CN116695411A - Antistatic clothing fabric processing device - Google Patents

Abstract

The invention discloses an antistatic garment fabric processing device, which comprises a wind-up roll and is characterized in that: still include first dust removal roller structure and second dust removal roller structure, first dust removal roller structure and second dust removal roller structure include the interior panel respectively, the exterior panel, center roller and rotating electrical machines, rotating electrical machines sets up in the outside of interior panel and drives the center roller and rotate, the inboard of interior panel is provided with sun gear and ring gear, sun gear and center roller are connected, the meshing has planetary gear between sun gear and ring gear, the inboard rotation of outside panel is provided with central dish and ring, the center roller is connected on the central dish, the annular equipartition has many string archs of tightening between ring and ring gear, the equipartition has a plurality of hammers that are used for beating string arch on sun gear and/or central dish. The invention provides a preparation method of an antistatic clothing fabric processing device, which is used for cleaning flocks and dust on the front and back surfaces of a fabric and improving the dust removal effect of the fabric.

Description

Antistatic clothing fabric processing device

Technical Field

The invention relates to an antistatic garment fabric processing device.

Background

The antistatic clothing is used to prevent static electricity accumulation in static sensitive place, fire disaster or explosion dangerous place, and is suitable for electronic, optical instrument, medicine, microbial engineering, precise instrument and other fields. The antistatic clothing is sewn by taking antistatic fabric as a fabric, wherein the antistatic fabric is processed by antistatic processing, and after the antistatic fabric is processed, the antistatic fabric needs to be wound for convenient later storage and use.

At present, when the existing equipment is used for dedusting antistatic antibacterial fabrics, the following defects generally exist: the existing equipment cannot flap the fabric, and the dust and the filings adhered on the fabric are not easy to blow off and separate, so that the phenomenon of incomplete cleaning of the filings and the dust is easy to occur on the fabric after dust removal, and the dust removal effect of the fabric is reduced; most of the surface of a conveying roller used on the winding machine is smooth, so that the friction force between the conveying roller and the antistatic fabric is small, and the smoothness of the antistatic fabric during winding cannot be ensured.

Disclosure of Invention

Aiming at the current situation of the prior art, the invention provides the antistatic clothing fabric processing device, which can clean the filings and dust on the front and back surfaces of the fabric and improve the dust removal effect of the fabric.

The technical scheme adopted for solving the technical problems is as follows: the utility model provides an antistatic clothing surface fabric processingequipment, includes wind-up roll, its characterized in that: the novel multifunctional winding machine comprises a winding roller, a fabric winding roller, a first dust removing roller structure, a second dust removing roller structure, a central gear, a central disc, a circular ring, a plurality of tightening string bows, a central gear and/or a plurality of driving hammers for beating strings, wherein the winding roller is wound around the first dust removing roller structure and the second dust removing roller structure in sequence, the first dust removing roller structure and the second dust removing roller structure are wound around the winding roller, the first dust removing roller structure is located at the inner side surface of the fabric, the second dust removing roller structure is located at the outer side surface of the fabric, the first dust removing roller structure and the second dust removing roller structure respectively comprise an inner side plate, an outer side plate, a central roller and a rotating motor, the central roller is arranged at the central position between the outer side plate and the inner side plate in a rotating mode, the rotating motor is arranged outside the inner side plate to drive the central roller to rotate, the central gear and the circular ring are arranged at the inner side of the inner side plate, the central gear is connected with the central roller, the planetary gear is meshed between the central gear and the circular ring, the central disc and the circular ring are arranged on the central disc, and the plurality of tightening string bows are uniformly distributed between the circular ring and/or the central disc.

As an improvement, a plurality of supporting columns are uniformly distributed between the circular ring and the gear ring in the circumferential direction, the supporting columns are positioned between two adjacent string bows, radially arranged sliding grooves are respectively formed in the circular ring and the gear ring, a sliding block and a spring propped against the sliding block are arranged in the sliding grooves, the string bows are arranged on the sliding block, and in a natural state, the string bows are positioned outside the supporting columns.

And the tensioning mechanism is arranged on the sliding block and used for tensioning the string bow, the tensioning mechanism comprises a tensioning wheel, a screw rod and a nut, the string bow bypasses the tensioning wheel, the tensioning wheel is arranged on the sliding block, the nut is fixedly connected with the tensioning wheel, and the screw rod is connected with the nut in a matched manner.

And six rotating rollers are arranged between the second dust removing roller structure and the wind-up roller, the first rotating roller, the third rotating roller and the fifth rotating roller are positioned below, the second rotating roller, the fourth rotating roller and the sixth rotating roller are positioned above, the fabric is wound around the first rotating roller, the second rotating roller, the fourth rotating roller, the third rotating roller, the fifth rotating roller and the sixth rotating roller in sequence and then wound on the wind-up roller, a first cavity with a downward opening and a second cavity with an upward opening are formed between the six rotating rollers and the fabric, a first vibration dust removing structure is arranged in the first cavity, a second vibration dust removing structure is arranged in the second cavity, a first dust collecting box is arranged below the first cavity, an opening of the first dust collecting box is upward and extends to the lower part of the first dust removing roller structure, a second dust collecting box is arranged above the second cavity, an opening of the second dust collecting box is upward and extends to the upper part of the second dust removing roller structure, and a suction pump is respectively arranged at the first dust collecting box and the second dust collecting box.

The improved structure is characterized in that the first vibration dust removing structure and the second vibration dust removing structure respectively comprise an N pole plate, an S pole plate, a first conductive rail, a second conductive rail, a power supply and a current reverser, the N pole plate and the S pole plate are arranged up and down, the first conductive rail and the second conductive rail are horizontally arranged and are positioned on the outer side of the fabric, guide grooves are respectively formed in the opposite side walls of the first conductive rail and the second conductive rail, a conductive rod is arranged in the guide grooves in a moving mode, an insulating sleeve is sleeved on the outer wall of the conductive rod, an impact part for impacting the fabric is arranged on the insulating sleeve in an extending mode, and the first conductive rail and the second conductive rail are respectively connected with the current reverser and the power supply.

Still improve, be provided with the leveling mechanism that is used for carrying out the flattening to the surface fabric between wind-up roll and the sixth roller, leveling mechanism is including two screeds that are V-arrangement and one end are articulated each other together, is provided with the conveyer belt along length direction on the screeds, is provided with the flattening motor that is used for driving the conveyer belt motion on the screeds, and the interval arrangement has the shovel piece that is used for carrying out the leveling to the surface fabric on the lateral wall of conveyer belt.

Compared with the prior art, the invention has the advantages that: the fabric is subjected to a first dust removing roller structure and a second dust removing roller structure, the first dust removing roller structure cleans the inner side surface of the fabric, the second dust removing roller structure removes dust on the outer side surface of the fabric, and particularly, when the fabric bypasses the first dust removing roller structure and the second dust removing roller structure, the whole string bow is pressed on the surface of the fabric, the rotating motor drives the center roller to rotate in the process of driving the gear ring through the planetary gear and the center gear, the rotation directions of the center gear and the gear ring are opposite, and in the rotation process, the driving hammer on the inner side wall of the center gear and/or the inner side wall of the center disk continuously knocks the string bow, so that the string bow vibrates and the vibration is transferred to the fabric, the flocks and the dust on the fabric are separated from the surface of the fabric, and the suction pump is used for sucking away the flocks and the dust on the surface of the fabric, so that the flocks and the dust on the surface of the fabric are cleaned, and the dust removing effect on the surface of the fabric is improved.

Drawings

FIG. 1 is a schematic structural view of an antistatic garment materials processing device in an embodiment of the invention;

FIG. 2 is a schematic view of the first dust collector roll structure of FIG. 1;

FIG. 3 is another schematic view of the first dust collector roll configuration of FIG. 1;

FIG. 4 is a schematic view of the first vibratory dust collection structure of FIG. 1;

fig. 5 is a schematic view of the leveling mechanism of fig. 1.

Detailed Description

The invention is described in further detail below with reference to the embodiments of the drawings.

As shown in fig. 1 to 5, the antistatic garment materials processing apparatus in this embodiment includes a wind-up roll 4, a first dust removing roll structure 1, a second dust removing roll structure 101, a first roll 61, a second roll 62, a third roll 63, a fourth roll 64, a fifth roll 65 and a sixth roll 66, a first vibration dust removing structure 2, a second vibration dust removing structure 201, and a leveling mechanism 3.

As shown in fig. 1 and 2, the fabric 5 bypasses the first dust removing roller structure 1 and the second dust removing roller structure 101 and winds around the wind-up roller 4 in turn, the first dust removing roller structure 1 is located at the inner side surface of the fabric 5, the second dust removing roller structure 101 is located at the outer side surface of the fabric 5, the first dust removing roller structure 1 and the second dust removing roller structure 11 respectively comprise an inner side plate 11, an outer side plate 12, a central roller 13 and a rotating motor, the central roller 13 is rotatably arranged at the central position between the outer side plate 12 and the inner side plate 11, the rotating motor is arranged outside the inner side plate 11 to drive the central roller 13 to rotate, a central gear 15 and a gear ring 17 are arranged at the inner side of the inner side plate 11, the central gear 15 is connected with the central roller 13, a planetary gear 16 is meshed between the central gear 15 and the gear ring gear 17, a plurality of stretched strings 14 are annularly and uniformly distributed between the ring and the gear ring 17, a plurality of beating hammers 15 and/or a plurality of beating bows are uniformly distributed on the central gear 15 and/or the central plate, the first dust removing roller structure 1 and the second dust removing roller structure 101 are respectively connected with a dust collecting box.

The fabric 5 passes through the first dust removing roller structure 1 and the second dust removing roller structure 101, the first dust removing roller structure 1 cleans the inner side surface of the fabric 5 with dust, the second dust removing roller structure 101 removes dust on the outer side surface of the fabric 5, specifically, the dust removing modes of the first dust removing roller structure 1 and the second dust removing roller structure 101 are that when the fabric 5 bypasses the first dust removing roller structure 1 and the second dust removing roller structure 101, the whole string bow 14 is pressed on the surface of the fabric 5, the rotating motor drives the central roller 13 to rotate, the planetary gear 16 and the central gear 15 drive the gear ring 17 to rotate in the rotating process, and the rotating directions of the central gear 15 and the gear ring 17 are opposite, in the rotating process, the central gear 16 and/or the inner side wall of the central disk continuously knocks the string bow 14 to enable the string bow 14 to vibrate, the vibration is transmitted to the fabric 5, and the hair and dust on the fabric 5 are separated from the surface of the fabric, and then the suction pump is utilized to suck away, so that the hair and dust on the surface of the fabric 5 is cleaned, and the dust removing effect of the fabric 5 is improved.

Further, in the first dust removing roller structure 1 and the second dust removing roller structure 101, since the chord bow 14 is small in diameter, if it is in direct contact with the face fabric 5, the face fabric 5 is easily cut, and for this reason, the first dust removing roller structure 1 and the second dust removing roller structure 101 are improved. Specifically, as shown in fig. 3, a plurality of support columns 18 are uniformly distributed between the ring and the gear ring 17 in the circumferential direction, the support columns 18 are located between two adjacent string bows 14, radially arranged sliding grooves 192 are respectively arranged on the ring and the gear ring 17, sliding blocks 19 and springs 191 which are abutted against the sliding blocks 19 are arranged in the sliding grooves 192, the string bows 14 are arranged on the sliding blocks 19, and in a natural state, the string bows 14 are located outside the support columns 18. Thus, by arranging the support column 18 structure, when the fabric 5 is wrapped on the first dust removing roller structure 1 and the second dust removing roller structure 101, the string bow 14 is pressed on the fabric, and the fabric 5 is supported on the support column 19. Due to the adoption of the structures of the sliding blocks 19 and the springs 191, the string bow 14 can be pressed on the fabric 5, and the string bow 14 can remove dust and vibrate the fabric 5 between two adjacent support columns 18.

Still further, in order to realize adjusting the tension of the string bow 14, the slider 19 is provided with a tensioning mechanism for tensioning the string bow 14, the tensioning mechanism comprises a tensioning wheel, a screw and a nut, the string bow 14 bypasses the tensioning wheel, the tensioning wheel is further arranged on the slider 19, the nut is fixedly connected with the tensioning wheel, and the screw is in fit connection with the nut. Thus, the tension of the string bridge 14 is adjusted by rotating the screw to adjust the position of the slider 19.

In addition, in order to reduce interference between the hammer and the support column 18, the support column 18 is disposed on opposite inner side walls of the ring and the ring gear 17, and at the same time, the sun gear 15 and the ring gear 17 penetrate the inner side plate 11, the center plate and the ring penetrate the outer side plate 12, the ends of the string bow 14 penetrate the corresponding ring gear 17 and ring respectively, a connecting frame is formed on the outer side walls of the ring gear 17 and ring, the ends of the string bow 14 are connected to the connecting frame, the hammer is disposed on the outer side walls of the sun gear 15 and the center plate, and the hammer can hammer the string bow 14 outside the ring gear 17 and ring.

In addition, in the embodiment of the present invention, in order to improve the dust removing effect, as shown in fig. 1 and 4, six rotating rolls are disposed between the second dust removing roll structure 101 and the wind-up roll 4, the first rotating roll 61, the third rotating roll 63 and the fifth rotating roll 65 are located below, the second rotating roll 62, the fourth rotating roll 63 and the sixth rotating roll 66 are located above, the fabric 5 is wound around the first rotating roll 61, the second rotating roll 62, the fourth rotating roll 64, the third rotating roll 63, the fifth rotating roll 65 and the sixth rotating roll 66 in sequence and then wound on the wind-up roll 5, a first cavity 41 with a downward opening and a second cavity 42 with an upward opening are defined between the six rotating rolls and the fabric 5, a first vibration dust removing structure 2 is disposed in the first cavity 41, a second vibration dust removing structure 201 is disposed in the second cavity 42, a first dust collecting box 71 is disposed below the first cavity 41, the first dust collecting box 71 is opened upward and extends to the lower side of the first dust removing roll structure 1, a second dust box 72 is disposed above the second cavity 42, a second dust collecting box 72 is opened and a second dust collecting box 72 is disposed above the second dust collecting box 72 is opened and extends to the second dust collecting box 72 is disposed above the second dust box 72.

Specifically, in the embodiment of the present invention, as shown in fig. 4, the first vibration dust removing structure 2 and the second vibration dust removing structure 201 respectively include an N-pole plate 21, an S-pole plate 22, a first conductive rail 23, a second conductive rail 230, a power supply 25 and a current reverser, the N-pole plate 21 and the S-pole plate 22 are arranged up and down, the first conductive rail 23 and the second conductive rail 230 are horizontally arranged and are located at the outer side of the fabric 5, guide grooves 231 are respectively formed on opposite side walls of the first conductive rail 23 and the second conductive rail 230, a conductive rod 241 is disposed in the guide grooves 231, an insulating sleeve 24 is sleeved on the outer wall of the conductive rod 241, an impact part for impacting the fabric 5 is extended on the insulating sleeve 24, and the first conductive rail 23 and the second conductive rail 230 are respectively connected with the current reverser and the power supply 25.

The power supply 25 is electrified, the forward and reverse circulating flow of current is realized under the action of the current reverser, the current flows back through the first conductive rail 23, the conductive rod 241 and the second conductive rail 230, the current flows through the conductive rod 241, meanwhile, the insulating sleeve 24 impacts the fabric 5 back and forth in the first cavity 41 or the second cavity 42 under the action of the magnetic fields of the N pole plate 21 and the S pole plate 22, and meanwhile, the dust removing operation on the front and reverse sides of the fabric 5 can be realized by arranging the first vibration dust removing structure 2 and the second vibration dust removing structure 201.

Meanwhile, in order to realize that the conducting rod 241 can strike back and forth, the first vibration dust removing structure 2 and the second vibration dust removing structure 201 may further include an N pole plate 21, an S pole plate 22, a first conducting rail 23, a second conducting rail 230, a direct current power supply, a connecting frame and a control motor, wherein the N pole plate 21 and the S pole plate 22 are respectively connected to opposite ends of the connecting frame, the control motor is connected with the connecting frame, the first conducting rail 23 and the second conducting rail 230 are horizontally arranged transversely and are located at the outer side of the fabric 5, guide grooves 231 are respectively formed in opposite side walls of the first conducting rail 23 and the second conducting rail 230, the conducting rod 241 is arranged in the guide grooves 231 in a moving mode, an insulating sleeve 24 is sleeved on the outer wall of the conducting rod 241, an impact part for striking the fabric 5 extends on the insulating sleeve 24, and the first conducting rail 23 and the second conducting rail 230 are respectively connected with the direct current power supply. In this way, the on-off of the direct current power supply and the control motor drive the connecting frame to rotate are utilized to realize the up-and-down position exchange of the N pole plate 21 and the S pole plate 22, drive the conducting rod 241 to move, and finally realize the back-and-forth movement of the insulating sleeve 24.

Finally, in order to improve the flatness of the rolled fabric 5, in the embodiment of the present invention, as shown in fig. 5, a leveling mechanism 3 for leveling the fabric 5 is disposed between the wind-up roller 4 and the sixth roller 66, the leveling mechanism 3 includes two leveling plates 31 that are disposed in a V shape and have one ends hinged to each other, a conveyor belt 32 is disposed on the leveling plates 31 along the length direction, a leveling motor for driving the conveyor belt 32 to move is disposed on the leveling plates 31, and shovel blades 33 for leveling the fabric 5 are disposed on the outer side wall of the conveyor belt 32 at intervals. Like this, can be through breaking apart two screeds 31, adjust the contained angle between two screeds 31, simultaneously, the flattening motor on the screeds 31 drives conveyer belt 32 rotation, and the shovel piece 33 on the conveyer belt 32 is round the outer wall circulation rotation of conveyer belt 32, and shovel piece 33 is when surface fabric 5 top, and shovel piece 22 can outwards trend the shovel action to the surface fabric 5, ensures that surface fabric 5 keeps the leveling before receiving wind-up roll 4 to avoid surface fabric 5 to take place the fold.

Claims (6)

1. The utility model provides an antistatic clothing surface fabric processingequipment, includes wind-up roll (4), its characterized in that: the utility model also comprises a first dust removing roller structure (1) and a second dust removing roller structure (101), the fabric (5) winds around the first dust removing roller structure (1) and the second dust removing roller structure (101) in turn and winds around the wind-up roller (4), the first dust removing roller structure (1) is positioned at the inner side surface of the fabric (5), the second dust removing roller structure (101) is positioned at the outer side surface of the fabric (5), the first dust removing roller structure (1) and the second dust removing roller structure (101) respectively comprise an inner side plate (11), an outer side plate (12), a central roller (13) and a rotating motor, the central roller (13) is arranged at the central position between the outer side plate (12) and the inner side plate (11) in a rotating way, the rotating motor is arranged outside the inner side plate (11) to drive the central roller (13) to rotate, a central gear (15) and a gear ring gear (17) are arranged at the inner side of the inner side plate (11), the central gear (15) and the central gear (15) are connected with the central gear ring gear (17), a planetary gear (16) is meshed between the central gear (15) and the gear (17), the central gear (12) is arranged at the central rotating plate (12) and the central ring (13) is uniformly distributed on a ring disc (13), a plurality of hammers for striking the bows (14) are distributed on the central gear (15) and/or the central disk.

2. The antistatic garment fabric processing apparatus of claim 1, wherein: a plurality of supporting columns (18) are uniformly distributed between the circular ring and the gear ring (17) in the circumferential direction, the supporting columns (18) are located between two adjacent string bows (14), radially arranged sliding grooves (192) are respectively formed in the circular ring and the gear ring (17), sliding blocks (19) and springs (191) propped against the sliding blocks (19) are arranged in the sliding grooves (192), the string bows (14) are arranged on the sliding blocks (19), and in a natural state, the string bows (14) are located outside the supporting columns (18).

3. The antistatic garment fabric processing apparatus of claim 2, wherein: the tension mechanism for tensioning the string bow (14) is arranged on the sliding block (191) and comprises a tension wheel, a screw rod and a nut, the string bow bypasses the tension wheel, the tension wheel is also arranged on the sliding block (19), the nut is fixedly connected with the tension wheel, and the screw rod is connected with the nut in a matched mode.

4. The antistatic garment fabric processing apparatus of claim 1, wherein: six rotating rollers are arranged between the second dust removing roller structure (101) and the wind-up roller (4), the first rotating roller (61), the third rotating roller (63) and the fifth rotating roller (65) are located below, the second rotating roller (62), the fourth rotating roller (64) and the sixth rotating roller (66) are located above, the fabric (4) sequentially bypasses the first rotating roller (61), the second rotating roller (62), the fourth rotating roller (64), the third rotating roller (63), the fifth rotating roller (65) and the sixth rotating roller (66), then is wound on the wind-up roller (4), a first cavity (41) with a downward opening and a second cavity (42) with an upward opening are formed between the six rotating rollers and the fabric (5), a first vibration dust removing structure (2) is arranged in the first cavity (41), a second vibration dust removing structure (201) is arranged in the second cavity (42), a first dust collecting box (71) is arranged below the first cavity (41), the first dust collecting box (71) is opened to the second dust collecting box (72) and extends to the second dust collecting box (72) above the second dust collecting box (72).

5. The antistatic garment fabric processing apparatus of claim 4 wherein: the first vibration dust removal structure (2) and the second vibration dust removal structure (201) respectively comprise an N pole plate (21), an S pole plate (22), a first conductive rail (23), a second conductive rail (230), a power supply (25) and a current reverser, wherein the N pole plate (21) and the S pole plate (22) are arranged up and down, the first conductive rail (23) and the second conductive rail (230) are horizontally arranged and are positioned on the outer side of the fabric (5), guide grooves (231) are respectively formed in the opposite side walls of the first conductive rail (23) and the second conductive rail (230), conductive rods (241) are arranged in the guide grooves (231), an insulating sleeve (24) is sleeved on the outer wall of each conductive rod (241), impact parts for impacting the fabric (5) extend on the insulating sleeve (24), and the first conductive rail (23) and the second conductive rail (230) are respectively connected with the current reverser and the power supply (25).

6. The antistatic garment fabric processing apparatus of claim 5, wherein: leveling mechanism (3) that are used for carrying out the flattening to surface fabric (5) are provided with between wind-up roll (4) and sixth roller (66), leveling mechanism (3) are including two screeds (31) that are V-arrangement and one end are articulated each other together, are provided with conveyer belt (32) along length direction on screeds (31), are provided with on screeds (31) and are used for driving the flattening motor of conveyer belt (32) motion, and the interval is arranged on the lateral wall of conveyer belt (32) and is used for carrying out shovel flat shovel piece (33) to surface fabric (5).