A fixed base for textile equipment
By integrating positioning, buffering, and leveling mechanisms into the base of the textile equipment, the vibration problem of high-speed rotating textile equipment has been solved, achieving full-frequency vibration suppression and equipment stability, thereby improving the service life and processing quality of the equipment.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- FUJIAN CHARME TEXTILE
- Filing Date
- 2026-01-14
- Publication Date
- 2026-06-09
Smart Images

Figure CN121497773B_ABST
Abstract
Description
Technical Field
[0001] This invention belongs to the field of equipment bases, and specifically relates to a fixed base for textile equipment. Background Technology
[0002] Textile equipment is a general term for various mechanical equipment used to process natural or chemical fibers into textiles. It is the production means and material basis of the textile industry, and its technical level directly affects the development of the textile industry.
[0003] High-speed air-jet looms, high-yield carding machines, and rapier looms have become the mainstream equipment in textile workshops due to their high operating speed and large power load. The core working components of such equipment include main shaft bearings, cam transmission mechanisms, and weft yarn detectors. These components need to maintain high-precision matching during equipment operation, and their working stability directly determines the forming quality and production efficiency of the fabric.
[0004] During operation, existing high-speed air-jet looms generate high-frequency vibrations due to the spindle speed reaching 1000-1800 r / min. This high-frequency vibration can cause the jet airflow to deviate, leading to fabric defects such as weft breakage, weft shrinkage, and uneven density. Furthermore, the long-term vibration can exacerbate the wear of internal components, reducing the equipment's lifespan.
[0005] The existing equipment base lacks a targeted buffer and vibration reduction structure, which makes the equipment prone to horizontal displacement due to long-term vibration, further amplifying processing errors;
[0006] This application proposes a fixing base for textile equipment to improve upon the aforementioned defects. Summary of the Invention
[0007] The technical problem to be solved by the present invention is to overcome the shortcomings of the prior art and provide a fixed base for textile equipment that has the function of vibration reduction for textile equipment.
[0008] To solve the above-mentioned technical problems, the present invention adopts the following technical solution:
[0009] A fixed base for textile equipment includes a base, a buffer base plate, a positioning mechanism, support legs, and a buffer mechanism. The bottom of the base has a plurality of support legs arranged in an array. The base has a built-in buffer mechanism. The top of the buffer mechanism is connected to the buffer base plate. The top of the buffer base plate is equipped with the positioning mechanism. The top of the positioning mechanism is connected and installed to the bottom of the textile equipment.
[0010] In one specific implementation scheme, the positioning mechanism includes a guide rail, a slider, a mounting plate, and a telescopic cylinder. Two sets of guide rails are symmetrically arranged and mounted on a buffer base plate. Sliders are slidably engaged on both sets of guide rails. Mounting plates are fixed on both sides of the two sliders. The bottom of the mounting plate is connected to the piston end of the telescopic cylinder. The telescopic cylinder is fixed on the buffer base plate.
[0011] In one specific implementation scheme, the buffer mechanism includes a partition, a primary buffer plate, a U-shaped seat, a push rod, a secondary buffer box, and a buffer sleeve. The partition is located inside the base and contacts the inner wall of the base. Several primary buffer plates are installed on the top of the partition, and the primary buffer plates are arranged in an equidistant array. Several U-shaped seats are symmetrically installed on both sides of the partition, and push rods are rotatably fitted on the U-shaped seats. The other end of the push rod is connected to the secondary buffer box, which is installed at the bottom of the base. The bottom of the partition is connected to the buffer sleeve, which is located on the base.
[0012] In one specific implementation scheme, several of the primary buffer plates are arc-shaped components with the same structure. By utilizing the mechanical properties of the arc structure, when an external force is applied to the arc surface, the impact force will be decomposed along the curved surface and transmitted to a larger area, avoiding local concentration. In addition, the arc design can undergo elastic deformation when subjected to force, storing and releasing some energy and improving stability.
[0013] In one specific implementation scheme, the secondary buffer box includes a sliding groove, a push block, a buffer spring, and an airbag. The inner wall of the secondary buffer box has sliding grooves on both sides, and the push block is slidably fitted in the sliding grooves on both sides. The top of the push block is fixed to a push rod, and a buffer spring is installed at the front end of the push block. The other end of the buffer spring is fixed to the inner wall of the secondary buffer box, and an airbag is installed on the spring joint at the tail end of the buffer spring. The airbag is a rubber elastic airbag.
[0014] In one specific implementation scheme, when the textile equipment is mounted on the mounting plate of the positioning mechanism, the equipment's gravity will press down on the buffer mechanism and drive the buffer base plate to move downwards until the bottom of the textile equipment contacts the top of the base and then stops.
[0015] In one specific implementation, the buffer sleeve includes an outer cylinder, a buffer post, and a secondary buffer spring. The buffer post is slidably fitted inside the outer cylinder, inserted into the outer cylinder, and a secondary buffer spring is installed between the bottom of the buffer post and the outer cylinder.
[0016] In one specific implementation, the support leg includes a leveling mechanism, a motor, and a top plate. The leveling mechanism is mounted on the top of the support leg, and a motor is mounted on the outer side of the leveling mechanism. The motor is electrically connected to an external control unit, and a top plate connected to the base is connected to the top of the leveling mechanism.
[0017] In one specific implementation scheme, the leveling mechanism includes a worm gear, a limiting seat, a worm wheel, a rotating seat, a pull rod, rollers, an L-shaped groove, and a lifting rod. The worm gear is rotatably fitted onto the leveling mechanism, and one end is connected to the output end of the motor. The limiting seat is rotatably fitted onto the worm gear and is fixed to the leveling mechanism. The worm wheel meshes with the bottom of the worm gear and is rotatably fitted onto the rotating seat. The rotating seat is fixed to the leveling mechanism. A pull rod is rotatably fitted onto one side of the worm wheel. Rollers are installed at both ends of the pull rod, and the rollers are located in the L-shaped groove. The L-shaped groove is installed on the side wall of the leveling mechanism. A lifting rod is connected to one side of the pull rod.
[0018] In one specific implementation scheme, the leveling mechanism has a leveling accuracy of ±0.1mm. The motor drives the lifting rod to rise and fall through a worm gear transmission, with a lifting stroke of 0-50mm, adapting to working conditions with a ground height difference of 0-50mm.
[0019] In one specific implementation, the two sets of rollers installed at both ends of the pull rod are located inside the two sliding grooves in the transverse and longitudinal directions of the L-shaped groove, respectively, and can slide inside them to drive the pull rod to change the tilt angle.
[0020] According to the above-mentioned technical solution, the present invention provides a fixing base for textile equipment, which has the following beneficial effects:
[0021] (1) The present invention provides a positioning mechanism on the base of the textile equipment. By extending and retracting the piston rod on the telescopic cylinder, the mounting plate and the slider connected to the mounting plate move back and forth on the guide rail, thereby adjusting the installation position of the textile equipment. The position can be adjusted according to the installation position size of textile equipment of different sizes, which is highly applicable and improves the installation efficiency of the equipment.
[0022] (2) The present invention provides a buffer mechanism in the base of the textile equipment. The first-level buffer plate disperses the vibration energy, the buffer spring and the air bladder can absorb high-frequency vibration, and the second-level buffer spring absorbs medium and low-frequency vibration. Through the cooperation between the first-level buffer plate and the second-level buffer box, the vibration of the textile equipment in the whole frequency band is suppressed in stages, so that the vibration of the main shaft bearing and other core components of the equipment is buffered and reduced, the wear rate of the equipment components is reduced, the replacement cycle is extended, and the noise of the textile equipment is also reduced.
[0023] (3) The present invention provides a leveling mechanism on the support feet of the equipment base. The worm gear driven by the motor rotates will drive the worm wheel at the bottom to rotate. The worm wheel drives the pull rod on one side to move synchronously in the L-shaped groove, thereby adjusting the height of the four feet on the base. This can quickly compensate for the difference in ground height to adapt to uneven ground, avoid the equipment from tilting and affecting the textile processing efficiency, and ensure the horizontal placement of the base and textile equipment.
[0024] (4) After the device of the present invention is installed on the base, the buffer plate moves downward under the action of gravity to the bottom of the device and fits against the base to form a pre-positioning lock. With the rigid connection of the positioning mechanism, it effectively prevents horizontal displacement during the operation of the device and ensures the stability of the processing accuracy.
[0025] (5) The various mechanisms of the present invention adopt a modular and detachable design. The components of the positioning mechanism and the buffer mechanism (such as sliders, buffer springs and airbags) can be disassembled and replaced individually without disassembling the base as a whole. The stepper motor and worm gear transmission structure of the leveling mechanism can reduce the failure rate and make the maintenance cycle longer than the equipment overhaul cycle, further reducing the maintenance cost of the equipment. Attached Figure Description
[0026] Other features, objects, and advantages of the present invention will become more apparent from the following detailed description of non-limiting embodiments with reference to the accompanying drawings:
[0027] Figure 1 This is a schematic diagram of a fixed base for textile equipment in an embodiment of this application;
[0028] Figure 2 This is a schematic diagram of the positioning mechanism in the embodiments of this application;
[0029] Figure 3 This is a schematic diagram of the buffer mechanism in the embodiments of this application;
[0030] Figure 4 This is a schematic diagram of the structure of the secondary buffer box in the embodiments of this application;
[0031] Figure 5 This is a schematic diagram of the installation of the airbag bulb in an embodiment of this application;
[0032] Figure 6 This is a schematic diagram of the structure of the buffer sleeve in the embodiments of this application;
[0033] Figure 7 This is a schematic diagram of the support leg structure in the embodiments of this application;
[0034] Figure 8 This is a schematic diagram of the leveling mechanism in an embodiment of this application.
[0035] In the diagram: Base-1, Buffer base plate-2, Positioning mechanism-3, Support leg-4, Buffer mechanism-5, Guide rail-31, Slider-32, Mounting plate-33, Telescopic cylinder-34, Partition plate-51, Primary buffer plate-52, U-shaped seat-53, Push rod-54, Secondary buffer box-55, Buffer sleeve-56, Slide groove-551, Push block-552, Buffer spring-553, Airbag ball-554, Outer cylinder-561, Buffer column-562, Secondary buffer spring-563, Leveling mechanism-41, Motor-42, Top plate-43, Worm gear-11, Limit seat-12, Worm wheel-13, Rotating seat-14, Pull rod-15, Roller-16, L-shaped groove-17, Lifting rod-18. Detailed Implementation
[0036] To make the technical means, creative features, objectives and effects of this invention easier to understand, the invention will be further described below in conjunction with specific embodiments.
[0037] Example 1: Please refer to Figures 1-6 The specific embodiments of the present invention are as follows:
[0038] A fixed base for textile equipment includes a base 1, a buffer base plate 2, a positioning mechanism 3, support legs 4, and a buffer mechanism 5. The bottom of the base 1 has several support legs 4 arranged in an array. The base 1 has a built-in buffer mechanism 5 that can buffer the vibration generated when the textile equipment is running. The top of the buffer mechanism 5 is connected to the buffer base plate 2. The top of the buffer base plate 2 is equipped with the positioning mechanism 3. The top of the positioning mechanism 3 is connected to the bottom of the textile equipment.
[0039] Please see Figures 1-2 The positioning mechanism 3 includes a guide rail 31, a slider 32, a mounting plate 33, and a telescopic cylinder 34. Two sets of guide rails 31 are symmetrically arranged and mounted on the buffer base plate 2. Slider 32 is slidably fitted on both sets of guide rails 31. Mounting plates 33 are fixed on both sides of the two sliders 32. The mounting plates 33 can be installed and fixed to the base of the textile equipment by bolts. The bottom of the mounting plate 33 is connected to the piston end of the telescopic cylinder 34. The telescopic cylinder 34 is fixed on the buffer base plate 2.
[0040] Please see Figure 2 By driving the telescopic cylinder 34 to operate, and with the extension and retraction of the piston rod, the mounting plate 33 connected to it and the slider 32 connected to the mounting plate 33 can be moved back and forth on the guide rail 31, thereby adjusting the installation position of the textile equipment. The position can be adjusted according to the installation position size of textile equipment of different sizes, making it highly adaptable.
[0041] Please see Figure 3The buffer mechanism 5 includes a partition 51, a primary buffer plate 52, a U-shaped seat 53, a push rod 54, a secondary buffer box 55, and a buffer sleeve 56. The partition 51 is located inside the base 1 and contacts the inner wall of the base 1. Several primary buffer plates 52 are installed on the top of the partition 51. The primary buffer plates 52 are arranged in an array at equal intervals. Several U-shaped seats 53 are symmetrically installed on both sides of the partition 51. Push rods 54 are rotatably fitted on the U-shaped seats 53. The other end of the push rod 54 is connected to the secondary buffer box 55. The secondary buffer box 55 is installed at the bottom of the base 1. The bottom of the partition 51 is connected to the buffer sleeve 56, which is located on the base 1.
[0042] Please see Figure 3 Several primary buffer plates 52 are arc-shaped components with the same structure. With the help of the mechanical properties of the arc structure, when an external force is applied to the arc surface, the impact force will be decomposed along the curved surface and transmitted to a larger area, avoiding local concentration. Moreover, the arc design can undergo elastic deformation when subjected to force, storing and releasing some energy and improving stability.
[0043] Please see Figures 4-5 The secondary buffer box 55 includes a slide groove 551, a push block 552, a buffer spring 553, and an airbag ball 554. The inner wall of the secondary buffer box 55 has slide grooves 551 on both sides, and push blocks 552 are slidably fitted in the slide grooves 551 on both sides. The top of the push block 552 is fixed to the push rod 54. The front end of the push block 552 is equipped with a buffer spring 553. The other end of the buffer spring 553 is fixed to the inner wall of the secondary buffer box 55. An airbag ball 554 is installed on the spring joint at the tail end of the buffer spring 553. The airbag ball 554 is a rubber elastic airbag. When the buffer spring 553 is compressed by the movement of the push block 552, the airbag ball 554 can squeeze the airbag ball 554, which can increase the buffering performance of the buffer spring 553.
[0044] Please see Figures 1-5 When the textile equipment is installed on the mounting plate 33 of the positioning mechanism 3, under the action of the equipment's gravity, it will squeeze the buffer mechanism 5 downward and drive the buffer base plate 2 to move downward until the bottom of the textile equipment contacts the top of the base 1 and then stops.
[0045] Please see Figure 5 When the textile equipment is running, it generates downward vibration force. With the help of the arc-shaped structure of the primary buffer plate 52 installed on the buffer mechanism 5, the external force can be effectively dispersed, energy absorbed and local impact reduced, thus providing initial buffering for the vibration of the equipment. Then, under the action of the equipment's gravity and vibration force, it will press down on the partition plate 51 and move forward through the push rods 54 on both sides of the partition plate 51, compressing the buffer spring 553. Under the action of the buffer spring 553 and the airbag ball 554, the textile equipment can reduce vibration and noise.
[0046] Please see Figure 6 The buffer sleeve 56 includes an outer cylinder 561, a buffer column 562, and a secondary buffer spring 563. The buffer column 562 is slidably fitted inside the outer cylinder 561. The buffer column 562 is inserted into the outer cylinder 561, and a secondary buffer spring 563 is installed between the bottom of the buffer column 562 and the outer cylinder 561. When the buffer column 562 is subjected to the downward gravity and compression force of the partition 51, it will move downward and compress the secondary buffer spring 563. The secondary buffer spring 563 can play a buffering role for the buffer column 562. The elastic coefficient of the secondary buffer spring 563 is greater than that of the buffer spring 553.
[0047] Example 2: Please refer to Figures 7-8 The specific embodiments of the present invention are as follows:
[0048] Please see Figure 7 The support leg 4 includes a leveling mechanism 41, a motor 42 and a top plate 43. The leveling mechanism 41 is installed on the top of the support leg 4. The motor 42 is installed on the outer side of the leveling mechanism 41. The motor 42 is electrically connected to the external control unit. The top of the leveling mechanism 41 is connected to the top plate 43, which is connected to the base 1.
[0049] Please see Figures 7-8 The leveling mechanism 41 includes a worm gear 11, a limiting seat 12, a worm wheel 13, a rotating seat 14, a pull rod 15, a roller 16, an L-shaped groove 17, and a lifting rod 18. The worm gear 11 is rotatably fitted onto the leveling mechanism 41, and one end is connected to the output end of the motor 42. The worm gear 11 is driven to rotate by the forward and reverse rotation of the motor 42. The limiting seat 12 is rotatably fitted onto the worm gear 11 and is fixed to the leveling mechanism 41. The worm wheel 13 meshes with the bottom of the worm gear 11 and is rotatably fitted onto the rotating seat 14. On the seat 14, the rotating seat 14 is fixed to the leveling mechanism 41. A pull rod 15 is rotatably fitted on one side of the worm gear 13. Rollers 16 are installed at both ends of the pull rod 15. The rollers 16 are located in the L-shaped groove 17 and can slide in the L-shaped groove 17. The L-shaped groove 17 is installed on the side wall of the leveling mechanism 41. A lifting rod 18 is connected to one side of the pull rod 15. The lifting rod 18 passes through the outside of the leveling mechanism 41 and is connected to the top plate 43, which can drive the top plate 43 to adjust the height.
[0050] Please see Figures 7-8 The leveling mechanism 41 has a leveling accuracy of ±0.1mm. The motor 42 drives the lifting rod 18 to rise and fall through the worm gear transmission. The lifting stroke is 0-50mm, which is suitable for working conditions with a ground height difference of 0-50mm.
[0051] Please see Figure 8The two sets of rollers 16 installed at both ends of the pull rod 15 are located inside the two sliding grooves in the horizontal and vertical directions of the L-shaped groove 17, respectively, and can slide inside them to drive the pull rod 15 to change the tilt angle.
[0052] Please see Figures 7-8 The motor 42 drives the worm gear 11 to rotate, which, with the help of the worm wheel and worm, drives the worm wheel 13 at the bottom to rotate. As the worm wheel 13 rotates, it drives the pull rod 15 on one side to move synchronously in the L-shaped groove 17, thereby adjusting the height of the lifting rod 18.
[0053] Please see Figures 1-8 The components of the positioning and buffering mechanisms (such as sliders, buffer springs, and airbags) can be disassembled and replaced individually without disassembling the entire base. The stepper motor and worm gear transmission structure of the leveling mechanism can reduce the failure rate and make the maintenance cycle longer than the equipment overhaul cycle, further reducing the maintenance cost of the equipment.
[0054] Based on the above embodiments, the specific working principle is as follows:
[0055] When the textile equipment needs to be placed on the base 1, the mounting plate 33 provided on the base 1 is installed and fixed to the bottom of the textile equipment. Then, the telescopic cylinder 34 drives the mounting plate 33 and the slider 32 connected to it to move back and forth on the guide rail 31, thereby adjusting the installation position of the textile equipment. When the textile equipment is installed on the mounting plate 33, under the action of the equipment's gravity, it will squeeze the buffer mechanism 5 downward and drive the buffer base plate 2 to move downward until the bottom of the textile equipment contacts the top of the base 1 and then stops.
[0056] When the textile equipment is running, it generates downward vibration force. The primary buffer plate 52 installed on the buffer mechanism 5 can effectively disperse the external force, absorb energy and reduce local impact, thus providing initial buffering for the vibration of the equipment. Then, under the action of the equipment's gravity and vibration force, it will press down on the partition plate 51, and the push rods 54 on both sides of the partition plate 51 will move forward to press the buffer spring 553. Under the action of the buffer spring 553 and the airbag ball 554, the textile equipment can reduce vibration and noise.
[0057] When the ground is uneven, the motor 42 drives the worm gear 11 to rotate. With the help of the worm wheel and worm gear, the worm wheel 13 at the bottom will rotate. As the worm wheel 13 rotates, the pull rod 15 on one side will move synchronously in the L-shaped groove 17, thereby adjusting the height of the lifting rod 18.
[0058] This invention solves the problems of existing high-speed air-jet looms, which, due to the high-speed rotation of the spindle, generate high-frequency vibrations that cause fabric defects such as weft breakage, weft shrinkage, and sparse or dense lines, and whose long-term vibrations exacerbate the wear of internal components and reduce the service life of the equipment.
[0059] This invention, through the combination of the above-mentioned components, uses a primary buffer plate to disperse vibration energy, a buffer spring and an air bladder to absorb high-frequency vibrations, and a secondary buffer spring to absorb mid- and low-frequency vibrations. Through the cooperation between the primary buffer plate and the secondary buffer box, it achieves graded suppression of vibrations across the entire frequency range of textile equipment, thereby buffering and reducing the vibrations of core components such as the main shaft bearings, reducing the wear rate of equipment components, extending the replacement cycle, and also reducing noise in textile equipment.
[0060] In the description of this invention, it should be understood that the indicated orientation or positional relationship is based on the orientation or positional relationship shown in the accompanying drawings, and is only for the convenience of describing this invention and simplifying the description, and is not intended to indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this invention.
[0061] The control method of the present invention is through a controller. The control circuit of the controller can be implemented by simple programming by those skilled in the art. The power supply is also common knowledge in the art. Therefore, the present invention will not explain the control method and circuit connection in detail.
[0062] The above are merely specific embodiments of this application, but the scope of protection of this application is not limited thereto. Any changes or substitutions that can be easily conceived by those skilled in the art within the scope of the technology disclosed in this application should be included within the scope of protection of this application.
Claims
1. A fixed base for textile equipment, comprising a base (1), a plurality of legs (4) arranged in an array at the bottom of the base (1), and a buffer mechanism (5) built into the base (1), wherein a buffer base plate (2) is connected to the top of the buffer mechanism (5), and a positioning mechanism (3) is mounted on the top of the buffer base plate (2), and the top of the positioning mechanism (3) is connected to the bottom of the textile equipment; characterized in that: The buffer mechanism (5) includes a partition (51), a plurality of primary buffer plates (52) located on the top of the partition (51), a plurality of U-shaped seats (53) symmetrically installed on both sides of the partition (51), and a push rod (54) for rotating with the plurality of U-shaped seats (53). The other end of the push rod (54) is connected to the secondary buffer box (55). The bottom of the partition (51) is connected to the buffer sleeve (56), and the buffer sleeve (56) is located on the base (1). The secondary buffer box (55) includes a sliding groove (551) on both sides of the inner wall of the secondary buffer box (55), a push block (552) for sliding cooperation with the sliding groove (551) on both sides, and a buffer spring (553) installed at the front end of the push block (552). The other end of the buffer spring (553) is fixed to the inner wall of the secondary buffer box (55), and an airbag ball (554) is installed on the spring joint at the tail end of the buffer spring (553). The support leg (4) includes a leveling mechanism (41) and a motor (42) located on the outside of the leveling mechanism (41). The motor (42) is electrically connected to an external control unit. The top of the leveling mechanism (41) is connected to a top plate (43) connected to the base (1). The leveling mechanism (41) includes a worm (11), a limiting seat (12) for rotating with the worm (11), a worm wheel (13) for meshing with the bottom of the worm (11), a rotating seat (14) for rotating with the worm wheel (13), and a pull rod (15) located on one side of the worm wheel (13). Rollers (16) are installed at both ends of the pull rod (15). The rollers (16) are located in an L-shaped groove (17). The L-shaped groove (17) is installed on the side wall of the leveling mechanism (41). A lifting rod (18) is connected to one side of the pull rod (15). The lifting rod (18) passes through the outside of the leveling mechanism (41) and is connected to the top plate (43). The positioning mechanism (3) includes a guide rail (31), a slider (32) for sliding cooperation with the guide rail (31), and a mounting plate (33) located on the slider (32). The bottom of the mounting plate (33) is connected to the piston end of the telescopic cylinder (34). The telescopic cylinder (34) is fixed on the buffer base plate (2) with a stroke of 0-600 mm. When textile equipment is installed on the mounting plate (33) of the positioning mechanism (3), under the action of the equipment's gravity, it will squeeze the buffer mechanism (5) downward and drive the buffer base plate (2) to move downward until the bottom of the textile equipment contacts the top of the base (1) and stops, thus achieving positioning and locking. Several of the first-level buffer plates (52) are arc-shaped components with the same structure. With the help of the mechanical properties of the arc structure, when an external force is applied to the arc surface, the impact force will be decomposed along the curved surface and transmitted to a larger area, avoiding local concentration. The leveling mechanism (41) has a leveling accuracy of ±0.1mm. The motor (42) drives the lifting rod (18) to rise and fall through the worm gear transmission. The lifting stroke is 0-50mm, which is suitable for working conditions with a ground height difference of 0-50mm. The components of the positioning mechanism (3) and the buffer mechanism (5) can be disassembled and replaced individually without disassembling the base (1) as a whole. The buffer sleeve (56) includes an outer cylinder (561), a buffer post (562), and a secondary buffer spring (563). The buffer post (562) is slidably fitted inside the outer cylinder (561). The buffer post (562) is inserted into the outer cylinder (561), and a secondary buffer spring (563) is installed between the bottom of the buffer post (562) and the outer cylinder (561). The airbag ball (554) is a rubber elastic airbag.
2. A fixing base for textile equipment according to claim 1, characterized in that: The secondary buffer box (55) is installed at the bottom of the base (1), and the top of the push block (552) is fixed to the push rod (54).
3. A fixing base for textile equipment according to claim 1, characterized in that: The two sets of rollers (16) installed at both ends of the pull rod (15) are located inside the two sliding grooves in the horizontal and vertical directions of the L-shaped groove (17), respectively, and can slide inside them to drive the pull rod (15) to change the tilt angle.