阅读说明：本技术 力压式电磁辐射防护纺织面料表面绒毛处理涂胶设备 (Pressure type electromagnetic radiation protection textile fabric surface fluff treatment gluing equipment ) 是由 赵钟芳 于 2021-07-14 设计创作，主要内容包括：本发明涉及一种电磁辐射防护领域,尤其涉及一种力压式电磁辐射防护纺织面料表面绒毛处理涂胶设备。本发明的技术问题为：提供一种力压式电磁辐射防护纺织面料表面绒毛处理涂胶设备。技术方案如下：一种力压式电磁辐射防护纺织面料表面绒毛处理涂胶设备,包括有支撑架、第一滑动轨道、第二滑动轨道和涂胶机构等；支撑架上设置有涂胶机构。本发明实现了对纺织面料表面纠缠绒毛的处理,并在涂胶时将纺织面料表面绒毛梳理平整,使得胶水与纺织面料表面紧密接触,加大了胶水与纺织面料粘附力度,并且控制了胶水的涂覆范围,在纺织面料上贴压其它物件时不会使胶水溢出。(The invention relates to the field of electromagnetic radiation protection, in particular to a pressure type electromagnetic radiation protection textile fabric surface fluff treatment gluing device. The technical problem of the invention is as follows: provides a pressure type electromagnetic radiation protection textile fabric surface fluff treatment gluing device. The technical scheme is as follows: a pressure type electromagnetic radiation protection textile fabric surface fluff treatment gluing device comprises a support frame, a first sliding rail, a second sliding rail, a gluing mechanism and the like; the supporting frame is provided with a gluing mechanism. The method realizes the treatment of entangled fluff on the surface of the textile fabric, and the fluff on the surface of the textile fabric is carded and leveled during gluing, so that the glue is in close contact with the surface of the textile fabric, the adhesion strength of the glue and the textile fabric is increased, the coating range of the glue is controlled, and the glue cannot overflow when other objects are stuck and pressed on the textile fabric.)

1. A pressure type electromagnetic radiation protection textile fabric surface fluff treatment gluing device comprises a support frame (1), a first sliding rail (3), a second sliding rail (4) and a supporting plate (10); the support frame (1) is fixedly connected with the first sliding track (3) and the second sliding track (4); it is characterized by also comprising a lifting mechanism and a gluing mechanism; the supporting frame (1) is provided with a lifting mechanism; the lifting mechanism can prepare for the textile fabric except the surface pilling; a gluing mechanism is arranged on the support frame (1); the glue coating mechanism can coat glue on the textile fabric without pilling.

2. The surface fluff treatment and gluing equipment for the pressure-type electromagnetic radiation protection textile fabric, according to claim 1, is characterized in that the lifting mechanism comprises a first motor (201), a first driving wheel (202), a second driving wheel (203), a first screw rod (204), a third driving wheel (205), a moving rod (206), a first wedge-shaped block (207), a first polished rod (208), a first electromagnet (209), a second electromagnet (2010), a fourth driving wheel (2011), a second screw rod (2012), a fifth driving wheel (2013), a sixth driving wheel (2014), a first lifting frame (2015), a second polished rod (2016), a third screw rod (2017), a second lifting frame (2018) and a third polished rod (2019); the first motor (201) is fixedly connected with the support frame (1); the first motor (201) is fixedly connected with the inner axle center of the first transmission wheel (202); the outer ring surface of the first transmission wheel (202) is in transmission connection with a second transmission wheel (203) through a belt; the inner axle center of the second transmission wheel (203) is fixedly connected with the first screw rod (204) through a shaft sleeve; the first screw rod (204) is fixedly connected with the inner axle center of the third driving wheel (205) through a shaft sleeve; the first screw rod (204) is rotationally connected with the first electric slide rail (5); the first screw rod (204) is rotatably connected with the support frame (1); the first screw rod (204) is connected with the movable rod (206) in a screwing way; the outer ring surface of the third driving wheel (205) is in transmission connection with a fourth driving wheel (2011) through a belt; the moving rod (206) is fixedly connected with the first wedge-shaped block (207); the movable rod (206) is in sliding connection with the first polish rod (208); one side of the movable rod (206) is fixedly connected with the first electromagnet (209); the other side of the movable rod (206) is fixedly connected with a second electromagnet (2010); the first polish rod (208) is fixedly connected with the support frame (1); the first polish rod (208) is fixedly connected with the second electric slide rail (6); the inner axis of the fourth transmission wheel (2011) is fixedly connected with the second screw rod (2012) through a shaft sleeve; the second screw rod (2012) is fixedly connected with the inner axle center of the fifth driving wheel (2013) through a shaft sleeve; the second screw rod (2012) is rotatably connected with the first electric slide rail (5); the second screw rod (2012) is connected with the first lifting frame (2015) in a screwing way; the second screw rod (2012) is rotatably connected with the support frame (1); the outer ring surface of the fifth driving wheel (2013) is in transmission connection with a sixth driving wheel (2014) through a belt; the inner axle center of the sixth driving wheel (2014) is fixedly connected with a third screw rod (2017) through a shaft sleeve; the first lifting frame (2015) is in sliding connection with the second polish rod (2016); the first lifting frame (2015) is in contact with the cutter (9); the second polish rod (2016) is fixedly connected with the first electric slide rail (5); the second polish rod (2016) is fixedly connected with the support frame (1); the third screw rod (2017) is rotatably connected with the second electric slide rail (6); the third screw rod (2017) is in screwed connection with the second lifting frame (2018); the third screw rod (2017) is rotatably connected with the support frame (1); the second lifting frame (2018) is in sliding connection with the third polished rod (2019); the third polish rod (2019) is fixedly connected with the second electric slide rail (6); the third polish rod (2019) is fixedly connected with the support frame (1).

3. The gluing equipment for the fluff treatment on the surface of the pressure type electromagnetic radiation protection textile fabric, according to claim 2, characterized in that the gluing equipment comprises a second motor (301), a first transmission rod (302), a first bevel gear (303), a second bevel gear (304), a second transmission rod (305), a first column gear (306), a first flat gear (307), a third transmission rod (308), a second wedge-shaped block (309), a third wedge-shaped block (3010), a second flat gear (3011), a fourth transmission rod (3012), a seventh transmission wheel (3013), an eighth transmission wheel (3014), a fifth transmission rod (3015), a third bevel gear (3016), a fourth bevel gear (3017), a sixth transmission rod (3018), a ninth transmission wheel (3019), a tenth transmission wheel (3020), a fourth lead screw (3021), a gluing device (3022), a fourth polish rod (3023), a roller (302201), The device comprises a protective frame (302202), a telescopic block (302203), a first spring (302204), a second spring (302205), a fixed frame (302206), a first rack (302207), a second rack (302208), a second column gear (302209), a first toothed bar (3022010), a second toothed bar (3022011), a glue storage tank (3022012), a rotating plate (3022013), a rotating rod (3022014), a guide plate (3022015) and a brush (3022016); the second motor (301) is fixedly connected with the support frame (1); the second motor (301) is fixedly connected with the first transmission rod (302); the first transmission rod (302) is rotatably connected with the support frame (1) through a bracket; the first transmission rod (302) is fixedly connected with the inner axis of the first bevel gear (303); the first bevel gear (303) is meshed with the second bevel gear (304); the inner axis of the second bevel gear (304) is fixedly connected with a second transmission rod (305); the second transmission rod (305) is rotatably connected with the support frame (1) through a bracket; the second transmission rod (305) is fixedly connected with the inner axle center of the first cylindrical gear (306); the first column gear (306) is meshed with the first flat gear (307); the inner axle center of the first flat gear (307) is fixedly connected with a third transmission rod (308); a second flat gear (3011) is arranged on one side of the first flat gear (307); the third transmission rod (308) is in transmission connection with the support frame (1); (ii) a The third transmission rod (308) is rotationally connected with the second wedge-shaped block (309); the second wedge block (309) is in contact with the third wedge block (3010); the second wedge-shaped block (309) and the third wedge-shaped block (3010) are in sliding connection with the support frame (1) through a base sliding groove; the inner axis of the second flat gear (3011) is fixedly connected with a fourth transmission rod (3012); the fourth transmission rod (3012) is rotatably connected with the support frame (1) through a bracket; the fourth transmission rod (3012) is fixedly connected with the inner axis of the seventh transmission wheel (3013); the outer ring surface of the seventh driving wheel (3013) is in transmission connection with the eighth driving wheel (3014) through a belt; the inner axle center of the eighth transmission wheel (3014) is fixedly connected with the fifth transmission rod (3015); the fifth transmission rod (3015) is rotatably connected with the support frame (1) through a bracket; the fifth transmission rod (3015) is fixedly connected with the inner axis of the third bevel gear (3016); the third bevel gear (3016) is engaged with the fourth bevel gear (3017); the inner axis of the fourth bevel gear (3017) is fixedly connected with a sixth transmission rod (3018); the sixth transmission rod (3018) is rotatably connected with the support frame (1) through a bracket; the sixth transmission rod (3018) is fixedly connected with the inner axis of the ninth transmission wheel (3019); the sixth transmission rod (3018) is fixedly connected with the fifth screw rod (401); the outer ring surface of the ninth driving wheel (3019) is in transmission connection with a tenth driving wheel (3020) through a belt; the inner axis of the tenth driving wheel (3020) is fixedly connected with a fourth screw rod (3021) through a shaft sleeve; the fourth screw rod (3021) is screwed with the glue applicator (3022); the fourth screw rod (3021) is rotatably connected with the support frame (1) through a shaft sleeve; the glue applicator (3022) is connected with the fourth polish rod (3023) in a sliding manner; the fourth polish rod (3023) is fixedly connected with the support frame (1) through a bracket; the roller (302201) is rotatably connected with the protective frame (302202) through a bracket; the protective frame (302202) is fixedly connected with the telescopic block (302203) through a bracket; the telescopic block (302203) is fixedly connected with the first rack (302207) and the second rack (302208); the telescopic block (302203) is fixedly connected with the first spring (302204) and the second spring (302205); the first spring (302204) and the second spring (302205) are fixedly connected with the fixed frame (302206); the fixed frame (302206) is fixedly connected with the glue storage groove (3022012); the first rack (302207) and the second rack (302208) are both engaged with the second column gear (302209); the second column gear (302209) is meshed with both the first rack (3022010) and the second rack (3022011); the second column gear (302209) is rotationally connected with the fixed frame (302206) through a rotating rod; one sides of the first toothed bar (3022010) and the second toothed bar (3022011) are in sliding connection with the glue storage tank (3022012) through sliding grooves; the other sides of the first rack bar (3022010) and the second rack bar (3022011) are rotatably connected with a rotating plate (3022013) through a bracket; the two sides of the glue storage tank (3022012) are respectively provided with a combination of a roller (302201), a protective frame (302202), a telescopic block (302203), a first spring (302204), a second spring (302205), a fixed frame (302206), a first rack (302207), a second rack (302208), a second rack gear (302209), a first rack bar (3022010) and a second rack bar (3022011); the glue storage tank (3022012) is fixedly connected with the rotary rod (3022014); the glue storage tank (3022012) is fixedly connected with the guide plate (3022015) through a bracket; the rotating rod (3022014) is in rotating connection with the rotating plate (3022013); the guide plate (3022015) is fixedly connected with the brush (3022016) through a bracket; when the first flat gear (307) is meshed with the second flat gear (3011), the first flat gear (307) drives the second flat gear (3011) to rotate; when the first flat gear (307) is not meshed with the second flat gear (3011), the first flat gear (307) does not drive the second flat gear (3011) to rotate.

4. The pressure type electromagnetic radiation protection textile fabric surface fluff treatment and gluing equipment as claimed in claim 1, wherein an upward opening is respectively arranged on two sides of the first sliding rail (3) and the second sliding rail (4).

5. The pressure electromagnetic radiation protection textile fabric surface fluff treatment and gluing device according to claim 1, characterized in that two sides of the first electric sliding rail (5) are respectively provided with an opening which is opened downwards, and the opening close to one side of the first electric push rod (7) is provided with two spring blocks.

6. The pressure type electromagnetic radiation protection textile fabric surface fluff treatment and gluing equipment according to claim 1, characterized in that two sides of the second electric sliding rail (6) are respectively provided with an opening which is opened downwards, and the opening close to one side of the second electric push rod (8) is provided with two spring blocks.

7. The pressure type electromagnetic radiation protection textile fabric surface fluff treatment and gluing equipment as claimed in claim 1, characterized in that a plurality of groups of needling devices are arranged under the cutter (9) at equal intervals, and two sides of the cutter (9) are respectively provided with an electric sliding block.

8. A pressure-type electromagnetic radiation protection textile fabric surface fluff treatment and gluing device as claimed in claim 3, characterized in that the deflector (3022015) is arranged at the opening below the glue storage tank (3022012) in a thirty-degree inclined state.

Technical Field

The invention relates to the field of electromagnetic radiation protection, in particular to a pressure type electromagnetic radiation protection textile fabric surface fluff treatment gluing device.

Background

Present electromagnetic radiation protection textile fabric viscose coating, glue easily with textile fabric surface fine hair adhesion during the coating, make textile fabric surface adhesion's glue less, make adhesion dynamics greatly reduced, protection quality receives the influence, and textile fabric surface fine hair also can entangle and form the hair group together, hinder the coating of glue, and glue is blocked by fine hair and can lead to glue to flow everywhere, when pasting other articles, the glue on textile fabric surface receives the extrusion and can spill over, make glue coating scope receive the influence, cause the radiation protection effect to worsen.

To sum up, the pressure induction type electromagnetic radiation protection textile fabric fluff treatment gluing equipment is needed to solve the problems.

Disclosure of Invention

In order to overcome the defects that the existing electromagnetic radiation protection textile fabric viscose is coated, glue is easy to adhere to fluff on the surface of the textile fabric during coating, the glue adhered to the surface of the textile fabric is less, the adhesion strength is greatly reduced, the protection quality is influenced, the fluff on the surface of the textile fabric can be entangled to form a fluff lump, the coating of the glue is hindered, the glue is blocked by the fluff to cause the glue to flow everywhere, when other objects are pasted, the glue on the surface of the textile fabric is extruded to overflow, the glue coating range is influenced, and the radiation protection effect is poor, the invention has the technical problems that: provides a pressure type electromagnetic radiation protection textile fabric surface fluff treatment gluing device.

The technical scheme is as follows: a pressure type electromagnetic radiation protection textile fabric surface fluff treatment gluing device comprises a support frame, a controller, a first sliding rail, a second sliding rail, a first electric sliding rail, a second electric sliding rail, a first electric push rod, a second electric push rod, a cutter and a supporting plate; the support frame is fixedly connected with the controller; the support frame is fixedly connected with the first sliding rail and the second sliding rail; the support frame is fixedly connected with the first electric slide rail and the second electric slide rail; the first electric sliding rail is fixedly connected with the first electric push rod; the second electric slide rail is fixedly connected with the second electric push rod; the first electric slide rail and the second electric slide rail are fixedly connected with the supporting plate; the supporting frame is provided with a lifting mechanism; the lifting mechanism is rotationally connected with the first electric sliding rail and the second electric sliding rail; the lifting mechanism can prepare for the textile fabric except the surface pilling; a gluing mechanism is arranged on the supporting frame; the glue coating mechanism can coat glue on the textile fabric without pilling.

In addition, it is particularly preferable that the lifting mechanism comprises a first motor, a first driving wheel, a second driving wheel, a first screw rod, a third driving wheel, a moving rod, a first wedge block, a first polish rod, a first electromagnet, a second electromagnet, a fourth driving wheel, a second screw rod, a fifth driving wheel, a sixth driving wheel, a first lifting frame, a second polish rod, a third screw rod, a second lifting frame and a third polish rod; the first motor is fixedly connected with the support frame; the first motor is fixedly connected with the inner axle center of the first driving wheel; the outer ring surface of the first driving wheel is in transmission connection with the second driving wheel through a belt; the inner axle center of the second driving wheel is fixedly connected with the first screw rod through a shaft sleeve; the first screw rod is fixedly connected with the inner axle center of the third driving wheel through a shaft sleeve; the first screw rod is rotatably connected with the first electric slide rail; the first screw rod is rotatably connected with the support frame; the first screw rod is connected with the movable rod in a rotating mode; the outer ring surface of the third driving wheel is in transmission connection with the fourth driving wheel through a belt; the movable rod is fixedly connected with the first wedge-shaped block; the movable rod is in sliding connection with the first polish rod; one side of the movable rod is fixedly connected with the first electromagnet; the other side of the movable rod is fixedly connected with the second electromagnet; the first polish rod is fixedly connected with the support frame; the first polish rod is fixedly connected with the second electric slide rail; the inner axle center of the fourth driving wheel is fixedly connected with the second screw rod through a shaft sleeve; the second screw rod is fixedly connected with the inner axle center of the fifth driving wheel through a shaft sleeve; the second screw rod is rotatably connected with the first electric slide rail; the second screw rod is connected with the first lifting frame in a screwing way; the second screw rod is rotatably connected with the support frame; the outer ring surface of the fifth driving wheel is in transmission connection with the sixth driving wheel through a belt; the inner axle center of the sixth driving wheel is fixedly connected with the third screw rod through a shaft sleeve; the first lifting frame is in sliding connection with the second polished rod; the first lifting frame is in contact with the cutter; the second polished rod is fixedly connected with the first electric slide rail; the second polish rod is fixedly connected with the support frame; the third screw rod is rotatably connected with the second electric slide rail; the third screw rod is connected with the second lifting frame in a screwing way; the third screw rod is rotatably connected with the support frame; the second lifting frame is in sliding connection with the third polish rod; the third polished rod is fixedly connected with the second electric slide rail; the third polish rod is fixedly connected with the support frame.

In addition, it is particularly preferable that the glue coating includes a second motor, a first transmission rod, a first bevel gear, a second transmission rod, a first column gear, a first flat gear, a third transmission rod, a second wedge-shaped block, a third wedge-shaped block, a second flat gear, a fourth transmission rod, a seventh transmission wheel, an eighth transmission wheel, a fifth transmission rod, a third bevel gear, a fourth bevel gear, a sixth transmission rod, a ninth transmission wheel, a tenth transmission wheel, a fourth screw rod, a glue applicator, a fourth polish rod, a roller, a protective frame, a telescopic block, a first spring, a second spring, a fixed frame, a first rack, a second column gear, a first rack rod, a second rack rod, a glue storage tank, a rotating plate, a rotating rod, a guide plate and a brush; the second motor is fixedly connected with the support frame; the second motor is fixedly connected with the first transmission rod; the first transmission rod is rotatably connected with the support frame through a bracket; the first transmission rod is fixedly connected with the inner axis of the first bevel gear; the first bevel gear is meshed with the second bevel gear; the inner axis of the second bevel gear is fixedly connected with a second transmission rod; the second transmission rod is rotatably connected with the support frame through a bracket; the second transmission rod is fixedly connected with the inner axle center of the first column gear; the first column gear is meshed with the first flat gear; the inner axle center of the first flat gear is fixedly connected with the third transmission rod; a second flat gear is arranged on one side of the first flat gear; the third transmission rod is rotatably connected with the support frame through a bracket; the third transmission rod is rotatably connected with the second wedge-shaped block; the second wedge block is contacted with the third wedge block; the second wedge-shaped block and the third wedge-shaped block are in sliding connection with the support frame through the base sliding groove; the inner axle center of the second flat gear is fixedly connected with a fourth transmission rod; the fourth transmission rod is rotatably connected with the support frame through a bracket; the fourth transmission rod is fixedly connected with the inner axle center of the seventh transmission wheel; the outer ring surface of the seventh driving wheel is in transmission connection with the eighth driving wheel through a belt; the inner axle center of the eighth driving wheel is fixedly connected with the fifth driving rod; the fifth transmission rod is rotatably connected with the support frame through a bracket; the fifth transmission rod is fixedly connected with the inner axle center of the third bevel gear; the third bevel gear is meshed with the fourth bevel gear; the inner axis of the fourth bevel gear is fixedly connected with a sixth transmission rod; the sixth transmission rod is rotatably connected with the support frame through a bracket; the sixth transmission rod is fixedly connected with the inner axle center of the ninth transmission wheel; the sixth transmission rod is fixedly connected with the fifth screw rod; the outer ring surface of the ninth driving wheel is in transmission connection with the tenth driving wheel through a belt; the inner axis of the tenth transmission wheel is fixedly connected with the fourth screw rod through a shaft sleeve; the fourth screw rod is connected with the glue applicator in a rotating mode; the fourth screw rod is rotatably connected with the support frame through a shaft sleeve; the glue applicator is in sliding connection with the fourth polish rod; the fourth polish rod is fixedly connected with the support frame through a bracket; the roller is rotationally connected with the protective frame through a bracket; the protective frame is fixedly connected with the telescopic block through a bracket; the telescopic block is fixedly connected with the first rack and the second rack; the telescopic block is fixedly connected with the first spring and the second spring; the first spring and the second spring are fixedly connected with the fixed frame; the fixed frame is fixedly connected with the glue storage groove; the first rack and the second rack are meshed with the second column gear; the second column gear is meshed with the first gear rack and the second gear rack; the second column gear is rotationally connected with the fixed frame through a rotating rod; one sides of the first toothed bar and the second toothed bar are in sliding connection with the glue storage groove through the sliding groove; the other sides of the first rack bar and the second rack bar are rotationally connected with the rotating plate through a bracket; the two sides of the glue storage tank are respectively provided with a combination of a roller, a protective frame, a telescopic block, a first spring, a second spring, a fixed frame, a first rack, a second column gear, a first rack bar and a second rack bar; the glue storage tank is fixedly connected with the rotating rod; the glue storage tank is fixedly connected with the guide plate through a bracket; the rotating rod is in rotating connection with the rotating plate; the guide plate is fixedly connected with the brush through a bracket; when the first flat gear is meshed with the second flat gear, the first flat gear drives the second flat gear to rotate; when the first flat gear is not meshed with the second flat gear, the first flat gear does not drive the second flat gear to rotate.

In addition, it is particularly preferred that one opening is provided on each of both sides of the first slide rail and the second slide rail.

In addition, it is particularly preferred that the first electrical sliding rail has an opening facing downwards on both sides, and the opening on the side close to the first electrical push rod is provided with two spring blocks.

Furthermore, it is particularly preferred that the second electrical rail has an opening facing downwards on both sides, and the opening on the side close to the second electrical push rod is provided with two spring blocks.

In addition, it is particularly preferred that a plurality of groups of the needle prickers are arranged at equal intervals below the cutter, and two electric sliders are arranged on two sides of the cutter respectively.

In addition, it is especially preferred that the guide plate is arranged at the opening below the glue storage tank in a thirty-degree inclined state.

The invention has the advantages that: one, for solving present electromagnetic radiation protection textile fabric viscose coating, glue is easy and textile fabric surface fine hair adhesion during the coating, make textile fabric surface adhesion's glue less, make adhesion dynamics greatly reduced, protection quality receives the influence, and textile fabric surface fine hair also can entangle and form the hair group together, hinder the coating of glue, and glue is blocked by fine hair and can lead to glue to flow everywhere, when pasting other articles, the glue on textile fabric surface receives the extrusion and can spill over, make glue coating scope receive the influence, cause the problem of radiation protection effect variation.

Secondly, a lifting mechanism, a gluing mechanism and a conveying mechanism are designed; when in use, the supporting frame is horizontally placed, then the power supply is externally connected, the controller controls the device to operate, then the textile fabric is manually placed on the supporting plate, glue is poured into the glue storage groove, then the first motor is started to drive the lifting mechanism to operate, the cutter is moved upwards to the downward gap of the first electric sliding rail and the second electric sliding rail through the first lifting frame and the second lifting frame, then the first electric push rod and the second electric push rod are controlled to be started to push the cutter into the first electric sliding rail and the second electric sliding rail, the cutter is driven to operate on the textile fabric through the first electric sliding rail and the second electric sliding rail, fluff on the surface of the textile fabric and fluff wound on the surface of the textile fabric are cut and combed to be flat, then the first electromagnet and the second electromagnet suck the cutter, and the cutter is driven to move downwards through the moving rod until the first wedge-shaped block is contacted with the second wedge-shaped block, so that the first flat gear is meshed with the second flat gear, and then, a second motor is started to drive the gluing mechanism to operate, during gluing, the gluing device is controlled to move towards the direction of the supporting plate, so that the roller rolls on the textile fabric, the deflection of the rotating plate is controlled by the extrusion acting force of the roller on the textile fabric, glue is guided to the textile fabric from the deflected rotating plate through the guide plate through the lower opening of the glue storage groove, then the glue is coated on the textile fabric through the brush, the glue is in surface contact with the textile fabric, meanwhile, the cutter is pushed to move on the first sliding rail and the second sliding rail through the conveying mechanism until the cutter returns to the positions of the first lifting frame and the second lifting frame, and finally, the glued textile fabric is taken away through an external device and is subjected to next treatment.

The method realizes the treatment of entangled fluff on the surface of the textile fabric, and the fluff on the surface of the textile fabric is carded and leveled during gluing, so that the glue is in close contact with the surface of the textile fabric, the adhesion strength of the glue and the textile fabric is increased, the coating range of the glue is controlled, and the glue cannot overflow when other objects are stuck and pressed on the textile fabric.

Drawings

FIG. 1 is a schematic perspective view of a first embodiment of the present invention;

FIG. 2 is a schematic perspective view of a second embodiment of the present invention;

FIG. 3 is a schematic view of the first sliding track and the first electric putter combination according to the present invention;

FIG. 4 is a perspective view of the cutter of the present invention;

FIG. 5 is a perspective view of the lancet brush of the present invention;

FIG. 6 is a schematic perspective view of a first embodiment of the lifting mechanism of the present invention;

FIG. 7 is a schematic diagram of a second three-dimensional structure of the lifting mechanism of the present invention;

FIG. 8 is a top view of the lift mechanism of the present invention;

FIG. 9 is a schematic view of a first three-dimensional structure of the glue applying mechanism of the present invention;

FIG. 10 is a schematic perspective view of a second glue applying mechanism according to the present invention;

FIG. 11 is a schematic view of a partial perspective structure of the glue application mechanism of the present invention;

FIG. 12 is a front view of the glue mechanism of the present invention;

FIG. 13 is a schematic perspective view of a first embodiment of the applicator of the present invention;

FIG. 14 is a schematic perspective view of a second embodiment of the applicator of the present invention;

FIG. 15 is a schematic view of a partial perspective view of the applicator of the present invention;

FIG. 16 is a schematic perspective view of a glue storage tank according to the present invention;

FIG. 17 is a perspective view of the combination of a rotating plate and a rotating lever according to the present invention;

FIG. 18 is a schematic perspective view of a first embodiment of the transport mechanism of the present invention;

FIG. 19 is a schematic perspective view of a second embodiment of the transport mechanism of the present invention;

fig. 20 is a bottom view of the transport mechanism of the present invention.

In the figure: 1. a support frame, 2, a controller, 3, a first sliding track, 4, a second sliding track, 5, a first electric sliding rail, 6, a second electric sliding rail, 7, a first electric push rod, 8, a second electric push rod, 9, a cutter, 10, a support plate, 201, a first motor, 202, a first driving wheel, 203, a second driving wheel, 204, a first screw rod, 205, a third driving wheel, 206, a moving rod, 207, a first wedge block, 208, a first polished rod, 209, a first electromagnet, 2010, a second electromagnet, 2011, a fourth driving wheel, 2012, a second screw rod, 2013, a fifth driving wheel, 2014, a sixth driving wheel, 2015, a first lifting frame, 2016, a second polished rod, 2017, a third screw rod, 2018, a second lifting frame, 2019, a third polished rod, 301, a second motor, 302, a first driving rod, 303, a first bevel gear, 304, a second bevel gear, 305, a second driving rod, 306, A first column gear 307, a first flat gear, 308, a third transmission rod, 309, a second wedge block, 3010, a third wedge block, 3011, a second flat gear, 3012, a fourth transmission rod, 3013, a seventh transmission wheel, 3014, an eighth transmission wheel, 3015, a fifth transmission rod, 3016, a third bevel gear, 3017, a fourth bevel gear, 3018, a sixth transmission rod, 3019, a ninth transmission wheel, 3020, a tenth transmission wheel, 3021, a fourth screw, 3022, a glue applicator, 3023, a fourth polish rod, 302201, a roller, 302202, a guard frame, 302203, a telescopic block, 302204, a first spring, 302205, a second spring, 302206, a fixed frame, 302207, a first rack, 302208, a second rack, 302209, a second column gear, 3022010, a first toothed bar, 3022011, a second toothed bar, 3022012, a glue storage tank, 3022013, a rotating plate, 3022014, a rotating rod, a second rack, a 3022016, a fifth guide rod, a guide plate, a 35403, a fifth guide rod, a brush 401, a third wedge block, 3011, a fourth transmission rod, 3019, a fourth transmission rod, 901. a needle brush.

Detailed Description

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

Examples

A pressure type electromagnetic radiation protection textile fabric surface fluff treatment gluing device is shown in figures 1-5 and comprises a support frame 1, a controller 2, a first sliding rail 3, a second sliding rail 4, a first electric sliding rail 5, a second electric sliding rail 6, a first electric push rod 7, a second electric push rod 8, a cutter 9 and a supporting plate 10; the support frame 1 is fixedly connected with the controller 2; the support frame 1 is fixedly connected with the first sliding track 3 and the second sliding track 4; the support frame 1 is fixedly connected with the first electric slide rail 5 and the second electric slide rail 6; the first electric slide rail 5 is fixedly connected with a first electric push rod 7; the second electric slide rail 6 is fixedly connected with a second electric push rod 8; the first electric slide rail 5 and the second electric slide rail 6 are fixedly connected with the supporting plate 10; the supporting frame 1 is provided with a lifting mechanism; the lifting mechanism is rotationally connected with the first electric slide rail 5 and the second electric slide rail 6; the lifting mechanism can prepare for the textile fabric except the surface pilling; a gluing mechanism is arranged on the support frame 1; the glue coating mechanism can coat glue on the textile fabric without pilling.

When in use, the support frame 1 is horizontally placed, then an external power supply is connected, the controller 2 controls the device to operate, then the textile fabric is manually placed on the support plate 10, glue is poured into the glue storage groove 3022012, then the first motor 201 is started to drive the lifting mechanism to operate, the cutter 9 is moved upwards to the downward notches of the first electric slide rail 5 and the second electric slide rail 6 through the first lifting frame 2015 and the second lifting frame 2018, then the first electric push rod 7 and the second electric push rod 8 are controlled to be started to push the cutter 9 into the first electric slide rail 5 and the second electric slide rail 6, the cutter 9 is driven to operate on the textile fabric through the first electric slide rail 5 and the second electric slide rail 6, fluff on the surface of the textile fabric and the fluff wound on the surface are cut and combed to be flat, then the cutter 9 is sucked by the first electromagnet 209 and the second electromagnet 2010 and is driven to move downwards through the moving rod 206 until the first wedge-shaped block 207 is contacted with the second wedge-shaped block 309, the first spur gear 307 is meshed with the second spur gear 3011, then the second motor 301 is started to drive the glue coating mechanism to run, when coating glue, the glue applicator 3022 is controlled to move towards the support plate 10, the roller 302201 rolls on the textile fabric, the deflection of the rotating plate 3022013 is controlled by the extrusion force of the roller 302201 on the textile fabric, so that glue is drained from the deflected rotating plate 3022013 to the textile fabric through the guide plate 3022015 through the opening below the glue storage 3022012, then the glue is coated on the textile fabric through the brush 3022016, so that the glue is in contact with the surface of the textile fabric, meanwhile, the cutter 9 is pushed by the conveying mechanism to move on the first sliding rail 3 and the second sliding rail 4 until the cutter 9 returns to the positions of the first crane 2015 and the second crane 2018, and finally the coated textile fabric is taken away by an external device and is processed in the next step; the method realizes the treatment of entangled fluff on the surface of the textile fabric, and the fluff on the surface of the textile fabric is carded and leveled during gluing, so that the glue is in close contact with the surface of the textile fabric, the adhesion strength of the glue and the textile fabric is increased, the coating range of the glue is controlled, and the glue cannot overflow when other objects are stuck and pressed on the textile fabric.

Referring to fig. 6-8, the lifting mechanism includes a first motor 201, a first driving wheel 202, a second driving wheel 203, a first screw 204, a third driving wheel 205, a moving rod 206, a first wedge block 207, a first polished rod 208, a first electromagnet 209, a second electromagnet 2010, a fourth driving wheel 2011, a second screw 2012, a fifth driving wheel 2013, a sixth driving wheel 2014, a first crane 2015, a second polished rod 2016, a third screw 2017, a second crane 2018 and a third polished rod 2019; the first motor 201 is fixedly connected with the support frame 1; the first motor 201 is fixedly connected with the inner axis of the first driving wheel 202; the outer ring surface of the first transmission wheel 202 is in transmission connection with a second transmission wheel 203 through a belt; the inner axle center of the second transmission wheel 203 is fixedly connected with the first screw rod 204 through a shaft sleeve; the first screw rod 204 is fixedly connected with the inner axle center of the third driving wheel 205 through a shaft sleeve; the first lead screw 204 is rotatably connected with the first electric slide rail 5; the first screw rod 204 is rotatably connected with the support frame 1; the first screw 204 is screwed with the movable rod 206; the outer annular surface of the third transmission wheel 205 is in transmission connection with a fourth transmission wheel 2011 through a belt; the movable rod 206 is fixedly connected with a first wedge block 207; the movable rod 206 is connected with the first polished rod 208 in a sliding way; one side of the movable rod 206 is fixedly connected with the first electromagnet 209; the other side of the movable rod 206 is fixedly connected with a second electromagnet 2010; the first polish rod 208 is fixedly connected with the support frame 1; the first polish rod 208 is fixedly connected with the second electric slide rail 6; the inner axis of the fourth transmission wheel 2011 is fixedly connected with the second lead screw 2012 through a shaft sleeve; the second screw rod 2012 is fixedly connected with the inner axle center of the fifth driving wheel 2013 through a shaft sleeve; the second screw rod 2012 is rotatably connected with the first electric slide rail 5; the second screw rod 2012 is connected with the first lifting frame 2015 in a screwing manner; the second screw rod 2012 is rotatably connected with the support frame 1; the outer annular surface of the fifth driving wheel 2013 is in transmission connection with the sixth driving wheel 2014 through a belt; the inner axle center of the sixth driving wheel 2014 is fixedly connected with a third screw rod 2017 through a shaft sleeve; the first lifting frame 2015 is in sliding connection with the second polish rod 2016; the first crane 2015 is in contact with the cutter 9; the second polish rod 2016 is fixedly connected with the first electric slide rail 5; the second polish rod 2016 is fixedly connected with the support frame 1; the third screw rod 2017 is rotatably connected with the second electric slide rail 6; the third screw rod 2017 is in screwed connection with the second lifting frame 2018; the third screw rod 2017 is rotatably connected with the support frame 1; the second lifting frame 2018 is in sliding connection with the third polished rod 2019; the third polished rod 2019 is fixedly connected with the second electric slide rail 6; the third polish rod 2019 is fixedly connected with the support frame 1.

At the beginning, the textile fabric is manually placed on the supporting plate 10, glue is poured into the glue storage tank 3022012, then the first motor 201 is started to drive the first driving wheel 202 to rotate, further the outer ring surface of the first driving wheel 202 drives the second driving wheel 203 to rotate through a belt, further the second driving wheel 203 drives the first lead screw 204 to rotate, further the first lead screw 204 drives the third driving wheel 205 to rotate, further the outer ring surface of the third driving wheel 205 drives the fourth driving wheel 2011 to rotate through a belt, further the fourth driving wheel 2011 drives the second lead screw 2012 to rotate, further the second lead screw 2012 drives the first lifting frame 2015 to slide upwards on the second polish rod 2016, simultaneously the second lead screw 2012 drives the fifth driving wheel 2013 to rotate, further the outer ring surface of the fifth driving wheel 2013 drives the sixth driving wheel 2014 to rotate through a belt, further the sixth driving wheel 2014 drives the third lead screw 2017 to drive the second lifting frame 2018 to slide upwards on the third polish rod 2019, then the first crane 2015 and the second crane 2018 simultaneously drive the cutter 9 to move upwards to the downward notches of the first electric slide rail 5 and the second electric slide rail 6, and the cutter 9 is driven by the first crane 2015 and the second crane 2018 to stay in front of the first electric push rod 7 and the second electric push rod 8 through the spring blocks at the notches of the first electric slide rail 5 and the second electric slide rail 6, meanwhile, the first screw 204 drives the moving rod 206 to move upwards on the first polished rod 208, the moving rod 206 drives the first wedge-shaped block 207, the first electromagnet 209 and the second electromagnet 2010 to move upwards, the first electromagnet 209 and the second electromagnet 2010 are driven to move to the notches at the relative positions of the first electric slide rail 5 and the second electric slide rail 6, then the first electric push rod 7 and the second electric push rod 8 are started to drive the cutter 9, so that the cutter 9 entangles fluff on the surface of the textile fabric through the needle brush 901 to perform cutting and carding treatment, and finally the cutter 9 is driven by the first motor 201 to move downwards through the first electromagnet 2010 and the reverse rotation of the cutter 9 Moving to the gap of the first sliding track 3 and the second sliding track 4, and at this time, the first wedge block 207 extrudes the third wedge block 3010; the mechanism finishes the cutting and combing of the entangled fluff on the surface of the textile fabric.

Referring to fig. 9-17, the glue coating includes a second motor 301, a first transmission rod 302, a first bevel gear 303, a second bevel gear 304, a second transmission rod 305, a first column gear 306, a first flat gear 307, a third transmission rod 308, a second wedge block 309, a third wedge block 3010, a second flat gear 3011, a fourth transmission rod 3012, a seventh transmission wheel 3013, an eighth transmission wheel 3014, a fifth transmission rod 3015, a third bevel gear 3016, a fourth bevel gear 3017, a sixth transmission rod 3018, a ninth transmission wheel 3019, a tenth driving wheel 3020, a fourth screw rod 3021, a glue applicator 3022, a fourth polished rod 3023, a roller 302201, a protective frame 302202, a telescopic block 302203, a first spring 302204, a second spring 302205, a fixed frame 302206, a first rack 302207, a second rack 302208, a second rack 302209, a first rack 3022010, a second rack 3022011, a glue storage tank 3022012, a rotating plate 3022013, a rotating rod 3022014, a guide plate 3022015, and a brush 3022016; the second motor 301 is fixedly connected with the support frame 1; the second motor 301 is fixedly connected with the first transmission rod 302; the first transmission rod 302 is rotatably connected with the support frame 1 through a bracket; the first transmission rod 302 is fixedly connected with the inner axis of the first bevel gear 303; the first bevel gear 303 meshes with the second bevel gear 304; the inner axis of the second bevel gear 304 is fixedly connected with a second transmission rod 305; the second transmission rod 305 is rotatably connected with the support frame 1 through a bracket; the second transmission rod 305 is fixedly connected with the inner axis of the first cylindrical gear 306; the first column gear 306 meshes with the first flat gear 307; the inner axis of the first flat gear 307 is fixedly connected with the third transmission rod 308; a second flat gear 3011 is arranged on one side of the first flat gear 307; the third transmission rod 308 is rotatably connected with the support frame 1 through a bracket; the third driving rod 308 is rotatably connected with the second wedge block 309; second wedge 309 is in contact with third wedge 3010; the second wedge block 309 and the third wedge block 3010 are connected with the support frame 1 in a sliding manner through a base sliding chute; the axle center in the second flat gear 3011 is fixedly connected with the fourth transmission rod 3012; the fourth transmission rod 3012 is rotatably connected with the support frame 1 through a bracket; the fourth transmission rod 3012 is fixedly connected with the inner axis of the seventh transmission wheel 3013; the outer ring surface of the seventh driving wheel 3013 is in transmission connection with the eighth driving wheel 3014 through a belt; the axle center inside the eighth driving wheel 3014 is fixedly connected with the fifth driving rod 3015; the fifth transmission rod 3015 is rotatably connected with the support frame 1 through a bracket; the fifth transmission rod 3015 is fixedly connected with the inner axis of the third bevel gear 3016; third bevel gear 3016 meshes with fourth bevel gear 3017; the axis inside the fourth bevel gear 3017 is fixedly connected with a sixth transmission rod 3018; the sixth transmission rod 3018 is rotatably connected with the support frame 1 through a bracket; the sixth transmission rod 3018 is fixedly connected with the inner axis of the ninth transmission wheel 3019; the sixth transmission rod 3018 is fixedly connected to the fifth screw 401; the outer ring surface of the ninth driving wheel 3019 is in transmission connection with a tenth driving wheel 3020 through a belt; the inner axis of the tenth driving wheel 3020 is fixedly connected with the fourth screw rod 3021 through a shaft sleeve; the fourth screw rod 3021 is screwed with the glue applicator 3022; the fourth screw rod 3021 is rotatably connected with the support frame 1 through a shaft sleeve; the glue applicator 3022 is slidably connected to the fourth polish rod 3023; the fourth polish rod 3023 is fixedly connected with the support frame 1 through a bracket; the roller 302201 is rotatably connected with the protective frame 302202 through a bracket; the protective frame 302202 is fixedly connected with the telescopic block 302203 through a bracket; the telescopic block 302203 is fixedly connected with the first rack 302207 and the second rack 302208; the telescopic block 302203 is fixedly connected with the first spring 302204 and the second spring 302205; the first spring 302204 and the second spring 302205 are fixedly connected with the fixing frame 302206; the fixing frame 302206 is fixedly connected with the glue storage groove 3022012; the first rack 302207 and the second rack 302208 are both engaged with the second column gear 302209; the second column gear 302209 meshes with both the first rack bar 3022010 and the second rack bar 3022011; the second column gear 302209 is rotationally connected with the fixed frame 302206 through a rotating rod; one sides of the first toothed bar 3022010 and the second toothed bar 3022011 are in sliding connection with the glue storage tank 3022012 through sliding grooves; the other sides of the first gear lever 3022010 and the second gear lever 3022011 are rotatably connected with the rotating plate 3022013 through a bracket; the two sides of the glue storage tank 3022012 are respectively provided with a combination of a roller 302201, a protective frame 302202, a telescopic block 302203, a first spring 302204, a second spring 302205, a fixed frame 302206, a first rack 302207, a second rack 302208, a second rack 302209, a first rack 3022010 and a second rack 3022011; the glue storage tank 3022012 is fixedly connected with a rotary rod 3022014; the glue storage tank 3022012 is fixedly connected with the diversion plate 3022015 through a bracket; the rotating rod 3022014 is rotatably connected with the rotating plate 3022013; the guide plate 3022015 is fixedly connected with the brush 3022016 through a bracket; when the first flat gear 307 is meshed with the second flat gear 3011, the first flat gear 307 drives the second flat gear 3011 to rotate; when the first flat gear 307 is not meshed with the second flat gear 3011, the first flat gear 307 does not rotate the second flat gear 3011.

When the first wedge block 207 presses the third wedge block 3010, the third wedge block 3010 is pressed to move and also presses the second wedge block 309, so that the second wedge block 309 moves upward under the restriction of the fixed base, so that the first flat gear 307 is engaged with the second flat gear 3011, then the second motor 301 is started to drive the first transmission rod 302 to rotate, further the first transmission rod 302 drives the first bevel gear 303 to rotate, further the first bevel gear 303 drives the second bevel gear 304 to rotate, further the second bevel gear 304 drives the second transmission rod 305 to rotate, further the second transmission rod 305 drives the first column gear 306 to rotate, further the first column gear 306 drives the first flat gear 307 to rotate, further the first flat gear 307 drives the second flat gear 3011 to rotate, further the second flat gear 3011 drives the fourth transmission rod 3012 to rotate, further the fourth transmission rod 3012 drives the seventh transmission wheel 3013 to rotate, then the outer ring surface of the seventh driving wheel 3013 drives the eighth driving wheel 3014 to rotate through the belt, and further the fifth driving rod 3015 drives the third bevel gear 3016 to rotate, and further the third bevel gear 3016 drives the fourth bevel gear 3017 to rotate, and then the fourth bevel gear 3017 drives the sixth driving rod 3018 to rotate, and further the sixth driving rod 3018 drives the ninth driving wheel 3019 to rotate, and further the outer ring surface of the ninth driving wheel 3019 drives the tenth driving wheel 3020 to rotate through the belt, and further the tenth driving wheel 3020 drives the fourth lead screw 3021 to rotate, and then the fourth lead screw 3021 drives the glue applicator 3022 to move on the fourth polished rod 3023 towards the supporting plate 10, when the glue applicator 3022 moves on the textile fabric, due to the pressing force of the roller 302201, the roller 302201 drives the protective frame 302202 and the telescopic block 302203 to move upwards and cause pressing of the first spring 302204 and the second spring 302205, and further the telescopic block 302203 drives the first rack 302207 and the second rack 302208 to move upwards, the first rack 302207 and the second rack 302208 drive the second rack 302209 to rotate, and then the second rack 302209 drives the first rack 3022010 and the second rack 3022011 to move upwards through the chute, so that the first rack 3022010 and the second rack 3022011 drive the rotating plate 3022013 to deflect downwards, so that the glue in the glue storage tank 3022012 flows onto the guide plate 3022015 through the lower opening and flows onto the textile fabric through the guide plate 3022015, and meanwhile, the brush 3022016 coats the glue on the surface of the textile fabric, so that the glue is coated on the surface of the textile fabric; meanwhile, the sixth transmission rod 3018 drives the fifth screw 401 to rotate, so that the conveying mechanism starts to operate; the mechanism finishes the smearing of the textile fabric glue.

Referring to fig. 18-20, the device further comprises a transport mechanism, wherein the transport mechanism comprises a fifth screw 401, a push rod 402 and a fifth polish rod 403; the fifth screw 401 is fixedly connected with a sixth transmission rod 3018 through a shaft sleeve; the fifth screw 401 is rotatably connected with the support frame 1 through a bracket; the fifth screw 401 is in screwed connection with the push rod 402; the push rod 402 is in sliding connection with the fifth polish rod 403; the fifth polish rod 403 is fixedly connected with the support frame 1 through a bracket.

The sixth transmission rod 3018 drives the fifth screw 401 to rotate, and then the fifth screw 401 drives the push rod 402 to move on the fifth polished rod 403 towards the first crane 2015 direction, so that the push rod 402 pushes the cutter 9 to move on the first sliding track 3 and the second sliding track 4 towards the first crane 2015 direction, and finally the cutter 9 is moved to the first crane 2015 and the second crane 2018; this mechanism completes the reset operation of the cutter 9.

Two sides of the first sliding track 3 and the second sliding track 4 are respectively provided with an upward opening.

The cutter 9 can be made to move on the first slide rail 3 and the second slide rail 4 without hindrance.

Two sides of the first electric slide rail 5 are respectively provided with an opening which is opened downwards, and the opening close to one side of the first electric push rod 7 is provided with two spring blocks.

The cutter 9 can be made to freely move in and out of the first electrical slide 5.

Two sides of the second electric slide rail 6 are respectively provided with an opening which is opened downwards, and the opening close to one side of the second electric push rod 8 is provided with two spring blocks.

The cutter 9 can be made to freely move in and out of the second electrical slide 6.

A plurality of groups of acupuncture devices are arranged at equal intervals below the cutter 9, and two sides of the cutter 9 are respectively provided with an electric slide block.

The textile fabric surface can be cut by pilling, and the electric sliding block can enable the cutter 9 to move in the first electric sliding rail 5 and the second electric sliding rail 6.

The guide plate 3022015 is arranged at an opening below the glue storage tank 3022012 in a thirty-degree inclined state.

The viscose can be made to flow down rapidly.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by the present specification, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.