Intelligent six die spinning melt medical and health production system
The intelligent six-head spunbond and meltblown web-forming device and electromagnetic slide rail traction device, through the equidistant setting of spunbond and meltblown web-forming devices, has solved the problem of nonwoven fabric position adjustment, realized the production of multi-style and multi-layer nonwoven fabrics, and improved the flexibility and stability of the production system.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- DONGYING SHENZHOU BUILDING MATERIALS CO LTD
- Filing Date
- 2023-06-09
- Publication Date
- 2026-06-26
AI Technical Summary
In existing spunbond nonwoven fabric production systems, the positional relationship between the formed nonwoven fabrics is difficult to adjust flexibly, affecting production flexibility and applicability.
The intelligent six-head spunbond-meltblown medical and health production system includes three spunbond production lines and three meltblown production lines. By setting spunbond web forming devices and meltblown web forming devices at equal intervals, and installing a controllable electromagnetic slide rail traction device on the right side of the spunbond web forming device, along with auxiliary suction, limiting rollers and stop devices, flexible overlapping and adjustment of spunbond nonwoven fabric and meltblown nonwoven fabric can be achieved.
It improves the flexibility and applicability of the production system, reduces equipment size, ensures the stability of the production process and the drape stability of spunbond nonwoven fabrics, and enhances the diversity of production styles for multilayer nonwoven fabric products.
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Figure CN116853888B_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of spunbond nonwoven fabric production, and in particular to an intelligent six-head spunbond medical and health production system. Background Technology
[0002] Spunbond nonwoven fabric is a type of fabric formed without spinning or weaving. It is made by arranging short textile fibers or filaments in a directional or random manner to form a web structure, and then reinforcing it using mechanical, thermal bonding, or chemical methods. The resulting fiber product has properties such as softness, breathability, and stable planar structure. Spunbond nonwoven fabric has important applications in the medical and health industry.
[0003] The production of spunbond and meltblown nonwoven fabrics integrates spunbond and meltblown technologies. Multiple spunbond and meltblown production lines operate simultaneously for composite production. Different dies are used to produce different spunbond and meltblown nonwoven fabrics. In actual operation, the positions of the dies (diffusers) are fixed and constrained by the overall size and structural features of the equipment. This makes it difficult to adjust the positions of the dies (diffusers). When production improvements are needed, the positional relationship of the nonwoven fabric layers formed at each die (diffuser) cannot be flexibly adjusted according to actual needs. As a result, the nonwoven fabrics can only be installed in pre-set positions for overlapping and pressing, affecting the flexibility of the actual production process.
[0004] Therefore, an intelligent six-head spinning and melting medical and health production system is proposed to solve some of the problems existing in the above-mentioned existing technologies. Summary of the Invention
[0005] The purpose of this application is to solve the problem in existing multi-head spunbond meltblown production systems where the positional relationship between the formed nonwoven fabrics is difficult to adjust flexibly, affecting production flexibility. Compared with existing technologies, this application provides an intelligent six-head spunbond meltblown medical and health production system, including three spunbond production lines and three meltblown production lines. The end of each spunbond production line is connected to a spunbond diffuser, and the end of each meltblown production line is connected to a meltblown die. A web-forming device is installed below both the spunbond diffuser and the meltblown die. The web-forming device is divided into a spunbond web-forming device corresponding to the spunbond diffuser and a web-forming device corresponding to the meltblown die. The meltblown web forming device has three spunbond diffusers corresponding to three spunbond web forming devices, and three meltblown dies corresponding to one meltblown web forming device. The three spunbond diffusers and their corresponding spunbond web forming devices are equidistant from top to bottom. The three meltblown dies and their corresponding meltblown web forming devices are located at the lower right side of the spunbond web forming device. Each spunbond web forming device has an electromagnetic slide rail that extends laterally to the top of the meltblown web forming device. A traction device corresponding to the spunbond web forming device is fixedly installed on the sliding end of the electromagnetic slide rail. A hot rolling mill is installed on the right side of the meltblown web forming device.
[0006] By equidistantly arranging multiple spunbond web forming devices from top to bottom, and placing the meltblown web forming device to the lower right of the multiple spunbond web forming devices, and installing a traction device on the right side of each spunbond web forming device that can be controlled by an electromagnetic slide rail, the spunbond nonwoven fabric formed on the multiple spunbond web forming devices can be flexibly adjusted to fall onto the meltblown web forming device under the traction of the traction device. This allows for adjustment of the overlapping pattern of the spunbond nonwoven fabric and the meltblown nonwoven fabric, facilitating the production of more diverse multilayer nonwoven fabric products.
[0007] Furthermore, the spunbond production line includes a feeder, extruder, filter, metering pump, spinning box, pressure stabilizing box and stretcher connected in sequence to the front end of the spunbond diffuser, and the meltblown production line includes a feeder, extruder, filter and metering pump connected in sequence to the front end of the meltblown die.
[0008] Furthermore, the web forming device includes an outer frame arranged symmetrically at the front and back. Multiple longitudinally arranged conveying rollers a are rotatably connected to the inner sides of the left and right ends of the outer frame. A web forming curtain is driven sleeved on the outer side of the multiple conveying rollers a. The spunbond diffuser and meltblown die head are located above the upper surface of the web forming curtain. A main suction device located directly below the spunbond diffuser and meltblown die head is installed on the inner side of the web forming curtain.
[0009] Furthermore, the three spunbond diffusers are staggered in the left and right directions, with the uppermost spunbond diffuser located on the far right and the lowermost spunbond diffuser located on the far left.
[0010] Furthermore, three meltblown die heads are installed sequentially from left to right above the meltblown web forming device. Four auxiliary suction devices b located inside the web forming curtain are fixedly installed on the outer frame inside the meltblown web forming device. The four auxiliary suction devices b are staggered with the three meltblown die heads.
[0011] Furthermore, a limiting roller located on the upper surface of the forming curtain is rotatably mounted on the outer frame inside the meltblown forming device, and the limiting roller is positioned above the auxiliary suction device b on the right side.
[0012] Optionally, a transition device is installed on the upper right side of the spunbond web forming device, and the transition device extends to the right above the traction device.
[0013] Furthermore, a vertically installed stop device is mounted on the right side of the traction device.
[0014] Furthermore, the traction device, transition device, and stop device all include support plates symmetrically arranged front and rear, and three longitudinally arranged conveyor rollers b are rotatably connected inside the support plates. The three conveyor rollers b are arranged in a triangular structure, and a mesh conveyor belt is driven sleeved on the outer side of the three conveyor rollers b. An auxiliary suction device a is fixedly installed inside the support plate, located inside the mesh conveyor belt. The two upper conveyor rollers b in the traction device are on the same horizontal plane, the two lower conveyor rollers b in the transition device are on the same horizontal plane, and the two left conveyor rollers b in the stop device are on the same vertical plane.
[0015] Furthermore, there are two sliding ends inside the electromagnetic slide rail, which are symmetrically arranged on the left and right sides. The traction device is fixedly installed on the sliding end on the left side inside the electromagnetic slide rail, and the stop device is fixedly installed on the sliding end on the right side inside the electromagnetic slide rail.
[0016] Compared to existing technologies, the advantages of this application are:
[0017] (1) This application arranges multiple spunbond web forming devices at equal intervals from top to bottom, and places the meltblown web forming device at the lower right of the multiple spunbond web forming devices. With a traction device that can be controlled by an electromagnetic slide rail installed on the right side of each spunbond web forming device, the spunbond nonwoven fabric formed on the multiple spunbond web forming devices can be flexibly adjusted to fall onto the meltblown web forming device under the traction of the traction device. This allows for adjustment of the overlapping pattern of spunbond nonwoven fabric and meltblown nonwoven fabric, which is convenient for producing more styles of multilayer nonwoven fabric products. It also helps to improve the flexibility of the production system during operation and its wide applicability.
[0018] (2) By staggering the three spunbond diffusers from left to right, the left ends of the three spunbond web forming devices are shortened to the right in sequence. This avoids the influence of the larger stretcher on the multiple spunbond web forming devices that are equidistant from top to bottom. This helps to ensure the structural compactness between the three spunbond web forming devices, and helps to reduce the size of the equipment and reduce its space occupation.
[0019] (3) By installing four auxiliary suction devices b in the forming curtain of the meltblown forming device and setting the four auxiliary suction devices b and the three meltblown die heads in an alternating manner, the four auxiliary suction devices b are located at the drop point of the spunbond nonwoven fabric. The auxiliary suction devices b can be used to attract the spunbond nonwoven fabric hanging above, ensuring stable contact between the spunbond nonwoven fabric and the upper surface of the forming curtain.
[0020] (4) By setting the limiting roller on the upper right side of the auxiliary suction device b, the spunbond nonwoven fabric that is hanging down can be restricted by the limiting roller, so as to prevent it from being pulled up because the feeding speed is less than the rotation speed of the web forming curtain on the meltblown web forming device, thus further ensuring the stability of the production system during operation.
[0021] (5) By installing the transition device on the upper right of the spunbond web forming device and making the transition device connected above the gap between the spunbond web forming device and the traction device, the spunbond nonwoven fabric can be guided when it is transferred from the spunbond web forming device to the traction device, so as to ensure that the spunbond nonwoven fabric is transferred to the traction device more stably.
[0022] (6) By setting a stop device and using it in conjunction with the traction device, the falling direction of the spunbond nonwoven fabric is stopped and restricted, which helps to ensure the stability of the spunbond nonwoven fabric falling onto the meltblown web forming device.
[0023] (7) By installing the stop devices on the sliding end of the electromagnetic rail, the position of each stop device can be flexibly adapted and adjusted according to the position relationship of multiple traction devices, which improves the flexibility of the stop devices during use to a certain extent. Attached Figure Description
[0024] Figure 1 This is a front sectional view of this application;
[0025] Figure 2 This is a perspective view of the SMMMSS production mode of this application;
[0026] Figure 3 for Figure 2 Front sectional view of the structure;
[0027] Figure 4 This is a perspective view of the SMMSMS production mode in this application;
[0028] Figure 5 for Figure 4 Front sectional view of the structure;
[0029] Figure 6 This is a schematic diagram of the internal structure of the meltblown web forming device of this application;
[0030] Figure 7 This is a schematic diagram of the structure of a spunmelt production system in the prior art;
[0031] Figure 8 This is a schematic diagram of the structure of a spunbond production line in the existing technology;
[0032] Figure 9 This is a schematic diagram of the structure of a meltblown production line in the prior art;
[0033] Figure 10 This is a schematic diagram of the web-forming device structure in existing spunbond and meltblown production lines.
[0034] Explanation of the labels in the diagram:
[0035] 1. Spunbond diffuser; 2. Meltblown die head; 3. Outer frame; 301. Conveyor roller a; 302. Mesh forming curtain; 303. Main suction device; 4. Electromagnetic slide rail; 5. Traction device; 6. Transition device; 7. Stop device; 8. Support plate; 801. Conveyor roller b; 802. Mesh conveyor belt; 803. Auxiliary suction device a; 9. Auxiliary suction device b; 901. Restriction roller. Detailed Implementation
[0036] The embodiments will be described clearly and completely with reference to the accompanying drawings. All other embodiments obtained by those skilled in the art based on the embodiments in this application without creative effort are within the scope of protection of this application.
[0037] Example 1:
[0038] This invention provides an intelligent six-head spinning and melting medical and health production system. Please refer to [link / reference]. Figure 1 - Figure 10 The system includes three spunbond production lines and three meltblown production lines. Each spunbond production line is connected to a spunbond diffuser 1 at its end, and each meltblown production line is connected to a meltblown die 2 at its end. A web-forming device is installed below both the spunbond diffuser 1 and the meltblown die 2. The web-forming devices are divided into spunbond web-forming devices corresponding to the spunbond diffuser 1 and meltblown web-forming devices corresponding to the meltblown die 2. Each of the three spunbond diffusers 1 corresponds to one spunbond web-forming device, and each of the three meltblown dies 2 corresponds to one meltblown web-forming device. The three spunbond diffusers 1 and their corresponding spunbond web-forming devices are equidistant from top to bottom. The three meltblown dies 2 and their corresponding meltblown web-forming devices are located on the lower right side of the spunbond web-forming device. Each spunbond web-forming device has an electromagnetic slide rail 4 extending laterally to the top of the meltblown web-forming device on its right side. A traction device 5 corresponding to the spunbond web-forming device is fixedly installed on the sliding end of the electromagnetic slide rail 4. A hot rolling mill is installed on the right side of the meltblown web-forming device.
[0039] During the operation of this intelligent six-die spunbond medical and health production system, the yarns processed by the three spunbond production lines are led out by the spunbond diffuser 1 and formed into spunbond nonwoven fabric on the spunbond web forming device. The yarns processed by the three meltblown production lines are led out by the meltblown die head 2 and formed into meltblown nonwoven fabric on the meltblown web forming device. The spunbond nonwoven fabric is guided by the traction device 5 and falls downward onto the meltblown web forming device, where it overlaps with the meltblown nonwoven fabric formed on the meltblown web forming device to form a multi-layer nonwoven fabric structure. The formed multi-layer nonwoven fabric is then pulled into the hot rolling mill for hot pressing and reinforcement. During this process, the position of the traction device 5 installed on its sliding end can be adjusted laterally by the electromagnetic slide rail 4 to adjust the position of the spunbond nonwoven fabric falling onto the meltblown web forming device.
[0040] Using "S" to mark spunbond nonwoven fabric and "M" to mark meltblown nonwoven fabric, the number of spunbond and meltblown production lines that can be started can be flexibly controlled during actual operation. The positions of the three traction devices 5 can be adjusted synchronously, allowing the spunbond nonwoven fabric produced by the three spunbond production lines to be flexibly combined with the meltblown nonwoven fabric produced by the three meltblown production lines to form product production modes such as "SMS", "SMMS", "SMMSS", "SMMMSS", and "SMMSMS". In this application, multiple spunbond web forming devices are arranged from top to bottom... The meltblown nonwoven fabric is equidistantly positioned below and to the right of multiple spunbond nonwoven fabric units. A traction device 5, controllable by an electromagnetic rail 4, is installed on the right side of each spunbond nonwoven fabric unit. This allows the spunbond nonwoven fabric formed on the multiple spunbond nonwoven fabric units to be flexibly adjusted in position to fall onto the meltblown nonwoven fabric unit under the traction of the traction device 5. This enables adjustments to the overlapping pattern of the spunbond and meltblown nonwoven fabrics, facilitating the production of more diverse multilayer nonwoven fabric products. This enhances the flexibility and applicability of the production system during operation.
[0041] Please see Figure 7 - Figure 9 The spunbond production line includes a feeder, extruder, filter, metering pump, spinning box, pressure stabilizing box, and drafter connected sequentially to the front end of the spunbond diffuser 1. The meltblown production line includes a feeder, extruder, filter, and metering pump connected sequentially to the front end of the meltblown die 2. During the operation of this intelligent six-die spunbond-meltblown medical and health production system, the raw materials used to produce spunbond nonwoven fabric and meltblown nonwoven fabric are fed into the extruder through the feeder in each production line. They are heated and melted in the extruder, and then enter the metering pump after passing through the filter. The raw materials used to produce spunbond nonwoven fabric enter the spinning box to form numerous fine filaments. These filaments are cooled by cold air after entering the pressure stabilizing box, and then formed into spunbond nonwoven fabric on the spunbond web forming device under the traction of the drafter. The raw materials used to produce meltblown nonwoven fabric directly enter the meltblown die 2, and are ejected into even finer filaments, which are directly formed into meltblown nonwoven fabric on the meltblown web forming device.
[0042] Please see Figure 3 , Figure 5 and Figure 6The web-forming device includes an outer frame 3 symmetrically arranged front and rear. Multiple longitudinally arranged conveyor rollers a301 are rotatably connected to the inner sides of the left and right ends of the outer frame 3. A web-forming curtain 302 is driven and sleeved on the outer sides of the multiple conveyor rollers a301. A spunbond diffuser 1 and a meltblown die 2 are located above the upper surface of the web-forming curtain 302. A main suction device 303 is installed on the inner side of the web-forming curtain 302, located directly below the spunbond diffuser 1 and the meltblown die 2. During the operation of this intelligent six-die spunbond medical and health production system, the conveyor rollers... A drive unit is connected to a301 to control its rotation and drive the forming curtain 302 to rotate, thereby conveying the formed spunbond nonwoven fabric and meltblown nonwoven fabric. When the yarn falls from the spunbond diffuser 1 and the meltblown die head 2 onto the forming device, it is actually laid flat on the top of the forming curtain 302. During this process, the forming curtain 302 installed at the corresponding position on the inner side of the forming curtain 302 will suck up the yarn to ensure that the yarn can be laid flat and stable on the top of the forming curtain 302, thereby realizing the forming operation of nonwoven fabric.
[0043] Please see Figure 1 The three spunbond diffusers 1 are staggered in the left and right directions, with the uppermost spunbond diffuser 1 located on the far right and the lowermost spunbond diffuser 1 located on the far left. During the operation of this intelligent six-head spunbond medical and health production system, since the spunbond diffuser 1 is connected to a relatively tall drafting device, in order to avoid the multiple spunbond web forming devices that are equidistant from top to bottom being affected by the drafting device, the three spunbond diffusers 1 are staggered from left to right, so that the left ends of the three spunbond web forming devices are successively shortened to the right. This helps to ensure the structural compactness between the three spunbond web forming devices, and helps to reduce the size of the equipment and reduce its space occupation.
[0044] Please see Figure 6 Three meltblown die heads 2 are installed sequentially from left to right above the meltblown web forming device. Four auxiliary suction devices b9 located inside the web forming curtain 302 are fixedly installed on the outer frame 3 inside the meltblown web forming device. The four auxiliary suction devices b9 are staggered with the three meltblown die heads 2. During the operation of this intelligent six-die-head spunbond medical and health production system, by installing the four auxiliary suction devices b9 in the web forming curtain 302 inside the meltblown web forming device and staggering the four auxiliary suction devices b9 with the three meltblown die heads 2, the four auxiliary suction devices b9 are located at the drop point of the spunbond nonwoven fabric. The auxiliary suction devices b9 can be used to attract the spunbond nonwoven fabric hanging from above, ensuring stable contact between the spunbond nonwoven fabric and the upper surface of the web forming curtain 302, and improving the stability of the spunbond nonwoven fabric hanging onto the meltblown web forming device to a certain extent.
[0045] Please see Figure 6A limiting roller 901 is rotatably mounted on the outer frame 3 inside the meltblown web forming device, located on the upper surface of the web forming curtain 302. The limiting roller 901 is positioned above the auxiliary suction device b9 on the right side. During the operation of this intelligent six-head spunbond nonwoven production system, by positioning the limiting roller 901 above the auxiliary suction device b9 on the right side, the limiting roller 901 can be used to restrict the drooping spunbond nonwoven fabric, preventing it from being pulled up due to the feed speed being less than the rotation speed of the web forming curtain 302 on the meltblown web forming device, thus further ensuring the stability of the production system during operation.
[0046] Example 2:
[0047] This invention provides an intelligent six-head spinning and melting medical and health production system. Please refer to [link / reference]. Figure 1 - Figure 10 A transition device 6 is installed on the upper right side of the spunbond web forming device, and the transition device 6 extends to the right above the traction device 5. During the operation of this intelligent six-die spunbond medical and health production system, by installing the transition device 6 on the upper right side of the spunbond web forming device and making the transition device 6 transitionally connected above the gap between the spunbond web forming device and the traction device 5, the spunbond nonwoven fabric can be guided when it is transferred from the spunbond web forming device to the traction device 5, ensuring that the spunbond nonwoven fabric is transferred to the traction device 5 more stably, thereby effectively ensuring the stability of the production system during operation.
[0048] Please see Figure 1 A vertically installed stop device 7 is installed on the right side of the traction device 5. During the operation of this intelligent six-head spunbond nonwoven medical and health production system, the stop device 7 is used in conjunction with the traction device 5 to stop and restrict the falling direction of the spunbond nonwoven fabric, which helps to ensure the stability of the spunbond nonwoven fabric falling onto the meltblown web forming device.
[0049] Please see Figure 3 and Figure 5 The traction device 5, transition device 6, and stop device 7 all include support plates 8 symmetrically arranged front and rear. Three longitudinally arranged conveyor rollers b801 are rotatably connected inside the support plates 8. The three conveyor rollers b801 are arranged in a triangular structure. A mesh conveyor belt 802 is driven sleeved on the outer side of the three conveyor rollers b801. An auxiliary suction device a803 located inside the mesh conveyor belt 802 is fixedly installed inside the support plates 8. The two upper conveyor rollers b801 in the traction device 5 are on the same horizontal plane. The two lower conveyor rollers b801 in the transition device 6 are on the same horizontal plane. The two left conveyor rollers b801 in the stop device 7 are on the same vertical plane.
[0050] During operation, the intelligent six-head spunbond nonwoven medical and health production system has a drive unit connected to the conveyor roller b801, which controls its rotation to drive the mesh conveyor belt 802 to rotate, thereby conveying the spunbond nonwoven fabric. In actual use, by installing the auxiliary suction device a803 on the inner side of the mesh conveyor belt 802, it can perform a suction effect on the spunbond nonwoven fabric that is in close contact with the mesh conveyor belt 802, so that the spunbond nonwoven fabric maintains a more stable state during transportation, transfer, traction and restraint, further ensuring the stability of the production system during operation.
[0051] Please see Figure 2 and Figure 4 There are two sliding ends in the electromagnetic slide rail 4, which are symmetrically arranged on the left and right. The traction device 5 is fixedly installed on the left sliding end in the electromagnetic slide rail 4, and the stop device 7 is fixedly installed on the right sliding end in the electromagnetic slide rail 4. During the operation of this intelligent six-die spinning and melting medical and health production system, by also installing the stop device 7 on the sliding end of the electromagnetic slide rail 4, the position of each stop device 7 can be flexibly adapted and adjusted according to the position relationship of multiple traction devices 5, which improves the flexibility of the stop device 7 in use to a certain extent.
[0052] This embodiment 2 references embodiment 1, and the differences are formed based on embodiment 1. Only the differences are explained here.
[0053] The above are merely the best implementation methods adopted in this application in light of current practical needs, but the scope of protection of this application is not limited thereto.
Claims
1. An intelligent six-die spunbond-meltblown medical and health production system, comprising three spunbond production lines and three meltblown production lines, wherein the end of each spunbond production line is connected to a spunbond diffuser (1), and the end of each meltblown production line is connected to a meltblown die (2), characterized in that, Below the spunbond diffuser (1) and meltblown die (2), a web-forming device is provided. The web-forming device is divided into a spunbond web-forming device corresponding to the spunbond diffuser (1) and a meltblown web-forming device corresponding to the meltblown die (2). The three spunbond diffusers (1) correspond to three spunbond web-forming devices respectively, and the three meltblown dies (2) correspond to one meltblown web-forming device. The three spunbond diffusers (1) and their corresponding spunbond web-forming devices are equidistant from top to bottom. The three meltblown dies (2) and their corresponding meltblown web-forming devices are located at the lower right side of the spunbond web-forming device. Each spunbond web-forming device has an electromagnetic slide rail (4) extending laterally to the top of the meltblown web-forming device installed on its right side. A traction device (5) corresponding to the spunbond web-forming device is fixedly installed on the sliding end of the electromagnetic slide rail (4). A hot rolling mill is installed on the right side of the meltblown web-forming device. The spunbond production line includes a spunbond diffuser (1) and a meltblown die (2) connected in sequence to the spunbond diffuser (1). The meltblown production line includes a feeder, extruder, filter, metering pump, spinning box, pressure stabilizing box and drawer at the front end of the device (1). The meltblown production line includes a feeder, extruder, filter and metering pump connected in sequence to the front end of the meltblown die (2). The web forming device includes an outer frame (3) symmetrically arranged at the front and back. Multiple longitudinally arranged conveying rollers a (301) are rotatably connected to the inner sides of the left and right ends of the outer frame (3). Web forming curtains (302) are driven sleeved on the outer sides of the multiple conveying rollers a (301). The spunbond diffuser (1) and the meltblown die (2) are located above the upper surface of the web forming curtain (302). The main suction device (303) located directly below the spunbond diffuser (1) and the meltblown die (2) is installed on the inner side of the web forming curtain (302). The three spunbond diffusers (1) are staggered in the left and right directions. The uppermost spunbond diffuser (1) is located on the rightmost side and the lowermost spunbond diffuser (1) is located on the leftmost side.
2. The intelligent six-head spinning and melting medical and health production system according to claim 1, characterized in that, The three meltblown die heads (2) are installed in sequence from left to right above the meltblown web forming device. Four auxiliary suction devices b (9) located inside the web forming curtain (302) are fixedly installed on the outer frame (3) inside the meltblown web forming device. The four auxiliary suction devices b (9) are staggered with the three meltblown die heads (2).
3. The intelligent six-head spinning and melting medical and health production system according to claim 1, characterized in that, The outer frame (3) inside the meltblown web forming device is rotatably mounted with a limiting roller (901) located on the upper surface of the web forming curtain (302), and the limiting roller (901) is located on the upper right side of the auxiliary suction device b (9).
4. The intelligent six-head spinning and melting medical and health production system according to claim 1, characterized in that, A transition device (6) is installed on the upper right side of the spunbond web forming device, and the transition device (6) extends to the right above the traction device (5).
5. The intelligent six-head spinning and melting medical and health production system according to claim 1, characterized in that, A vertically installed stop device (7) is installed on the right side of the traction device (5).
6. The intelligent six-head spinning and melting medical and health production system according to claim 5, characterized in that, The traction device (5), transition device (6) and stop device (7) all include a support plate (8) symmetrically arranged front and rear, and three longitudinally arranged conveyor rollers b (801) are rotatably connected inside the support plate (8). The three conveyor rollers b (801) are arranged in a triangular structure. A mesh conveyor belt (802) is driven sleeved on the outer side of the three conveyor rollers b (801). An auxiliary suction device a (803) located inside the mesh conveyor belt (802) is fixedly installed inside the support plate (8). The two upper conveyor rollers b (801) in the traction device (5) are on the same horizontal plane. The two lower conveyor rollers b (801) in the transition device (6) are on the same horizontal plane. The two left conveyor rollers b (801) in the stop device (7) are on the same vertical plane.
7. The intelligent six-head spinning and melting medical and health production system according to claim 6, characterized in that, There are two sliding ends in the electromagnetic slide rail (4), and the two sliding ends are arranged symmetrically on the left and right. The traction device (5) is fixedly installed on the sliding end on the left side of the electromagnetic slide rail (4), and the stop device (7) is fixedly installed on the sliding end on the right side of the electromagnetic slide rail (4).