalt pre-soaking system, the post-pre-soaking drying system, the film covering and/or sanding system and the coiled material winding system are all controlled in a correlation manner with the traction speed of the asphalt coating system.

The production line further comprises a tire base conveying system arranged in the input direction of the tire base drying system, the tire base conveying system comprises a tire base unfolding frame and a tire base connecting device, the tire base unfolding frame is used for placing tire cloth coiled materials and feeding the tire base connecting device, the tire base connecting device is used for realizing the overlapping of the tire base coiled materials, specifically, the tire base connecting device comprises a tire base overlapping device and a tire base storage frame, the tire base overlapping device is used for realizing the automatic overlapping sewing of the tire base, and the tire base storage frame is used for storing the tire base; the tyre base lapping device comprises brake devices arranged at two ends and is used for ensuring the limited length of lapping connection, and the lapping length is generally not more than 3cm in actual production.

The tire base drying system comprises a shuttle-shaped dryer and a drying traction device, wherein the shuttle-shaped dryer is arranged in parallel and used for heating and drying a tire base, the drying traction device is arranged in the output direction of the shuttle-shaped dryer and driven by an independent driving mechanism, an upper guide roller and a lower guide roller are respectively arranged above and below the shuttle-shaped dryer, the tire base is wound to the upper guide roller from one side of the shuttle-shaped dryer through the lower guide roller under the traction of the drying traction device and then wound to the lower guide roller from the other side of the shuttle-shaped dryer, and ejector rods are arranged on two sides of the shuttle-shaped dryer and used for supporting the tire base from the side surface to enable the tire base and the surface of the shuttle-shaped dryer to keep a gap. The base is wound around the surface of the shuttle-shaped dryer through the guide rollers, and the base is kept away from the surface of the shuttle-shaped dryer at a certain distance through the ejector rods positioned at two sides of the shuttle-shaped dryer. Adopt the utility model provides an in-process that child base drying device dried to the child base, the child base remains the certain distance with fusiformis drying apparatus surface throughout, avoids appearing the boiling hot wrinkle or the high temperature phenomenon of catching fire that local temperature too high leads to, has effectively guaranteed the steady quality and the safety in production of product.

The ejector rods comprise a left ejector rod and a right ejector rod, and the left ejector rod and the right ejector rod are respectively arranged on two sides of the waist of the shuttle-shaped dryer. Specifically, the waist of the shuttle-shaped dryer is the fatter position, the ejector rod is arranged at the position, the whole tyre base wound on the surface of the shuttle-shaped dryer can be effectively supported, and the structure is simple and easy to realize.

The axial direction of the ejector rod is along the winding direction which is vertical to the base of the tire on the surface of the shuttle-shaped dryer. This arrangement smoothly expands the tire base to be isolated from the shuttle dryer.

The ejector rod is movably connected to the shuttle-shaped dryer through a servo motor, and the distance between the base and the surface of the shuttle-shaped dryer is changed by controlling the distance between the ejector rod and the surface of the shuttle-shaped dryer. Specifically, the servo motor is further connected with a master control center of the production line, and the distance between the isolation tire base and the surface of the shuttle-shaped dryer is automatically further expanded by the servo motor after 2-3 min of delay under the conditions of low speed or stop state and power failure of the production line. Therefore, the phenomenon that the tyre base is wrinkled or ignited due to the fact that the surface temperature of the shuttle-shaped dryer is continuously increased under the conditions of low-speed drying or shutdown and power failure can be avoided, and the quality stability and safety of product production are further ensured.

The shuttle-shaped dryer comprises a heat conduction oil containing cavity and a heat conduction oil chamber pipe surrounding the heat conduction oil containing cavity, the heat conduction oil containing cavity is a heat conduction oil sealed cavity filled with heat conduction oil, and the heat conduction oil chamber pipe is used for introducing circulating high-temperature heat conduction oil to heat and dry the tire base. Through the mode of the sealed conduction oil of heat conduction oil heating that flows, realize thermal transmission and heating stoving child base, avoid appearing the direct heating to airtight container on the one hand like this, increase the quality safety management and control degree of difficulty, on the other hand fusiformis drying apparatus central point puts and sets up the conduction oil and hold the chamber and sealed the conduction oil of being equipped with, can realize thermal stable transmission for whole fusiformis drying apparatus has stable and continuous temperature, can realize the stoving to the child base better, avoids production line trouble or scram to lead to the stoving temperature to rise too high in the twinkling of an eye and lead to the child base to be scalded the wrinkle and warp or even catch fire the damage.

The heat conduction oil chamber pipe surrounds the heat conduction oil containing cavity in a parallel repeated winding mode, a heat conduction oil inlet and a heat conduction oil outlet are formed in two ends of the heat conduction oil chamber pipe respectively, the heat conduction oil inlet is located above the heat conduction oil containing cavity, and the outlet is located below the heat conduction oil containing cavity. It should be noted that, the heat conducting oil inlet and the outlet of the heat conducting oil are not limited to this, and may also be left-in right-out or right-in left-out or side-in up-out, as long as the heat conducting oil inlet and the outlet of the heat conducting oil can be realized in the same winding manner, the present invention is within the protection scope.

Specifically, the winding direction of the heat conduction oil bore tube is perpendicular to the winding direction of the base on the surface of the shuttle-shaped dryer, so that efficient heat transfer can be realized by winding for multiple circles, the winding direction of the heat conduction oil bore tube is perpendicular to the winding direction of the base, the heating temperature of the same transverse position of the base can be ensured to be consistent, the drying degree is consistent, synchronous uniform drying of the base can be ensured, and the product stability is good.

The heat conducting oil cavity is of a shuttle-shaped structure. The heat conducting oil chamber pipes are uniformly wound on the surface of the heat conducting oil containing cavity, the shape of the heat conducting oil containing cavity is consistent with that of the shuttle-shaped dryer, the heat conducting oil containing cavity is in a shuttle shape with thin ends and thick middle, the structure can further ensure balanced heat transfer, and the drying effect is good.

The size of the shuttle-shaped dryer is 3-5 m in height, 1.1-1.5 m in width and 0.2-0.6 m in thickness. Specifically, the thickness here refers to the thickness of the position where the waist of the shuttle dryer is fatest.

The tyre base drying system further comprises a closed box body covered on the outer side, so that the tyre base is dried in a relatively closed space, the heat loss is small, the heat utilization rate is high, the drying effect can be effectively improved, and meanwhile, the energy can be saved.

The child base drying system still sets up in the first spring frame of output side, further prevents that waterproofing membrane from being stretched, plays the effect of buffering. The first bouncing frame comprises a guide rail and a bouncing roller which is elastically and slidably connected with the guide rail.

The asphalt pre-dipping system comprises a pre-dipping pool used for containing and/or receiving asphalt and a pre-dipping extrusion mechanism arranged above the pre-dipping pool, wherein the pre-dipping extrusion mechanism is used for extruding a tire base pre-dipped with the asphalt in the pre-dipping pool and comprises at least two pre-dipping extrusion rollers, rotating shafts of the two adjacent pre-dipping extrusion rollers are parallel to each other but not in the same vertical plane, the tire base penetrates into a gap between the two adjacent pre-dipping extrusion rollers from the lower sides of the two adjacent pre-dipping extrusion rollers, and one pre-dipping extrusion roller is driven by a driving mechanism to drag a coiled material independently. The utility model discloses set up the axis of rotation of adjacent twice preimpregnation squeeze roll in the vertical plane of difference for the peak of the preimpregnation squeeze roll under the skew position of the extrusion line between the adjacent twice preimpregnation squeeze roll to the child base that passes formation extrusion, preimpregnation squeeze roll forms the contained angle between tangent plane and the horizontal plane of extrusion line department. The plane of the rotating shafts of the two adjacent pre-dipping squeeze rollers is used as a boundary surface, a groove with a bearing effect is formed between the two adjacent pre-dipping squeeze rollers on the upper side of the boundary surface (namely the upper sides of the two adjacent pre-dipping squeeze rollers), and extruded asphalt is accommodated by the groove when emerging from the upper side of the boundary surface when the tire base is squeezed, so that the phenomenon of roller sticking caused by flowing along the roller surface can be avoided. And when the extruded asphalt emerges from the lower side of the interface (namely the lower sides of two adjacent pre-dipping squeeze rollers), the extruded asphalt falls downwards or flows downwards along the roller surface, but because the pre-dipping squeeze rollers generally rotate along the material feeding direction of the tire base, the asphalt flowing through the roller surface is continuously absorbed again by the tire base, and does not stay on the roller surface for too long time, the problem of roller sticking can be solved to a great extent, so that the defects of air bubbles, surface white spots, poor water impermeability, low peeling strength and the like of a finished product are avoided, and the tension on the tire base/coiled material caused by the defects are avoided.

For higher viscosity asphalt, the extruded asphalt may stick to the pre-preg roll without being reabsorbed as it emerges from the underside of the interface and runs down the roll surface. For this reason, the rotating shafts of two adjacent prepreg extrusion rollers are not in the same horizontal plane, each two adjacent prepreg extrusion rollers comprise an upper roller and a lower roller in a position relation view, and the tire base is fed from one side far away from the upper roller and penetrates into a gap between the upper roller and the lower roller from the lower side. Therefore, the lower roller is wrapped on the feeding side of the tire base penetrating into the gap from the lower side, the asphalt which flows down falls on the tire base which is not extruded by the pre-dipping squeeze roller and cannot be adhered to the pre-dipping squeeze roller, the asphalt is further prevented from being adhered to the roller, especially when the viscosity of the asphalt is high, the extruded asphalt falls on the tire base which is not extruded by the pre-dipping squeeze roller again, the roller adhesion can be effectively prevented, the surface unevenness caused by the asphalt falling on the tire base again can be avoided, the extrusion effect is better, the good operation of equipment can be better kept, the maintenance frequency of the equipment is reduced, the production continuity is ensured, and the production efficiency is improved.

Preferably, the included angle between the plane where the rotating shafts of the two adjacent pre-dipping extrusion rollers are located and the vertical plane is 5-80 degrees; more preferably, the included angle between the plane where the rotating shafts of two adjacent pre-impregnation press rollers are located and the vertical plane is 10-60 degrees. The included angle between the plane where the rotating shafts of the two adjacent pre-dipping extrusion rollers are located and the vertical plane is not small, otherwise, all the asphalt extruded and extruded from the upper side of the interface can not be accommodated in the groove with the bearing effect formed between the two adjacent pre-dipping extrusion rollers; the included angle is not too large, otherwise, even if the lower roller is wrapped by the feeding side of the tire base penetrating into the crack from the lower side, the asphalt extruded and emerging from the lower side of the interface can directly fall onto other prepreg squeeze rollers at lower positions; the size of the included angle is closely related to the viscosity, density, dip coating and extrusion amount of the asphalt, and the included angle needs to be adjusted according to specific conditions.

An extrusion action line for extruding the tire base is formed between two adjacent pre-dipping extrusion rollers, and the distance between the extrusion action line and a vertical plane where the rotating shafts of the pre-dipping extrusion rollers are located is 50-150 mm.

The pre-dipping extrusion mechanism comprises three pre-dipping extrusion rollers, a first roller, a second roller and a third roller are arranged from bottom to top respectively, a tire base is fed from one side far away from the second roller, then the tire base firstly passes through a gap between the first roller and the second roller from the lower side, and then passes through a gap between the second roller and the third roller from the lower side, so that the tire base respectively carries out twice extrusion on the front side and the back side in the three pre-dipping extrusion rollers, the front side and the back side of a coiled material or a pre-dipping coiled material obtained after extrusion are evenly stressed and are not easy to warp, the surface is more flat, and the first roller and the third roller are respectively driven by a driving mechanism to drag the coiled material.

The pre-dipping extrusion mechanism further comprises a pre-dipping rack, the first roller and the third roller are respectively connected to the bottom and the top of the inner side of the pre-dipping rack, and the second roller is connected to the side wall of the inner side of the pre-dipping rack.

According to the scheme, the first roller and the third roller are respectively connected to the bottom and the top of the inner side of the pre-dipping frame in a lifting mode, the heights of the first roller and the third roller can be respectively adjusted according to the performance requirements of coiled materials when the pre-dipping frame is used, so that the distance between the gaps with the squeezing effect among the three pre-dipping extrusion rollers can be adjusted, and the distance between any two adjacent pre-dipping extrusion rollers can be adjusted at will. More preferably, a driving mechanism for driving the first roller to move up and down is arranged at the bottom of the pre-dipping frame, and a driving mechanism for driving the third roller to move up and down is arranged at the top of the pre-dipping frame, so that the distance between the three pre-dipping squeeze rollers for squeezing is adjusted more accurately and conveniently.

In another scheme, the second roller can be movably connected to the side wall of the inner side of the pre-soaking frame, when the pre-soaking frame is used, the second roller can be horizontally displaced according to the performance requirement of the coiled material, so that the distance between the gaps with the extrusion effect among the three pre-soaking extrusion rollers can be adjusted, and the position relation among the three pre-soaking extrusion rollers can be adjusted simultaneously only by adjusting the position of the second roller.

The pre-soaking drying system comprises two drying rollers which are arranged at a distance and are driven independently respectively and have heat. Drying system constitutes at a distance from setting up after preimpregnation mainly by twice independent drive's drying roller, twice drying roller is driven by different actuating mechanism respectively, even if viscosity is big under the high temperature can not lead to waterproofing membrane by tensile deformation under the condition for improving greatly, such setting has avoided twice drying roller to constitute the effect of dragging to the waterproofing membrane that is located between the two on the one hand, on the other hand is equivalent to providing the tension buffer zone for the waterproofing membrane before drying and after drying in the stoving stage, thereby effectively prevent waterproofing membrane by constantly stretching and take place to warp in process of production. Furthermore, the utility model discloses abandoned traditional empty dry mode that separates, adopted the contact to dry, improved the effect of drying greatly. Each drying roller is driven by a variable frequency motor, so that tension is further prevented from being formed on the coiled material, and shrinkage deformation and influence on the synchronous rate of the production line caused by the tension are avoided.

The drying roller is a sandwich oil-passing roller, wherein heat conducting oil is passed through the sandwich oil-passing roller, and the temperature of the heat conducting oil is 190-220 ℃. The design of stoving roller is the sandwich structure of leading to oil to the mode that adopts the conduction oil heating provides the heat for the stoving roller, makes the temperature of stoving roller be unlikely to produce the snap, and the change volume also can not be too big, effectively avoids consequently and destroys waterproofing membrane, leads to catching fire even.

The roll wrapping rate of each drying roll is not lower than 75%, and a higher roll wrapping rate can provide more drying areas, improve the drying efficiency and the utilization rate of the drying rolls, reduce the span of equipment and further save space; more importantly, the higher roll wrapping rate is beneficial to maintaining the temperature balance of heat conducting oil in the drying roll, the phenomenon that the drying roll deforms due to expansion caused by heat and contraction caused by cold is avoided, and the service life of the equipment is prolonged.

The angle between the horizontal plane and the common plane where the first drying roller rotating shaft and the second drying roller rotating shaft are located is 60-80 degrees; the pre-soaking post-drying system is further provided with two drying guide rollers which are arranged at a distance from the first drying roller and the second drying roller respectively, and the roller wrapping rate of the drying rollers is not lower than 75%.

The drying system after presoaking also comprises second bouncing frames arranged on two sides, so that the waterproof roll is further prevented from being stretched, and the buffering effect is achieved. The second bouncing frame comprises a guide rail and a bouncing roller which is elastically and slidably connected with the guide rail.

The asphalt coating system comprises a coating pool for containing and/or receiving asphalt and a double-straight-line extrusion forming mechanism arranged above the coating pool, wherein the double-straight-line extrusion forming mechanism comprises two pairs of coating extrusion rollers which are arranged in pairs at intervals and have heat, the first upper extrusion roller and the first lower extrusion roller are used for rough pressing, the second upper extrusion roller and the second lower extrusion roller are used for fine pressing, and the rotating speed of the first upper extrusion roller is greater than that of the second upper extrusion roller. Scribble and cover the device and adopt two straight row extrusion forming mechanism, each scribbles and covers the squeeze roll and all has the heat, further soften the pitch of contact department in the extrusion and make it extrude the air faster, it produces to fill up the gap, prevent the bubble, realize the coarse compression to waterproofing membrane under the extrusion of squeeze roll and first squeeze roll on the great first of rotational speed, realize the coining to waterproofing membrane under the extrusion of squeeze roll and second squeeze roll on the relatively less second of rotational speed, through the coarse compression, the coining improves extruded rigidness and homogeneity of combining together of two processes. In addition, squeeze roll on the at least first in the extrusion mechanism of two straight rows, squeeze roll is driven by different actuating mechanism respectively on the second, even if viscosity is big under the high temperature can not lead to waterproofing membrane by tensile deformation under the circumstances that improves yet, such setting has avoided on the one hand that two pairs of coating squeeze rolls constitute the effect of dragging to the waterproofing membrane that is located between the two, on the other hand is equivalent to provide the tension buffer area for the waterproofing membrane before the extrusion and after the extrusion in the extrusion stage, thereby effectively prevent waterproofing membrane by constantly stretching and take place to warp in process of production.

The rotating speed of the first upper squeeze roll is greater than that of the first lower squeeze roll, the rotating speed of the second upper squeeze roll is less than that of the second lower squeeze roll, a speed difference is formed between the upper and lower coating squeeze rolls, so that the first upper squeeze roll can form a leveling effect on the upper surface of the waterproof coiled material, the second upper squeeze roll can form a compacting effect on the upper surface of the waterproof coiled material, the leveling effect is achieved while compacting is achieved to a certain degree, the leveling effect is achieved while compacting is achieved, and the tightness uniformity of the waterproof coiled material is further improved. The rotating speed of the first lower extrusion roller is basically consistent with that of the second lower extrusion roller, and the continuous compaction effect of the first lower extrusion roller and the second lower extrusion roller on the lower surface of the waterproof roll is kept. Each coating extrusion roller is respectively driven by four large-torque servo motors.

At the contact position of the coating extrusion roller and the waterproof coiled material, the linear velocity direction of the first upper extrusion roller is the same as the moving direction of the waterproof coiled material, the linear velocity direction of the first lower extrusion roller is opposite to the moving direction of the waterproof coiled material, the linear velocity direction of the second upper extrusion roller is the same as the moving direction of the waterproof coiled material, and the linear velocity direction of the second lower extrusion roller is opposite to the moving direction of the waterproof coiled material. In other words, the rotating directions of all the coating extrusion rollers are kept consistent, and the coating extrusion rollers form a friction force consistent with the trend of the waterproof coiled material at the contact part of the coating extrusion rollers and the waterproof coiled material, so as to push the waterproof coiled material to move forwards; the lower coating cover extrusion roller forms a friction force opposite to the direction of the waterproof coiled material at the contact part of the lower coating cover extrusion roller and the waterproof coiled material, and a certain scraping effect is formed while compaction is carried out.

The distance between the two pairs of coating extrusion rollers is not more than 60cm, and the distance is too large, so that the compaction is not favorably finished at proper temperature, the continuity of the rough pressing and the fine pressing is not favorably maintained, and the synergistic effect of the two is not favorably exerted.

Each coat and cover the squeeze roll and go up and down to be connected in coating and cover pond top through ball screw drive mechanism respectively thereby realize waterproofing membrane thickness control, ball screw drive mechanism has higher precision, is favorable to the accurate control of waterproofing membrane thickness.

The length of the coating extrusion roller is generally larger, the coating extrusion roller with certain length is easy to deform to a certain degree due to the action of gravity or pressure, and the waterproof roll has the defects of thick middle and thin two sides, therefore, the coating extrusion roller is preferably designed into a structure with the diameter of the middle part larger than the diameter of the two ends.

The coating extrusion roller is a sandwich oil passing roller, wherein heat conducting oil is passed through the roller, the temperature of the heat conducting oil is 220 ℃, and the temperature of the roller surface is 170-190 ℃. The design of scribbling the lid squeeze roll is the sandwich structure of leading to oil to the mode that adopts the conduction oil heating provides the heat for scribbling the lid squeeze roll, makes the temperature of scribbling the lid squeeze roll be unlikely to produce the snap, and the change volume also can not be too big, effectively avoids consequently and destroys waterproofing membrane, leads to catching fire even.

The coating device also comprises a dipping material roller which is arranged in the coating pool or can be lifted into the coating pool, and the lower surface of the waterproof coiled material is coated with asphalt. The dipping roller is positioned between the coating pool wall and the double-straight-row extrusion forming mechanism, and a coating guide roller is also arranged between the dipping roller and the coating pool wall, so that the waterproof coiled material is prevented from touching the coating pool wall and even scraping the pitch presoaked in the previous process.

The feeding side of the double-straight-row extrusion forming mechanism is also provided with a waterfall type discharging mechanism which is used for uniformly spreading asphalt on the upper surface of the waterproof coiled material. The feeding side of each pair of coating extrusion rollers is provided with a waterfall type blanking mechanism, and asphalt is coated on the upper surface of the waterproof coiled material before extrusion, so that the waterproof coiled material is ensured to have enough thickness and tightness.

Tectorial membrane and/or sanding system include sanding device, tectorial membrane device, auto-change over device and arrange in the tectorial membrane draw gear by an independent actuating mechanism drive of output direction, the tectorial membrane device removes to set up in sanding device rear, auto-change over device is used for realizing the switching of sanding station and tectorial membrane station. The utility model discloses sanding device and tectorial membrane device have been set up simultaneously, through setting up switching device is actual sanding station and tectorial membrane station, and production facility around sanding or tectorial membrane can be shared to same system like this, and the resource rationalization utilizes, and the product production adaptability of equipment is good. When the film covering device is closer to a production device at a previous station, the temperature of the coiled material is reduced when the coiled material enters the film covering device, and the requirement for a product with relatively high film covering temperature can be met; on the contrary, when the film laminating device is farther away from the production device at the previous station, the temperature of the coiled material is reduced when the coiled material enters the film laminating device, and the requirement for products with relatively low film laminating temperature can be met.

The switching device comprises a lifting device which is matched with the sanding device, the lifting device corresponds to the film coating station when lifting the sanding device, and the lifting device corresponds to the sanding station when lowering the sanding device. Consider that sanding device's structure more distributes along vertical direction, and tectorial membrane device's structure more sets up along the horizontal direction, the utility model discloses a set up sanding device and tectorial membrane device around, utilize sanding device and tectorial membrane device's structural feature simultaneously, adopt hoisting device to realize sanding device and tectorial membrane device's switching, it is concrete, when needs use the tectorial membrane station, through hoisting device raises sanding device, and the coiled material just can directly get into the tectorial membrane device who is located the rear, when needs use sanding device, through hoisting device falls sanding device, and the coiled material directly gets into smoothly in the sanding device.

The tectorial membrane device includes the cooling water bed, sets up in the preceding tectorial membrane mechanism of cooling water bed below, sets up in the cooling water bed top and the back tectorial membrane mechanism at preceding tectorial membrane mechanism rear, and the coiled material is by preceding tectorial membrane mechanism to the coiled material lower surface cover the cooling water bed surface of water cooling of wafing behind basement membrane and the boundary film, then is by the back tectorial membrane mechanism to the coiled material upper surface cover net cloth, facial mask and the boundary film after dip in the cooling water bed aquatic cooling.

Considering that the coiled material is inevitably higher in temperature after the pre-processing, the bottom film and the side film are thinner and easy to be scalded, the pre-laminating mechanism further comprises a pre-cooling device for pre-cooling the bottom film and the side film before laminating. The precooling device is an atomization water spraying device which is used for carrying out atomization water spraying on one side of the basement membrane which is deviated from the contact with the coiled material. Adopt this kind of cooling structure can evenly dispel the heat, reasonable in design, it is effectual to cool down.

The sanding device includes the sanding frame, sets up feeding rod, preceding limit membrane tectorial membrane mechanism, preceding sanding mechanism, back limit membrane tectorial membrane mechanism and back sanding mechanism in the sanding frame, preceding limit membrane tectorial membrane mechanism is used for covering the facial mask of coiled material before the sanding and establishes the facial mask limit membrane, preceding sanding mechanism be used for the coiled material with facial mask before the feeding roller contact is dusted the sand and is handled, back limit membrane tectorial membrane mechanism is used for laying the basement membrane limit membrane to the basement membrane of coiled material before the sanding, back sanding mechanism is used for carrying out the sanding to the bottom surface of coiled material and handles.

To the limit membrane that sanding was handled places, there are two kinds according to the difference of construction method and standard, one kind is the single face and applies the limit membrane, one kind is two-sided application limit membrane, the utility model discloses preceding sanding mechanism has set up preceding limit membrane tectorial membrane mechanism and back membrane tectorial membrane mechanism respectively before the mechanism with back sanding, can lay the limit membrane according to actual conditions like this and handle to the coiled material, both can the single face apply the limit membrane also can two-sided application limit membrane for equipment production adaptability is better.

The front film laminating mechanism is a movable and detachable structure. The utility model discloses set up this kind of structure and can be when the coiled material of production single face application limit membrane, will preceding limit membrane tectorial membrane mechanism removes to dismantle, and is convenient nimble.

The sanding device also comprises a front sand sweeping device and/or a rear sand sweeping device, and a front sand returning box matched with the front sand sweeping device and/or a rear sand returning box matched with the rear sand sweeping device respectively; the front sand sweeping device is arranged behind a sand outlet of the front sand spreading mechanism, and the rear sand sweeping device is arranged behind a sand outlet of the rear sand spreading mechanism; the front sand return box and the rear sand return box are respectively arranged below the front sand sweeping device and the rear sand sweeping device. Through sweeping sand device and back sand device before setting up respectively to and sweep sand device and back sand box before sweeping sand device and back sand device and matching before, can control the homogeneity of spreading sand to facial mask and basement membrane and handling, avoid unnecessary gravel's arbitrary unrestrained simultaneously, realize the recycle of gravel, help the environmental cleaning when resources are saved, guarantee clean production environment.

The output direction of tectorial membrane device still is equipped with the double-deck cooling water bed that is used for further cooling to the coiled material, and the output direction of double-deck cooling water bed still is equipped with the knurling device that is used for carrying out the knurling to the coiled material.

The coiled material rolling system stores the frame, is located including the coiled material of storage coiled material the coiling mechanism of frame output direction is stored to the coiled material and with coiling mechanism control connection's brake motor, the coiled material is stored the frame including adjustable shelf, weight box and with weight box complex counter weight motor, the weight box can be realized with the counter weight motor cooperation the unsteady of adjustable shelf, the brake motor is used for the coiled material rolling system rolling speed prevents the coiled material further to follow when rolling too slowly or pause the storage frame is exported. Because the coiled material is stored the frame and is had and the space that floats, makes the storage length that the frame was stored to the coiled material can freely be adjusted, and then makes tension between the coiled material on the coiled material is stored the frame is controlled, but just because the structure of this kind of mobile regulation has been adopted, also makes a little float and can lead to a large amount of ejection of compact, the utility model discloses set up with coiling mechanism control connection's brake motor, brake motor control the output of frame is stored to the coiled material guarantees the at the uniform velocity rolling of follow-up coiling mechanism.

And a third bouncing frame is arranged between the coiled material storage frame and the rolling device and used for adjusting the tension of the coiled material between the coiled material storage frame and the rolling device. For practical production, because the discharging speed and the winding speed of the production line are very high, even if a brake motor which is in control connection with the winding device is arranged, the winding device is suddenly slowed down or suspended, so that coiled materials with a certain length are accumulated between the coiled material storage rack and the winding device; in addition, because the coil storage rack slightly floats, the coil output from the coil storage rack is suddenly reduced greatly, and at this time, if the winding speed of the winding device is not changed, the coil between the coil storage rack and the winding device is easily broken or deformed. The utility model discloses it can effectively adjust to set up the third spring frame here the coiled material stores the tension of coiled material between frame and the coiling mechanism, also can buffer memory coiled material length between frame and the coiling mechanism is stored to the coiled material.

The third bouncing frame is a double-rod bouncing frame, and the storage length is 15-25 m. The two parallel double-bounce frames are arranged, so that tension adjustment and coiled material buffering can be better realized, and the storage length is 15-25 m most suitable according to actual conditions.

The coiled material storage rack is characterized in that a traction motor is arranged between the coiled material storage rack and the third bouncing rack, the traction motor is used for providing output power for coiled materials on the coiled material storage rack, and the brake motor is in control connection with the traction motor. Can guarantee like this that the coiled material is in traction force on the waterproofing membrane rolling system is balanced, avoids because the resistance of coiled material storage rack is big, improper traction leads to the coiled material to draw and rises to warp even the stretch-break.

The winding device further comprises a safety alarm device, the safety alarm device is connected with the brake motor, and the safety alarm device is used for sending out early warning information and controlling the brake motor to work when the winding device is paused or breaks down.

The winding speed of the winding device is not lower than 130 m/min. The storage length of the coil storage shelf is not less than 120 m. The coiled material storage rack can meet the requirement that the coiling speed of the coiling device can be matched with the length of the coiled material storage rack.

The coiled material rolling system is in still including setting up the fourth spring frame of coiled material storage frame input direction, the fourth spring frame is used for adjusting the coiled material and gets into tension before the coiled material storage frame. Because the utility model discloses the coiled material that well adopted stores the frame for floating structure from top to bottom, its storage capacity change is big, and this coiled material tension after the place ahead process output that also must influence rather than being connected sets up the fourth spring and puts up and can effectively solve this problem.

Compared with the prior art, the utility model has following beneficial effect: the utility model pulls the base/coiled material passing through the system in each system through the independent driving mechanism, thereby effectively preventing the base/coiled material from being pulled mutually between different systems, thereby reducing the possibility that the base/coiled material is stretched and effectively reducing the shrinkage deformation; the independent drive mechanisms employed in each system ensure the speed of travel of the base/web in each system, thereby increasing the synchronization rate of each system in the production line.

Drawings

Fig. 1 is a schematic view of a production line of asphalt waterproofing rolls.

FIG. 2 is a schematic view of a tire base delivery system.

Fig. 3 is a schematic view of a tire-based drying system.

Fig. 4 is a perspective view of the tire base drying system.

Fig. 5 is a cross-sectional view of a tire base drying system.

FIG. 6 is a first schematic view of an asphalt prepreg system.

FIG. 7 is a schematic extrusion of the asphalt prepreg system shown in FIG. 1.

FIG. 8 is a second schematic view of an asphalt prepreg system.

Fig. 9 is a schematic extrusion of the asphalt prepreg system shown in fig. 8.

Fig. 10 is a schematic diagram of a post-presoak drying system.

FIG. 11 is a schematic view of an asphalt coating system.

Fig. 12 is a schematic view of a double inline extrusion mechanism.

Fig. 13 is a schematic view of a coating and/or sanding system.

Fig. 14 is a schematic view of a web roll-up system.

Description of reference numerals: a tire base/coiled material A, a tire base conveying system 100, a tire base spreading frame 110, a tire base lapping device 120, a brake device 121, a tire base storage frame 130, a tire base drying system 200, a shuttle-shaped dryer 210, a heat conducting oil containing cavity 211, a heat conducting oil chamber pipe 212, a heat conducting oil inlet 2121, a heat conducting oil outlet 2122, an upper guide roller 221, a lower guide roller 222, a left ejector rod 231, a right ejector rod 232, a servo motor 233, a first bouncing frame 250, an asphalt preimpregnation system 300, a preimpregnation tank 310, an preimpregnation extrusion roller 320, an upper roller 320a, a lower roller 320b, a first roller 321, a second roller 322, a third roller 323, a preimpregnation rack 330, a preimpregnation drying system 400, a first drying roller 411, a second drying roller 412, a drying guide roller 413, a second bouncing frame 420, a guide rail 421, a bouncing roller 422, an asphalt coating system 500, a coating tank 510, a first upper extrusion roller 521, a first lower extrusion roller 522, the device comprises a second lower extrusion roller 524, a material soaking roller 531, a coating guide roller 532, a waterfall type blanking mechanism 533, a film coating and/or sanding system 600, a sanding frame 611, a feeding roller 612, a front film coating mechanism 6131, a rear film coating mechanism 6132, a front sanding mechanism 6141, a rear sanding mechanism 6142, a front sanding device 6151, a rear sanding device 6152, a cooling water bed 621, a front film coating mechanism 622, a rear film coating mechanism 623, a switching device 630, a coiled material winding system 700, a coiled material storage frame 710, a movable frame 711, a weight box 712, a winding device 720, a brake motor 730, a third bouncing frame 740, a traction motor 750 and a fourth bouncing frame 760.

Detailed Description

The drawings are for illustrative purposes only and are not to be construed as limiting the invention; for the purpose of better illustrating the embodiments, certain features of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product; it will be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted; the positional relationships depicted in the drawings are for illustrative purposes only and are not to be construed as limiting the invention. The present invention will be described in further detail with reference to specific embodiments.

As shown in fig. 1, an asphalt waterproof coiled material production line at least comprises a tire base drying system 200, an asphalt pre-soaking system 300, a post-pre-soaking drying system 400, an asphalt coating system 500, a film covering and/or sanding system 600 and a coiled material rolling system 700 which are arranged in sequence, wherein each system is provided with an independent driving mechanism for dragging a tire base/coiled material.

The utility model pulls the base/coiled material passing through the system in each system through the independent driving mechanism, thereby effectively preventing the base/coiled material from being pulled mutually between different systems, thereby reducing the possibility that the base/coiled material is stretched and effectively reducing the shrinkage deformation; the independent drive mechanisms employed in each system ensure the speed of travel of the base/web in each system, thereby increasing the synchronization rate of each system in the production line.

Since the asphalt has viscosity, the coil will also have viscosity after being coated with asphalt, and a huge adhesion force will be generated between the working mechanisms directly contacting with the asphalt pre-soaking system 300, the post-pre-soaking drying system 400, the asphalt coating system 500, the film covering and/or sanding system 600, especially in the system using high-temperature extrusion, the adhesion force will be increased sharply, and thus a large deformation and shrinkage will be caused. For this purpose, the tire base drying system 200, the asphalt pre-soaking system 300, the post-pre-soaking drying system 400, the asphalt coating system 500, the laminating and/or sanding system 600, and the coil winding system 700 respectively have a traction speed, and the traction speeds of the tire base drying system 200, the asphalt pre-soaking system 300, the post-pre-soaking drying system 400, the laminating and/or sanding system 600, and the coil winding system 700 are based on the traction speed of the asphalt coating system 500. The asphalt coating system 500, the asphalt pre-dipping system 300 and the post-dipping drying system 400 which are performed before the asphalt coating system 500 are referred to as the first half of the production line, and the laminating and/or sanding system 600 and the coil winding system 700 which are performed after the asphalt coating system 500 are referred to as the second half of the production line; the first half is the preparation of coating pitch and carries out the stage, and this stage is to base of a tyre/coiled material formation tension the most serious stage, and especially pitch is scribbled and is covered system 500, and it has reached the biggest in the whole production line to the tension of coiled material, the utility model discloses well production line's traction speed is mainly covered system 500 with pitch to base of a tyre drying system 200, pitch preimpregnation system 300, preimpregnation after drying system 400, tectorial membrane and/or sanding system 600, coiled material rolling system 700 are assisted, greatly reduced tension control's the degree of difficulty, further improved the synchronous rate of each system in the production line for the synchronous rate of production can reach 99.7%

Specifically, when the base/web in the production line is stretched or piled, the pulling speed of the base drying system 200, the asphalt pre-soaking system 300, the post-pre-soaking drying system 400, the laminating and/or sanding system 600, and the web rolling system 700 is adjusted based on the pulling speed of the asphalt coating system 500. The traction speeds of the tire-based drying system 200, the asphalt pre-soaking system 300, the post-pre-soaking drying system 400, the laminating and/or sanding system 600 and the coil winding system 700 are all controlled in association with the traction speed of the asphalt coating system 500.

As shown in fig. 2, the production line further includes a tire base conveying system 100 disposed in the input direction of the tire base drying system 200, the tire base conveying system 100 includes a tire base placing frame 110 and a tire base connecting device, the tire base placing frame 110 is used for placing a tire fabric coiled material and feeding the tire base connecting device, the tire base connecting device is used for realizing the lap joint between the tire base coiled materials, specifically, the tire base connecting device includes a tire base lap joint device 120 and a tire base storage frame 130, the tire base lap joint device 120 is used for realizing the automatic lap joint sewing of the tire base, and the tire base storage frame 130 is used for storing the tire base; the base lap-joint device 120 comprises brake devices 121 arranged at two ends and used for ensuring the limited length of lap joint, and the lap joint length in actual production is generally not more than 3 cm.

As shown in fig. 3 to 5, the tire base drying system 200 includes a parallel arranged shuttle dryer 210 for heating and drying the tire base and a drying traction device arranged in the output direction of the shuttle dryer 210 and driven by an independent driving mechanism, an upper guide roller 221 and a lower guide roller 222 are respectively arranged above and below the shuttle dryer 210, the tire base is wound from one side of the shuttle dryer 210 to the upper guide roller 221 through the lower guide roller 222 under the traction of the drying traction device, and then wound from the other side of the shuttle dryer 210 to the lower guide roller 222, and ejector rods are arranged on both sides of the shuttle dryer 210 for laterally supporting the tire base to keep a gap between the tire base and the surface of the shuttle dryer 210. The base is wound around the surface of the shuttle-shaped dryer 210 by the guide rollers, and the base is kept away from the surface of the shuttle-shaped dryer 210 by a certain distance by the push rods positioned at two sides of the shuttle-shaped dryer 210. Adopt the utility model provides an in-process that child base drying device dried to the child base, the child base remains the certain distance with fusiformis drying apparatus 210 surface throughout, avoids appearing the boiling hot wrinkle or the high temperature phenomenon of catching fire that local temperature too high leads to, has effectively guaranteed the steady quality and the safety in production of product.

The push rods include a left push rod 231 and a right push rod 232, and the left push rod 231 and the right push rod 232 are respectively disposed at both sides of the waist of the shuttle dryer 210. Specifically, the waist of the shuttle-shaped dryer 210 is the most fat position, and the ejector rod is arranged at the position, so that the whole tyre base wound on the surface of the shuttle-shaped dryer 210 can be effectively supported, and the structure is simple and easy to realize.

The axial direction of the mandrel is along the winding direction of the vertical base on the surface of the shuttle-shaped dryer 210. This arrangement smoothly expands the tire base to be isolated from the shuttle dryer 210.

The lift pins are movably connected to the shuttle dryer 210 through a servo motor 233, and the distance between the base of the tire and the surface of the shuttle dryer 210 is changed by controlling the distance between the lift pins and the surface of the shuttle dryer 210. Specifically, the servo motor 233 is further connected with a master control center of the production line, and when the production line is in a low-speed or stop state and is powered off, the distance between the isolated tire base and the surface of the shuttle-shaped dryer 210 is automatically further expanded by the servo motor 233 after 2-3 min delay. Therefore, the situation that the temperature of the surface of the shuttle-shaped dryer 210 is continuously increased due to low-speed drying or shutdown and power failure can be avoided, the tyre base is prevented from being wrinkled or ignited, and the quality stability and the safety of product production are further ensured.

The shuttle-shaped dryer 210 comprises a heat conduction oil containing cavity 211 and a heat conduction oil chamber pipe 212 surrounding the heat conduction oil containing cavity 211, the heat conduction oil containing cavity 211 is a heat conduction oil sealed cavity with heat conduction oil inside, and the heat conduction oil chamber pipe 212 is used for introducing circulating high-temperature heat conduction oil to heat and dry the tire base. Through the mode of the sealed conduction oil of heat conduction oil of flow heat conduction oil heating, realize thermal transmission and heating stoving child base, avoid appearing the direct heating to airtight container on the one hand like this, increase the quality safety management and control degree of difficulty, on the other hand shuttle drying apparatus 210 central point puts and sets up the conduction oil and hold the chamber 211 and the sealed conduction oil that is equipped with, can realize thermal stable transmission for whole shuttle drying apparatus 210 has stable and continuous temperature, can realize better the stoving to the child base, avoids production line trouble or scram to lead to the stoving temperature to rise too high in the twinkling of an eye and lead to the child base to be scalded the wrinkle and warp or even catch fire the damage.

The heat conducting oil chamber pipe 212 surrounds the heat conducting oil cavity 211 in a parallel and repeated winding manner, two ends of the heat conducting oil chamber pipe 212 are respectively provided with a heat conducting oil inlet 2121 and a heat conducting oil outlet 2122, the heat conducting oil inlet 2121 is positioned above the heat conducting oil cavity 211, and the outlet is positioned below the heat conducting oil cavity 211. It should be noted that the heat conducting oil inlet 2121 and the outlet of the heat conducting oil are not limited thereto, and may be left-in and right-out, right-in and left-out, or side-in and up-out, as long as they can be realized in the same winding manner, the present invention is within the protection scope.

Specifically, the winding direction of the heat-conducting oil bore tube 212 is perpendicular to the winding direction of the base on the surface of the shuttle-shaped dryer 210, so that efficient heat transfer can be realized by winding for multiple circles, the winding direction of the heat-conducting oil bore tube is perpendicular to the winding direction of the base, the heating temperature of the same transverse position of the base can be ensured to be consistent, the drying degree is consistent, synchronous and uniform drying of the base can be ensured, and the product stability is good.

The heat conducting oil accommodating cavity 211 is of a shuttle-shaped structure. The heat conducting oil chamber pipes 212 are uniformly wound on the surface of the heat conducting oil cavity 211, the shape of the heat conducting oil cavity 211 is consistent with that of the shuttle-shaped dryer 210, the heat conducting oil cavity is in a shuttle shape with thin ends and thick middle, and the structure can further ensure balanced heat transfer and good drying effect.

The size of the shuttle-shaped dryer 210 is 3 to 5m in height, 1.1 to 1.5m in width, and 0.2 to 0.6m in thickness. Specifically, the thickness here refers to the thickness of the position where the waist of the shuttle dryer 210 is fatest.

The tire base drying system 200 further comprises a closed box body covered on the outer side, so that the tire base is dried in a relatively closed space, the heat loss is small, the heat utilization rate is high, the drying effect can be effectively improved, and meanwhile, the energy can be saved.

The tire base drying system 200 further includes a first bouncing frame 250 disposed on the output side, so as to further prevent the waterproof roll from being stretched, and play a role in buffering. The first bouncing frame 250 includes a guide rail 421 and a bouncing roller 422 elastically and slidably coupled to the guide rail 421.

As shown in fig. 6 to 9, the asphalt pre-dipping system 300 includes a pre-dipping tank 310 for holding and/or receiving asphalt, and a pre-dipping pressing mechanism disposed above the pre-dipping tank 310, the pre-dipping pressing mechanism is configured to press a base pre-dipped with the asphalt in the pre-dipping tank 310, and includes at least two pre-dipping pressing rollers 320, rotation axes of the two adjacent pre-dipping pressing rollers 320 are parallel to each other but not in the same vertical plane, the base penetrates into a gap between the two adjacent pre-dipping rollers 320 from a lower side of the two adjacent pre-dipping rollers 320, and one of the pre-dipping rollers 320 is driven by a driving mechanism alone to draw the web. The utility model discloses set up the axis of rotation of adjacent twice preimpregnation squeeze roll 320 in the vertical plane of difference for the peak of preimpregnation squeeze roll 320 to the skew position of the extrusion line between the adjacent twice preimpregnation squeeze roll 320 of the child base formation extrusion that passes, preimpregnation squeeze roll 320 forms the contained angle between tangent plane and the horizontal plane of extrusion line department. The plane where the rotating shafts of the two adjacent pre-dipping extrusion rollers 320 are located is used as an interface, a groove with a bearing effect is formed between the two adjacent pre-dipping extrusion rollers 320 on the upper side of the interface (namely the upper sides of the two adjacent pre-dipping extrusion rollers 320), and extruded asphalt is received by the groove when flowing out from the upper side of the interface when extruding the tire base, so that the phenomenon of roller sticking caused by flowing along the roller surface is avoided. And the extruded asphalt will fall downward or flow downward along the roller surface when emerging from the lower side of the interface (i.e. the lower sides of two adjacent pre-dipping squeeze rollers 320), but because the pre-dipping squeeze rollers 320 will generally rotate along the material feeding direction of the tire base, the asphalt flowing through the roller surface will be continuously absorbed again by the tire base weight, and will not stay on the roller surface for too long, so that the problem of roller sticking can be solved to a great extent, thereby avoiding the defects of air bubbles, surface white spots, poor water impermeability, low peeling strength and the like of the finished product, and avoiding the tension to the tire base/coiled material caused thereby.

For higher viscosity asphalt, the extruded asphalt may stick to the prepreg press roll 320 without being reabsorbed as it emerges from the underside of the interface and runs down the roll surface. For this reason, the rotation axes of two adjacent prepreg press rollers 320 are not in the same horizontal plane, each two adjacent prepreg press rollers 320 include an upper roller 320a and a lower roller 320b in a positional relationship, and the tire base is fed from a side away from the upper roller 320a and penetrates into the gap between the upper roller 320a and the lower roller 320b from the lower side. Therefore, the lower roller 320b is wrapped on the feeding side of the tire base penetrating into the gap from the lower side, the asphalt flowing down falls on the tire base which is not extruded by the pre-dipping extrusion roller 320 and cannot be adhered to the pre-dipping extrusion roller 320, the adhesion of the asphalt to the roller is further prevented, especially when the viscosity of the asphalt is high, the extruded asphalt falls on the tire base which is not extruded by the pre-dipping extrusion roller 320 again, the adhesion of the roller can be effectively prevented, the surface unevenness caused by the asphalt falling on the tire base again can be avoided, the extrusion effect is better, the good operation of equipment can be better kept, the maintenance frequency of the equipment is reduced, the continuity of production is ensured, and the production efficiency is improved.

Preferably, the included angle between the plane where the rotating shafts of two adjacent prepreg squeezing rollers 320 are located and the vertical plane is 5-80 degrees; more preferably, the included angle between the plane where the rotating shafts of two adjacent prepreg press rolls 320 are located and the vertical plane is 10 ° to 60 °. The included angle between the plane where the rotating shafts of the two adjacent pre-dipping extrusion rollers 320 are located and the vertical plane is not small, otherwise, all the asphalt extruded and extruded from the upper side of the interface can not be accommodated in the groove with the bearing effect formed between the two adjacent pre-dipping extrusion rollers 320; the included angle is not too large, otherwise, even if the lower roller 320b is wrapped by the feeding side of the tire base penetrating into the gap from the lower side, the asphalt extruded and emerging from the lower side of the interface can directly fall onto other prepreg extrusion rollers 320 at lower positions; the size of the included angle is closely related to the viscosity, density, dip coating and extrusion amount of the asphalt, and the included angle needs to be adjusted according to specific conditions.

An extrusion action line for extruding the tire base is formed between two adjacent pre-dip extrusion rollers 320, and the distance between the extrusion action line and a vertical plane where the rotating shafts of the pre-dip extrusion rollers 320 are located is 50-150 mm.

As shown in fig. 8 to 9, the pre-dipping extrusion mechanism includes three pre-dipping extrusion rollers 320, which are a first roller 321, a second roller 322, and a third roller 323 from bottom to top, and the base is fed from a side away from the second roller 322, then passes through the gap between the first roller 321 and the second roller 322 from the lower side, and then passes through the gap between the second roller 322 and the third roller 323 from the lower side, so that the base performs two extrusion operations on the front and back sides of the web or pre-dipped web in the three pre-dipping extrusion rollers 320, respectively, so that the front and back sides of the web or pre-dipped web after extrusion are subjected to an average force, are not easy to warp, and have a smoother surface, wherein the first roller 321 and the third roller 323 are respectively driven by a driving mechanism to pull the web.

The pre-dipping pressing mechanism further comprises a pre-dipping frame 330, the first roller 321 and the third roller 323 are respectively connected to the bottom and the top of the inner side of the pre-dipping frame 330, and the second roller 322 is connected to the side wall of the inner side of the pre-dipping frame 330.

In one scheme, the first roller 321 and the third roller 323 are respectively connected to the bottom and the top of the inner side of the prepreg frame 330 in a lifting manner, and when the device is used, the heights of the first roller 321 and the third roller 323 can be respectively adjusted according to the performance requirement of a coil, so that the distance between the gaps for performing the extrusion function between the three prepreg extrusion rollers 320 can be adjusted, and the distance between any two adjacent prepreg extrusion rollers 320 can be optionally adjusted. More preferably, a driving mechanism for driving the first roller 321 to move up and down is disposed at the bottom of the prepreg frame 330, and a driving mechanism for driving the third roller 323 to move up and down is disposed at the top of the prepreg frame 330, so that the distance between the three gaps for pressing the prepreg pressing rollers 320 can be adjusted more accurately and conveniently.

Alternatively, the second roller 322 may be movably connected to a sidewall of the inside of the prepreg frame 330, and when in use, the second roller 322 may be horizontally displaced according to the performance requirement of the web material so as to adjust the distance between the gaps for squeezing the three prepreg squeezing rollers 320, and the positional relationship between the three prepreg squeezing rollers 320 may be adjusted at the same time by only adjusting the position of the second roller 322.

As shown in fig. 10, the post-presoak drying system 400 includes two drying rollers with heat, which are disposed at a distance and driven independently from each other. Drying system 400 constitutes at a distance from setting up after preimpregnation mainly by twice independent drive's drying roller, twice drying roller is driven by different actuating mechanism respectively, even if viscosity is big under the high temperature can not lead to waterproofing membrane by tensile deformation under the condition for improving greatly, such setting has avoided twice drying roller to constitute the effect of dragging to the waterproofing membrane that is located between the two on the one hand, on the other hand is equivalent to providing the tension buffer zone for the waterproofing membrane before drying and after drying in the stoving stage, thereby effectively prevent waterproofing membrane by constantly stretching and take place to warp in process of production. Furthermore, the utility model discloses abandoned traditional empty dry mode that separates, adopted the contact to dry, improved the effect of drying greatly. Each drying roller is driven by a variable frequency motor, so that tension is further prevented from being formed on the coiled material, and shrinkage deformation and influence on the synchronous rate of the production line caused by the tension are avoided.

The drying roller is a sandwich oil-passing roller, wherein heat conducting oil is passed through the sandwich oil-passing roller, and the temperature of the heat conducting oil is 190-220 ℃. The design of stoving roller is the sandwich structure of leading to oil to the mode that adopts the conduction oil heating provides the heat for the stoving roller, makes the temperature of stoving roller be unlikely to produce the snap, and the change volume also can not be too big, effectively avoids consequently and destroys waterproofing membrane, leads to catching fire even.

The roll wrapping rate of each drying roll is not lower than 75%, and a higher roll wrapping rate can provide more drying areas, improve the drying efficiency and the utilization rate of the drying rolls, reduce the span of equipment and further save space; more importantly, the higher roll wrapping rate is beneficial to maintaining the temperature balance of heat conducting oil in the drying roll, the phenomenon that the drying roll deforms due to expansion caused by heat and contraction caused by cold is avoided, and the service life of the equipment is prolonged.

The angle between the horizontal plane and the common plane where the rotating shaft of the first drying roller 411 and the rotating shaft of the second drying roller 412 are located is 60-80 degrees; the pre-impregnation post-drying system 400 is further provided with two drying guide rollers 413 which are arranged at intervals of the first drying roller 411 and the second drying roller 412 respectively, so that the roller wrapping rate of the drying rollers is not lower than 75%.

The drying system 400 after pre-soaking further comprises second bouncing frames 420 arranged on two sides, so that the waterproof roll is further prevented from being stretched, and a buffering effect is achieved. The second bounce frame 420 comprises a guide rail 421 and a bounce roller 422 elastically and slidably connected to the guide rail 421.

As shown in fig. 11 to 12, the asphalt coating system 500 includes a coating tank 510 for containing and/or receiving asphalt, and a double-straight-line extrusion mechanism disposed above the coating tank 510, the double-straight-line extrusion mechanism includes two pairs of coating squeeze rollers disposed in pairs at a distance and having heat, respectively a first upper squeeze roller 521 and a first lower squeeze roller 522 for rough pressing and a second upper squeeze roller 523 and a second lower squeeze roller 524 for fine pressing, and the rotation speed of the first upper squeeze roller 521 is greater than that of the second upper squeeze roller 523. The coating device adopts a double-straight-line extrusion forming mechanism, each coating extrusion roller has heat, the asphalt at the contact part is further softened during extrusion to enable the asphalt to extrude air more quickly and fill gaps, bubble generation is prevented, the coarse pressing of the waterproof coiled material is realized under the extrusion action of the first upper extrusion roller 521 and the first lower extrusion roller 522 with larger rotating speed, the fine pressing of the waterproof coiled material is realized under the extrusion action of the second upper extrusion roller 523 and the second lower extrusion roller 524 with relatively smaller rotating speed, and the tightness and the uniformity of the extrusion are improved by combining the two procedures of the coarse pressing and the fine pressing. In addition, at least the first upper squeeze roll 521 in the extrusion forming mechanism of two straight rows, the squeeze roll 523 is driven by different actuating mechanism respectively on the second, even if viscosity is for the circumstances that improves greatly under the high temperature also can not lead to waterproofing membrane by tensile deformation, such setting has avoided on the one hand that two pairs of extrusion rolls of coating cover constitute the effect of dragging to the waterproofing membrane that is located between the two, on the other hand is equivalent to providing the tension buffer zone for waterproofing membrane before the extrusion and after the extrusion in the extrusion stage, thereby effectively prevent waterproofing membrane by constantly stretching and take place to warp in process of production.

The rotating speed of the first upper squeeze roll 521 is higher than that of the first lower squeeze roll 522, the rotating speed of the second upper squeeze roll 523 is lower than that of the second lower squeeze roll 524, a speed difference is formed between the upper and lower coating squeeze rolls, so that the first upper squeeze roll 521 can form a leveling effect on the upper surface of the waterproof roll, the second upper squeeze roll 523 can form a compacting effect on the upper surface of the waterproof roll, the leveling effect and the compacting effect are achieved to a certain degree, the compacting effect and the leveling effect are achieved to a certain degree, and the tightness uniformity of the waterproof roll is further improved. The rotation speed of the first lower squeeze roller 522 is substantially identical to that of the second lower squeeze roller 524, so that the lower surface of the waterproof roll is continuously compacted. Each of the coating and extruding rollers is driven by four high-torque servo motors 233.

At the contact position of the coating extrusion roller and the waterproof roll, the linear velocity direction of the first upper extrusion roller 521 is the same as the moving direction of the waterproof roll, the linear velocity direction of the first lower extrusion roller 522 is opposite to the moving direction of the waterproof roll, the linear velocity direction of the second upper extrusion roller 523 is the same as the moving direction of the waterproof roll, and the linear velocity direction of the second lower extrusion roller 524 is opposite to the moving direction of the waterproof roll. In other words, the rotating directions of all the coating extrusion rollers are kept consistent, and the coating extrusion rollers form a friction force consistent with the trend of the waterproof coiled material at the contact part of the coating extrusion rollers and the waterproof coiled material, so as to push the waterproof coiled material to move forwards; the lower coating cover extrusion roller forms a friction force opposite to the direction of the waterproof coiled material at the contact part of the lower coating cover extrusion roller and the waterproof coiled material, and a certain scraping effect is formed while compaction is carried out.

The distance between the two pairs of coating extrusion rollers is not more than 60cm, and the distance is too large, so that the compaction is not favorably finished at proper temperature, the continuity of the rough pressing and the fine pressing is not favorably maintained, and the synergistic effect of the two is not favorably exerted.

Each coat and cover the squeeze roll and go up and down to be connected in the top of coating the pond 510 and thereby realize waterproofing membrane thickness control through ball screw drive mechanism respectively, ball screw drive mechanism has higher precision, is favorable to the accurate control of waterproofing membrane thickness.

The length of the coating extrusion roller is generally larger, the coating extrusion roller with certain length is easy to deform to a certain degree due to the action of gravity or pressure, and the waterproof roll has the defects of thick middle and thin two sides, therefore, the coating extrusion roller is preferably designed into a structure with the diameter of the middle part larger than the diameter of the two ends.

The coating extrusion roller is a sandwich oil passing roller, wherein heat conducting oil is passed through the roller, the temperature of the heat conducting oil is 220 ℃, and the temperature of the roller surface is 170-190 ℃. The design of scribbling the lid squeeze roll is the sandwich structure of leading to oil to the mode that adopts the conduction oil heating provides the heat for scribbling the lid squeeze roll, makes the temperature of scribbling the lid squeeze roll be unlikely to produce the snap, and the change volume also can not be too big, effectively avoids consequently and destroys waterproofing membrane, leads to catching fire even.

The coating device also comprises a dipping roller 531 which is arranged in the coating pool 510 or can be lifted into the coating pool 510, and the lower surface of the waterproof coiled material is coated with asphalt. The dipping roller 531 is positioned between the wall of the coating tank 510 and the double straight-row extrusion forming mechanism, and a coating guide roller 532 is also arranged between the dipping roller 531 and the wall of the coating tank 510 to prevent the waterproof coiled material from touching the wall of the coating tank 510 and even scraping the asphalt presoaked in the previous process.

The feeding side of the double straight-row extrusion forming mechanisms is also provided with a waterfall type discharging mechanism 533 which is used for uniformly spreading asphalt on the upper surface of the waterproof coiled material. The feeding side of each pair of coating extrusion rollers is provided with a waterfall type blanking mechanism 533, and asphalt is coated on the upper surface of the waterproof coiled material before extrusion, so that the waterproof coiled material is ensured to have enough thickness and tightness.

As shown in fig. 13, the film coating and/or sanding system 600 includes a sanding device movably disposed behind the sanding device, a film coating device 630, and a film coating traction device disposed in the output direction and driven by an independent driving mechanism, wherein the switching device 630 is used for switching between a sanding station and a film coating station. The utility model discloses sanding device and tectorial membrane device have been set up simultaneously, through setting up sanding station and tectorial membrane station are actually appeared to auto-change over device 630, and production facility around sanding or tectorial membrane can be shared to same system like this, and the resource rationalization utilizes, and the product production adaptability of equipment is good. When the film covering device is closer to a production device at a previous station, the temperature of the coiled material is reduced when the coiled material enters the film covering device, and the requirement for a product with relatively high film covering temperature can be met; on the contrary, when the film laminating device is farther away from the production device at the previous station, the temperature of the coiled material is reduced when the coiled material enters the film laminating device, and the requirement for products with relatively low film laminating temperature can be met.

Switching device 630 includes the hoisting device who sets up with the sanding device cooperation, works as hoisting device corresponds the tectorial membrane station when mentioning the sanding device, works as the hoisting device corresponds the sanding station when reducing the sanding device. Consider that sanding device's structure more distributes along vertical direction, and tectorial membrane device's structure more sets up along the horizontal direction, the utility model discloses a set up sanding device and tectorial membrane device around, utilize sanding device and tectorial membrane device's structural feature simultaneously, adopt hoisting device to realize sanding device and tectorial membrane device's switching, it is concrete, when needs use the tectorial membrane station, through hoisting device raises sanding device, and the coiled material just can directly get into the tectorial membrane device who is located the rear, when needs use sanding device, through hoisting device falls sanding device, and the coiled material directly gets into smoothly in the sanding device.

Tectorial membrane device includes cooling water bed 621, sets up in preceding tectorial membrane mechanism 622 of cooling water bed 621 below, sets up in cooling water bed 621 top and preceding tectorial membrane mechanism 623 after tectorial membrane mechanism 622, and the coiled material has flown cooling water bed 621 surface of water cooling after covering basement membrane and limit membrane by preceding tectorial membrane mechanism 622 to the coiled material lower surface, then is immersed cooling water bed 621 aquatic cooling after covering net cloth, facial mask and limit membrane by back tectorial membrane mechanism 623 to the coiled material upper surface.

Considering that the coiled material is inevitably subjected to the preceding processing and has a higher temperature, and the bottom film and the side film are also relatively thin and easily scalded, the front film covering mechanism 622 further comprises a pre-cooling device for pre-cooling the bottom film and the side film before covering. The precooling device is an atomization water spraying device which is used for carrying out atomization water spraying on one side of the basement membrane which is deviated from the contact with the coiled material. Adopt this kind of cooling structure can evenly dispel the heat, reasonable in design, it is effectual to cool down.

The sanding device comprises a sanding frame 611, a feeding rod 612, a front edge film coating mechanism 6131, a front sanding mechanism 6141, a rear edge film coating mechanism 6132 and a rear sanding mechanism 6142, wherein the feeding rod 612, the front edge film coating mechanism 6141, the rear edge film coating mechanism 6132 and the rear sanding mechanism 6142 are arranged on the sanding frame 611, the front edge film coating mechanism 6131 is used for coating a film and a side film on a surface film of a coiled material before sanding, the front sanding mechanism 6141 is used for sanding the surface film of the coiled material before the coiled material contacts with the feeding rod, the rear edge film coating mechanism 6132 is used for coating the side film on the bottom film of the coiled material before sanding, and the rear sanding mechanism 6142 is used for sanding the bottom surface of the coiled material.

To the limit membrane that sanding was handled places, there are two kinds according to the difference of construction method and standard, one is the single face and applies the limit membrane, one is two-sided application limit membrane, the utility model discloses preceding sanding mechanism 6141 has set up preceding membrane coating mechanism 6131 and back membrane coating mechanism 6132 respectively before the mechanism 6142 of back sanding, can lay the limit membrane according to actual conditions like this and handle to the coiled material, both can the single face apply the limit membrane and also can two-sided application limit membrane for equipment production adaptability is better.

The front side film coating mechanism 6131 is a structure which can be moved and detached. The utility model discloses set up this kind of structure and can be when the coiled material of production single face side coating membrane, will preceding membrane laminating mechanism 6131 removes to dismantle, and is convenient nimble.

The sanding device also comprises a front sand sweeping device 6151 and/or a rear sand sweeping device 6152, and a front sand returning box matched with the front sand sweeping device 6151 and/or a rear sand returning box matched with the rear sand sweeping device 6152 respectively; the front sand sweeping device 6151 is arranged behind a sand outlet of the front sand spreading mechanism 6141, and the rear sand sweeping device 6152 is arranged behind a sand outlet of the rear sand spreading mechanism 6142; the front sand return box and the rear sand return box are respectively arranged below the front sand sweeping device 6151 and the rear sand sweeping device 6152. Through setting up preceding sand sweeping device 6151 and back sand sweeping device 6152 respectively to and return sand box and back sand box before with preceding sand sweeping device 6151 and the matching of back sand sweeping device 6152, can control the homogeneity of spreading sand to facial mask and basement membrane and handle, avoid unnecessary gravel's arbitrary unrestrained simultaneously, realize the recycle of gravel, help the environment clean when resources are saved, guarantee clean production environment.

The output direction of tectorial membrane device still is equipped with the double-deck cooling water bed 621 that is used for further cooling to the coiled material, and the output direction of double-deck cooling water bed 621 still is equipped with the knurling device that is used for carrying out the knurling to the coiled material.

As shown in fig. 14, the roll material winding system 700 includes a roll material storage rack 710 for storing roll material, a winding device 720 located at the output direction of the roll material storage rack 710, and a brake motor 730 in control connection with the winding device 720, the roll material storage rack 710 includes a movable rack 711, a weight box 712, and a weight motor cooperating with the weight box 712, the weight box 712 cooperating with the weight motor can realize the floating of the movable rack 711, and the brake motor 730 is used for preventing the roll material from being further output from the storage rack when the winding speed of the roll material winding system 700 is too slow or the winding is suspended. Because the coiled material is stored frame 710 has and the space that floats, makes the storage length that the coiled material was stored frame 710 can freely be adjusted, and then makes tension between the coiled material on the coiled material is stored frame 710 is controlled, but just because the structure of this kind of mobile regulation has been adopted, also makes a small amount of unsteady can lead to a large amount of ejection of compact, the utility model discloses set up with coiling mechanism 720 control connection's brake motor 730, brake motor 730 control the output of coiled material is stored frame 710 guarantees follow-up coiling mechanism 720 at the uniform velocity rolling.

A third bouncing frame 740 is arranged between the coil storage frame 710 and the winding device 720, and the third bouncing frame 740 is used for adjusting the tension of the coil between the coil storage frame 710 and the winding device 720. For practical production, because the discharging speed and the winding speed of the production line are both very fast, even if the brake motor 730 which is in control connection with the winding device 720 is arranged, a certain length of coiled material is accumulated between the coiled material storage rack 710 and the winding device 720 due to sudden slow-down or pause of the winding device 720; in addition, because the slight floating of the coil storage rack 710 may also cause the coil output from the coil storage rack 710 to suddenly decrease greatly, the coil winding speed of the winding device 720 may be constant, which may also cause the coil between the coil storage rack 710 and the winding device 720 to be broken or deformed. The utility model discloses it can effectively adjust to set up third spring frame 740 here the coiled material stores the tension of coiled material between frame 710 and the coiling mechanism 720, also can buffer memory coiled material stores coiled material length between frame 710 and the coiling mechanism 720.

The third bouncing frame 740 is a dual-bar bouncing frame, and the storage length is 15-25 m. The two parallel double-bounce frames are arranged, so that tension adjustment and coiled material buffering can be better realized, and the storage length is 15-25 m most suitable according to actual conditions.

Be equipped with traction motor 750 between coiled material storage rack 710 and the third frame 740 that bounces, traction motor 750 does coiled material on the coiled material storage rack 710 provides output power, brake motor 730 and traction motor 750 control are connected. Therefore, the traction force of the coiled material on the waterproof coiled material winding system 700 can be balanced, and the phenomenon that the coiled material is pulled to deform or even be broken due to improper traction caused by large resistance of the coiled material storage rack 710 is avoided.

The winding device 720 further comprises a safety alarm device, the safety alarm device is connected with the brake motor 730, and the safety alarm device is used for sending out early warning information and controlling the brake motor 730 to work when the winding device 720 is paused or breaks down.

The winding speed of the winding device 720 is not lower than 130 m/min. The coil stock shelf 710 has a storage length of not less than 120 m. The coil stock shelf 710 has a length corresponding to the winding speed of the winding device 720.

The web winding system 700 further includes a fourth bouncing frame 760 disposed at the input direction of the web storage shelf 710, wherein the fourth bouncing frame 760 is used for adjusting the tension of the web before the web enters the web storage shelf 710. Because the utility model discloses in the coiled material that adopts store frame 710 for floating structure from top to bottom, its storage capacity change is big, this coiled material tension after also must influencing rather than the place ahead process output of being connected sets up fourth spring frame 760 and can effectively solve this problem.

It is obvious that the above embodiments of the present invention are only examples for clearly illustrating the present invention, and are not limitations to the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.

Claims (10)

1. The asphalt waterproof coiled material production line is characterized by at least comprising a tire base drying system, an asphalt pre-soaking system, a pre-soaking drying system, an asphalt coating system, a film covering and/or sanding system and a coiled material winding system which are sequentially arranged, wherein each system is respectively provided with an independent driving mechanism for drawing the tire base/coiled material.

2. The asphalt waterproofing membrane production line according to claim 1, wherein the tire base drying system, the asphalt pre-soaking system, the post-pre-soaking drying system, the asphalt coating system, the laminating and/or sanding system, and the coil winding system each have a pulling speed, and the pulling speeds of the tire base drying system, the asphalt pre-soaking system, the post-pre-soaking drying system, the laminating and/or sanding system, and the coil winding system are based on the pulling speed of the asphalt coating system.

3. The asphalt waterproofing membrane production line of claim 2, wherein the base drying system comprises a shuttle dryer arranged in parallel for heating and drying the base and a drying traction device arranged in the output direction of the shuttle dryer and driven by an independent driving mechanism, an upper guide roller and a lower guide roller are respectively arranged above and below the shuttle dryer, the base is wound to the upper guide roller from one side of the shuttle dryer through the lower guide roller and then wound to the lower guide roller from the other side of the shuttle dryer, and ejector rods are arranged on two sides of the shuttle dryer and used for laterally supporting the base to keep a gap between the base and the surface of the shuttle dryer.

4. The asphalt waterproof coiled material production line according to claim 2, wherein the asphalt pre-dipping system comprises a pre-dipping tank for containing and/or receiving asphalt and a pre-dipping extrusion mechanism arranged above the pre-dipping tank, the pre-dipping extrusion mechanism is used for extruding a base pre-dipped with the asphalt in the pre-dipping tank, the asphalt waterproof coiled material production line comprises at least two pre-dipping extrusion rollers, rotating shafts of the two adjacent pre-dipping extrusion rollers are parallel to each other but not in the same vertical plane, the base penetrates into a gap between the two adjacent pre-dipping extrusion rollers from the lower sides of the two adjacent pre-dipping extrusion rollers, and one of the pre-dipping extrusion rollers is driven by a driving mechanism to form traction on the coiled material.

5. The asphalt waterproofing membrane production line of claim 4, characterized in that the axis of rotation of two adjacent prepreg squeeze rollers is also not in the same horizontal plane, each two adjacent prepreg squeeze rollers include an upper roller and a lower roller when viewed from the position relation, and the base is fed from the side far away from the upper roller and penetrates into the gap between the upper roller and the lower roller from the lower side.

6. The asphalt waterproofing membrane production line of claim 2, wherein the post-presoaking drying system comprises two drying rollers with heat arranged at a distance and driven independently.

7. The asphalt waterproofing membrane production line of claim 2, wherein the asphalt coating system comprises a coating tank for containing and/or receiving asphalt and a double straight row extrusion mechanism arranged above the coating tank, the double straight row extrusion mechanism comprises two pairs of coating extrusion rollers which are arranged at a distance and have heat, a first upper extrusion roller and a first lower extrusion roller for rough pressing and a second upper extrusion roller and a second lower extrusion roller for fine pressing respectively, and the rotation speed of the first upper extrusion roller is greater than that of the second upper extrusion roller.

8. The asphalt waterproofing membrane production line according to claim 7, wherein the rotation speed of the first upper squeeze roller is greater than the rotation speed of the first lower squeeze roller, the rotation speed of the second upper squeeze roller is less than the rotation speed of the second lower squeeze roller, and the rotation speed of the first lower squeeze roller is equal to the rotation speed of the second lower squeeze roller; at squeeze roll and waterproofing membrane contact department, the linear velocity direction of squeeze roll is the same with waterproofing membrane's moving direction on the first, the linear velocity direction of squeeze roll is opposite with waterproofing membrane's moving direction on the first, the linear velocity direction of squeeze roll is the same with waterproofing membrane's moving direction on the second, the linear velocity direction of squeeze roll is opposite with waterproofing membrane's moving direction under the second.

9. The asphalt waterproofing membrane production line of claim 2, characterized in that the tectorial membrane and/or sanding system includes sanding device, tectorial membrane device and auto-change over device, the tectorial membrane device removes and sets up in sanding device rear, auto-change over device is used for realizing the switching of sanding station and tectorial membrane station.

10. The asphalt waterproofing membrane production line of claim 9, characterized in that the tectorial membrane device includes the cooling water bed, set up preceding tectorial membrane mechanism in the cooling water bed below, set up in the cooling water bed and the back tectorial membrane mechanism behind the preceding tectorial membrane mechanism, preceding tectorial membrane mechanism is used for covering basement membrane and limit membrane to the coiled material lower surface, back tectorial membrane mechanism is used for covering net cloth, facial mask and limit membrane to the coiled material upper surface.

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