阅读说明：本技术 均压式医用外敷材料点状涂胶机 (Pressure equalizing type medical external application material point-like glue spreader ) 是由 吴海潮 于 2021-09-22 设计创作，主要内容包括：本发明涉及医用材料加工领域,尤其涉及一种均压式医用外敷材料点状涂胶机。本发明要解决的技术问题为：对无纺布进行撕扯的过程中极易出现点状胶脱落的缺点。本发明的技术实施方案是：一种均压式医用外敷材料点状涂胶机,包括有机架、底板和顶罩等；机架上方固定连接有底板；底板上方固定连接有顶罩。本发明设计的贴合系统对医用的外敷材料进行点状涂胶,利用胶液转移的方式进行生产制造,利用单条挤压的方式将无纺布局部嵌合复合的带孔涂胶转移材料,对无纺布整块地向上进行抬起,避免了撕扯式分离方式会出现点状胶脱落的现象发生。(The invention relates to the field of medical material processing, in particular to a uniform pressure type medical external application material point-like glue spreader. The technical problem to be solved by the invention is as follows: the disadvantage that the point glue is easy to fall off in the process of tearing the non-woven fabric is easily caused. The technical implementation scheme of the invention is as follows: a pressure equalizing type medical external application material punctiform glue spreader comprises a frame, a bottom plate, a top cover and the like; a bottom plate is fixedly connected above the rack; a top cover is fixedly connected above the bottom plate. The gluing system designed by the invention carries out point gluing on the medical external application material, the production and the manufacture are carried out by using a glue solution transfer mode, the perforated gluing transfer material which is locally embedded and compounded with the non-woven fabric is lifted up integrally by using a single extrusion mode, and the phenomenon that the point glue falls off in a tearing and pulling type separation mode is avoided.)

1. A pressure equalizing type medical external application material punctiform glue spreader, which comprises a frame (2), a bottom plate (4) and a first supporting frame (5); a first support frame (5) is fixedly connected to the rear part above the bottom plate (4); a bottom plate (4) is fixedly connected above the frame (2); it is characterized by also comprising a fitting system; the left rear side above the bottom plate (4) is connected with a fitting system; the first support frame (5) is connected with the fitting system;

the laminating system comprises a first servo motor (101), a first fixing frame (102), a first electric push rod (103), a grid frame (104), a clamping assembly (105), a first portal frame (106), a limiting rod (107), a moving block (108), a second electric push rod (109), a fixed beam (1010), an extrusion laminating assembly (1011) and a spring telescopic rod (1012); a first servo motor (101) is arranged at the left rear part above the bottom plate (4); a first fixing frame (102) is rotatably connected above the first supporting frame (5); an output shaft of the first servo motor (101) is fixedly connected with the first fixing frame (102); a first portal frame (106) is fixedly connected between the left side and the right side of the inner rear part of each first fixing frame (102); a first electric push rod (103) is fixedly connected to the front of the left side and the front of the right side in each first fixing frame (102); three spring telescopic rods (1012) are fixedly connected to the inner front part of each first fixing frame (102); grid frames (104) are fixedly connected to the moving end parts of the four first electric push rods (103); two clamping assemblies (105) are arranged on the left side and the right side of the grid frame (104); three spring telescopic rods (1012) are fixedly connected to the upper side and the lower side of the front of the grid frame (104); each first portal frame (106) is fixedly connected with a limiting rod (107); each limiting rod (107) is connected with a moving block (108) in a sliding manner; each moving block (108) is fixedly connected with a second electric push rod (109); a fixed beam (1010) is fixedly connected in front of the moving end parts of the two second electric push rods (109); five extrusion fitting assemblies (1011) are fixedly connected in front of the fixed beam (1010) at equal intervals;

the clamping assembly (105) comprises a straight sliding rail (1051), a spring rod (1052), a first sliding block (1053), a third electric push rod (1054), a clamping plate (1055) and a sliding rod (1056); a straight slide rail (1051) is fixedly connected below the right side of the grid rack (104); a sliding rod (1056) is fixedly connected above the straight sliding rail (1051); the straight slide rail (1051) is connected with a first slide block (1053) in a sliding way; a spring rod (1052) is fixedly connected to the right end part of the sliding rod (1056); the left side of the spring rod (1052) is fixedly connected with a first sliding block (1053); the first sliding block (1053) is connected with the sliding rod (1056) in a sliding way; a third electric push rod (1054) is fixedly connected above the first sliding block (1053); a clamping plate (1055) is fixedly connected with the rear side of the moving end part of the third electric push rod (1054).

2. The uniform pressure type medical external application material spot gluing machine according to claim 1, wherein the cross bars in the grid frame (104) are equidistant.

3. The uniform pressure type medical external application material spot glue spreader is characterized in that the radius of the extrusion roller in the extrusion laminating assembly (1011) is larger than the thickness of the cross beam in the middle of the grid frame (104).

4. The pressure-equalizing medical externally-applied material punctiform glue spreader of claim 3, which is characterized by further comprising a power system, wherein the power system comprises a first power motor (201), a first transmission wheel (202), a second transmission wheel (203), a screw rod (204) and a third transmission wheel (205); a first power motor (201) is fixedly connected to the left part of the first fixing frame (102); a first driving wheel (202) is fixedly connected above an output shaft of the first power motor (201); a screw rod (204) is rotatably connected below the first portal frame (106) on the right side; a screw rod (204) is rotatably connected below the first portal frame (106) on the left side; a second transmission wheel (203) is fixedly connected with the screw rod (204) on the right side; the second driving wheel (203) is a double-track wheel; a third transmission wheel (205) is fixedly connected with the screw rod (204) at the left side; the outer ring surface of the first transmission wheel (202) is in transmission connection with a second transmission wheel (203) through a belt; the outer annular surface of the second transmission wheel (203) is in transmission connection with a third transmission wheel (205) through a belt.

5. The pressure equalizing type medical external application material punctiform spreading machine according to claim 4, characterized by further comprising a second support frame (6), a third support frame (7) and a support clamping system; a second support frame (6) is arranged in the middle of the right side above the bottom plate (4); a third support frame (7) is arranged in the middle of the left side above the bottom plate (4); a supporting and clamping system is connected above the bottom plate (4); a supporting and clamping system is connected above the second supporting frame (6); a supporting and clamping system is connected above the third supporting frame (7).

6. The pressure equalizing type medical externally-applied material punctiform glue spreader of claim 5, wherein the supporting and clamping system comprises a worktable (301), a positioning block (302), a first rotating shaft (303), a first clamping plate (304), a fourth transmission wheel (305), a fifth transmission wheel (306), a first bevel gear (307), a second power motor (308), a second bevel gear (309), a third bevel gear (3010), a second rotating shaft (3011), a sixth transmission wheel (3012), a seventh transmission wheel (3013), a third rotating shaft (3014), an eighth transmission wheel (3015), a ninth transmission wheel (3016), a fourth rotating shaft (3017) and a second clamping plate (3018); a workbench (301) is arranged on the front side above the bottom plate (4); two positioning blocks (302) are respectively arranged on the front side and the rear side above the workbench (301); a first rotating shaft (303) is rotatably connected above the second supporting frame (6); a first clamping plate (304) is fixedly connected to the outer ring surface of the first rotating shaft (303); a fourth driving wheel (305) is fixedly connected to the rear part of the outer ring surface of the first rotating shaft (303); a second power motor (308) is arranged in the middle of the right side of the lower end face of the bottom plate (4); a second bevel gear (309) is fixedly connected to the right part of an output shaft of the second power motor (308); the rear side of the first bevel gear (307) is rotationally connected with the bottom plate (4) through a short rotating shaft; the first bevel gear (307) is connected with a fifth driving wheel (306) through a short rotating shaft; the outer ring surface of the fourth driving wheel (305) is in transmission connection with a fifth driving wheel (306) through a belt; a second rotating shaft (3011) is rotatably connected to the right side below the bottom plate (4); a third bevel gear (3010) and a sixth driving wheel (3012) are fixedly connected to the outer ring surface of the second rotating shaft (3011); the second bevel gear (309) is meshed with the first bevel gear (307); the second bevel gear (309) is meshed with the third bevel gear (3010); a third rotating shaft (3014) is rotatably connected to the left side below the bottom plate (4); a seventh driving wheel (3013) and an eighth driving wheel (3015) are fixedly connected to the outer ring surface of the third rotating shaft (3014); the outer ring surface of the sixth driving wheel (3012) is in transmission connection with the seventh driving wheel (3013) through a belt; a fourth rotating shaft (3017) is rotatably connected above the third supporting frame (7); a second clamping plate (3018) is fixedly connected to the outer ring surface of the fourth rotating shaft (3017); a ninth driving wheel (3016) is fixedly connected to the rear part of the outer ring surface of the fourth rotating shaft (3017); the outer ring surface of the eighth driving wheel (3015) is in transmission connection with the ninth driving wheel (3016) through a belt.

7. The pressure equalizing type spot gluing machine for medical external application material as claimed in claim 6, wherein the positioning block (302) is an L-shaped plate.

8. The pressure equalizing type spot gluing machine for medical dressing material according to claim 7, wherein the pressing plates of the first clamping plate (304) and the second clamping plate (3018) are made of rubber plates.

9. The uniform-pressure medical externally-applied material punctiform glue spreader is characterized by further comprising a flattening and righting system, wherein the flattening and righting system comprises a supporting plate (401), an electric sliding rail (402), a second sliding block (403), a second fixing frame (404), a fourth electric push rod (405), a second portal frame (406), a squeezing and pushing roller (407), a second servo motor (408), a connecting frame (409), a supporting beam (4010) and a sucking disc (4011); a supporting plate (401) is fixedly connected to the middle part of the front side of the top cover (8); an electric sliding rail (402) is fixedly connected to the rear side of the supporting plate (401); a second sliding block (403) is connected to the rear side of the electric sliding rail (402) in a sliding manner; a second fixed frame (404) is fixedly connected with the rear side of the second sliding block (403); a fourth electric push rod (405) is fixedly connected to the rear side of the second fixing frame (404); a second portal frame (406) is fixedly connected below the moving end part of the fourth electric push rod (405); a pushing roller (407) is rotatably connected to the lower part in the second portal frame (406); a second servo motor (408) is fixedly connected to the rear part of the left side of the second portal frame (406); the front side and the rear side of the left side of the second portal frame (406) are respectively and rotatably connected with a connecting frame (409); a connecting frame (409) is fixedly connected below the output shaft of the second servo motor (408); supporting beams (4010) are fixedly connected to the left sides of the two connecting frames (409); six suckers (4011) are fixedly connected to the left side of the supporting beam (4010).

Technical Field

The invention relates to the field of medical material processing, in particular to a uniform pressure type medical external application material point-like glue spreader.

Background

At present, most medical dressing products are coated with adhesive with higher gram weight and are fully coated, so that a completely sealed environment is formed after the medical dressing products are applied to wounds, the medical dressing products are airtight, the normal breathing of skin is blocked, and the growth speed of skin tissues is slowed down;

in the prior art, when the medical external application material is subjected to point processing, uniform dispensing of the non-woven fabric attached to the skin cannot be realized, so that the produced non-woven fabric has the problems of over-tight local attachment and local non-attachment in the use process of a patient due to the uneven thickness of the point-shaped glue on the surface, and the normal skin respiration of the patient is influenced; meanwhile, when the transfer type external application material is manufactured manually, the point-like glue is easy to fall off in the process of tearing the non-woven fabric, so that the quality of the product is influenced.

Aiming at the problems, a uniform pressure type medical external application material punctiform glue spreader is provided.

Disclosure of Invention

In order to overcome the defect that the spot glue is easy to fall off in the process of tearing the non-woven fabric in the prior art, the technical problem to be solved is as follows: provides a uniform pressure type medical external application material dotted gumming machine.

The technical implementation scheme of the invention is as follows: a pressure-equalizing medical externally-applied material punctiform glue spreader comprises a foot rest, a frame, a storage box, a bottom plate, a first support frame, a top cover and a fitting system; four corners of the lower end surface of the frame are respectively connected with a foot rest; a bottom plate is fixedly connected above the rack; the left part and the right part of the front side below the bottom plate are respectively connected with a storage box; the rear part above the bottom plate is fixedly connected with a first support frame; a top cover is fixedly connected above the bottom plate; the left rear side above the bottom plate is connected with a fitting system; the first support frame is connected with the fitting system.

The laminating system comprises a first servo motor, a first fixing frame, a first electric push rod, a grid frame, a clamping assembly, a first portal frame, a limiting rod, a moving block, a second electric push rod, a fixing beam, an extrusion laminating assembly and a spring telescopic rod; a first servo motor is arranged at the left rear part above the bottom plate; a first fixing frame is rotatably connected above the first supporting frame; the output shaft of the first servo motor is fixedly connected with the first fixing frame; a first portal frame is fixedly connected between the left side and the right side of the inner rear part of each first fixing frame; a first electric push rod is fixedly connected to the front of the left side and the front of the right side in each first fixing frame; three spring telescopic rods are fixedly connected to the front part in each first fixing frame; grid frames are fixedly connected to the moving end parts of the four first electric push rods; two clamping assemblies are arranged on the left side and the right side of the grid frame; the upper side and the lower side in front of the grid frame are fixedly connected with three spring telescopic rods; each first portal frame is fixedly connected with a limiting rod; each limiting rod is connected with a moving block in a sliding manner; each moving block is fixedly connected with a second electric push rod; a fixed beam is fixedly connected in front of the moving end parts of the two second electric push rods; five extrusion laminating assemblies are fixedly connected in front of the fixed beam at equal intervals.

The clamping assembly comprises a straight slide rail, a spring rod, a first slide block, a third electric push rod, a clamping plate and a slide rod; a straight slide rail is fixedly connected to the lower part of the right side of the grid frame; a sliding rod is fixedly connected above the straight sliding rail; the straight slide rail is connected with a first slide block in a sliding manner; a spring rod is fixedly connected to the right side end of the sliding rod; the left side of the spring rod is fixedly connected with a first sliding block; the first sliding block is in sliding connection with the sliding rod; a third electric push rod is fixedly connected above the first sliding block; a clamping plate is fixedly connected to the rear side of the moving end part of the third electric push rod.

As an improvement of the scheme, the cross bars in the grid frame are equidistant.

As an improvement of the scheme, the radius of the extrusion roller in the extrusion laminating assembly is larger than the thickness of the cross beam in the middle of the grid frame.

As an improvement of the scheme, the device also comprises a power system, wherein the power system comprises a first power motor, a first driving wheel, a second driving wheel, a screw rod and a third driving wheel; the left part of the first fixed frame is fixedly connected with a first power motor; a first driving wheel is fixedly connected above an output shaft of the first power motor; a screw rod is rotatably connected below the first portal frame on the right side; a screw rod is rotatably connected below the first portal frame on the left side; the right screw rod is fixedly connected with a second driving wheel; the second driving wheel is a double-track wheel; the left screw rod is fixedly connected with a third transmission wheel; the outer ring surface of the first driving wheel is in transmission connection with the second driving wheel through a belt; the outer ring surface of the second driving wheel is in transmission connection with the third driving wheel through a belt.

As an improvement of the scheme, the device also comprises a second support frame, a third support frame and a support clamping system; a second support frame is arranged in the middle of the right side above the bottom plate; a third support frame is arranged in the middle of the left side above the bottom plate; a supporting and clamping system is connected above the bottom plate; a supporting and clamping system is connected above the second supporting frame; and a supporting and clamping system is connected above the third supporting frame.

As an improvement of the above scheme, the supporting and clamping system comprises a workbench, a positioning block, a first rotating shaft, a first clamping plate, a fourth transmission wheel, a fifth transmission wheel, a first bevel gear, a second power motor, a second bevel gear, a third bevel gear, a second rotating shaft, a sixth transmission wheel, a seventh transmission wheel, a third rotating shaft, an eighth transmission wheel, a ninth transmission wheel, a fourth rotating shaft and a second clamping plate; a workbench is arranged on the front side above the bottom plate; two positioning blocks are respectively arranged on the front side and the rear side above the workbench; a first rotating shaft is rotatably connected above the second supporting frame; a first clamping plate is fixedly connected to the outer ring surface of the first rotating shaft; a fourth driving wheel is fixedly connected to the rear part of the outer ring surface of the first rotating shaft; a second power motor is arranged in the middle of the right side of the lower end face of the bottom plate; a second bevel gear is fixedly connected to the right part of an output shaft of the second power motor; the rear side of the first bevel gear is rotationally connected with the bottom plate through a short rotating shaft; the first bevel gear is connected with a fifth driving wheel through a short rotating shaft; the outer ring surface of the fourth driving wheel is in transmission connection with the fifth driving wheel through a belt; a second rotating shaft is rotatably connected to the right side below the bottom plate; a third bevel gear and a sixth driving wheel are fixedly connected to the outer ring surface of the second rotating shaft; the second bevel gear is meshed with the first bevel gear; the second bevel gear is meshed with the third bevel gear; a third rotating shaft is rotatably connected to the left side below the bottom plate; a seventh driving wheel and an eighth driving wheel are fixedly connected to the outer ring surface of the third rotating shaft; the outer ring surface of the sixth driving wheel is in transmission connection with the seventh driving wheel through a belt; a fourth rotating shaft is rotatably connected above the third supporting frame; a second clamping plate is fixedly connected to the outer ring surface of the fourth rotating shaft; a ninth driving wheel is fixedly connected to the rear part of the outer ring surface of the fourth rotating shaft; the outer ring surface of the eighth driving wheel is in transmission connection with the ninth driving wheel through a belt.

As an improvement of the scheme, the positioning block is an L-shaped plate.

As an improvement of the scheme, the pressing plates of the first clamping plate and the second clamping plate are both made of rubber plates.

As an improvement of the scheme, the device further comprises a flattening and righting system, wherein the flattening and righting system comprises a supporting plate, an electric sliding rail, a second sliding block, a second fixing frame, a fourth electric push rod, a second portal frame, an extrusion roller, a second servo motor, a connecting frame, a supporting beam and a sucker; a supporting plate is fixedly connected to the middle part of the front side of the top cover; an electric sliding rail is fixedly connected to the rear side of the supporting plate; the rear side of the electric slide rail is connected with a second slide block in a sliding way; a second fixed frame is fixedly connected with the rear side of the second sliding block; a fourth electric push rod is fixedly connected to the rear side of the second fixing frame; a second portal frame is fixedly connected below the moving end part of the fourth electric push rod; the lower part in the second portal frame is rotatably connected with an extrusion roller; a second servo motor is fixedly connected to the rear part of the left side of the second portal frame; the front side and the rear side of the left side of the second portal frame are respectively and rotatably connected with a connecting frame; a connecting frame is fixedly connected below the output shaft of the second servo motor; supporting beams are fixedly connected to the left sides of the two connecting frames; six suckers are fixedly connected to the left side of the supporting beam.

The invention has the beneficial effects that: the invention processes the stability of the transfer material, and carries out secondary bulge elimination and correct positioning of the holes on the composite perforated gluing transfer material;

the gluing system designed by the invention carries out point gluing on the medical external application material, the production and the manufacture are carried out by using a glue solution transfer mode, the perforated gluing transfer material which is locally embedded and compounded with the non-woven fabric is lifted up integrally by using a single extrusion mode, and the phenomenon that the point glue falls off in a tearing and pulling type separation mode is avoided.

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 front view of the present invention;

FIG. 4 is a combination view of a fit system and power system of the present invention;

FIG. 5 is a first combination diagram of the operating states of the laminating system and the power system of the present invention;

FIG. 6 is a schematic perspective view of the present invention at G;

FIG. 7 is a second combination of the attachment system and the powertrain system of the present invention;

FIG. 8 is a schematic perspective view of the support clamping system of the present invention;

FIG. 9 is a schematic view of a portion of the support and clamping system of the present invention;

FIG. 10 is a partial bottom view of the support clamp system of the present invention;

fig. 11 is a schematic perspective view of the leveling system according to the present invention.

Wherein: 1-foot rest, 2-machine frame, 3-storage box, 4-bottom plate, 5-first support frame, 6-second support frame, 7-third support frame, 8-top cover, 101-first servo motor, 102-first fixed frame, 103-first electric push rod, 104-grid frame, 105-clamping assembly, 106-first portal frame, 107-limit rod, 108-moving block, 109-second electric push rod, 1010-fixed beam, 1011-extrusion laminating assembly, 1012-spring telescopic rod, 1051-straight slide rail, 1052-spring rod, 1053-first slide block, 1054-third electric push rod, 1055-clamping plate, 1056-slide bar, 201-first power motor, 202-first transmission wheel, 203-second transmission wheel, 204-a screw rod, 205-a third transmission wheel, 301-a workbench, 302-a positioning block, 303-a first rotating shaft, 304-a first clamping plate, 305-a fourth transmission wheel, 306-a fifth transmission wheel, 307-a first bevel gear, 308-a second power motor, 309-a second bevel gear, 3010-a third bevel gear, 3011-a second rotating shaft, 3012-a sixth transmission wheel, 3013-a seventh transmission wheel, 3014-a third rotating shaft, 3015-an eighth transmission wheel, 3016-a ninth transmission wheel, 3017-a fourth rotating shaft, 3018-a second clamping plate, 401-a supporting plate, 402-an electric sliding rail, 403-a second sliding block, 404-a second fixing frame, 405-a fourth electric push rod, 406-a second portal frame, 407-a pushing roller and 408-a second servo motor, 409-connecting frame, 4010-supporting beam and 4011-sucker.

Detailed Description

The following further describes the technical solution with reference to specific embodiments, and it should be noted that: the words upper, lower, left, right, and the like used herein to indicate orientation are merely for the location of the illustrated structure in the corresponding figures. The serial numbers of the parts are themselves numbered herein, for example: first, second, etc. are used solely to distinguish one from another as to objects described herein, and do not have any sequential or technical meaning. The application states that: the connection and coupling, unless otherwise indicated, include both direct and indirect connections (couplings).

Example 1

A pressure-equalizing medical externally-applied material punctiform glue spreader is shown in figures 1-4 and comprises a foot rest 1, a frame 2, a storage box 3, a bottom plate 4, a first support frame 5, a top cover 8 and a fitting system; four corners of the lower end surface of the frame 2 are respectively connected with a foot rest 1; a bottom plate 4 is fixedly connected above the frame 2; the left part and the right part of the front side below the bottom plate 4 are respectively connected with a storage box 3; the rear part above the bottom plate 4 is fixedly connected with a first support frame 5; a top cover 8 is fixedly connected above the bottom plate 4; the left rear side above the bottom plate 4 is connected with a fitting system; the first support frame 5 is connected with the fitting system.

When using a pressure equalizing type medical external application material punctiform spreading machine, firstly leveling a foot rest 1 below a frame 2 at a horizontal working place, ensuring the horizontal stability of the device by taking a top cover 8 as a visual field plane, placing a required maintenance tool in a storage box 3, then switching on the device, manually placing a spreading release film and a perforated release paper which are bonded in advance horizontally and realizing fixation, ensuring that the perforated surface is upward, and fixing a new piece of non-woven fabric on a bonding system every time the device runs; then after the material preparation is finished, the laminating system above the bottom plate 4 is controlled to turn over on the first support frame 5, so that the laminating system is positioned to a working position, the laminating system positions the non-woven fabric right above the bonded adhesive coating release film and the perforated release paper, the embedded extrusion function of the laminating system can be realized by using a manual operation mode, the laminating system locally embeds the non-woven fabric on the composite perforated adhesive coating transfer material in a single extrusion mode, and then the laminating system lifts the non-woven fabric up integrally and upwards, so that the phenomenon that the spot adhesive falls off due to tearing is avoided, and the problem that the spot adhesive non-woven fabric with uniform thickness cannot be obtained in the prior art is solved; the invention carries out point-like gluing on the medical external application material, carries out production and manufacture by using a glue solution transfer mode, and lifts the non-woven fabric integrally and upwards by using the perforated gluing transfer material which is formed by locally embedding and compounding the non-woven fabric in a single extrusion mode, thereby avoiding the phenomenon that point-like glue falls off in a tearing separation mode.

Example 2

Based on embodiment 1, as shown in fig. 1 and fig. 4 to 7, the attaching system includes a first servo motor 101, a first fixing frame 102, a first electric push rod 103, a grid frame 104, a clamping assembly 105, a first gantry 106, a limit rod 107, a moving block 108, a second electric push rod 109, a fixing beam 1010, an extrusion attaching assembly 1011, and a spring telescopic rod 1012; a first servo motor 101 is arranged at the left rear part above the bottom plate 4; a first fixing frame 102 is rotatably connected above the first support frame 5; an output shaft of the first servo motor 101 is fixedly connected with the first fixing frame 102; a first portal frame 106 is fixedly connected between the left side and the right side of the inner rear part of each first fixing frame 102; a first electric push rod 103 is fixedly connected to the front of the left side and the front of the right side in each first fixing frame 102; three spring telescopic rods 1012 are fixedly connected to the inner front part of each first fixing frame 102; grid frames 104 are fixedly connected to the moving end parts of the four first electric push rods 103; two clamping assemblies 105 are arranged on the left side and the right side of the grid frame 104; three spring telescopic rods 1012 are fixedly connected to the upper side and the lower side of the front of the grid frame 104; each first portal frame 106 is fixedly connected with a limiting rod 107; each limiting rod 107 is connected with a moving block 108 in a sliding manner; each moving block 108 is fixedly connected with a second electric push rod 109; a fixed beam 1010 is fixedly connected in front of the moving end parts of the two second electric push rods 109; five extrusion laminating assemblies 1011 are fixedly connected in front of the fixed beam 1010 at equal intervals.

The clamping assembly 105 comprises a straight slide rail 1051, a spring rod 1052, a first slide block 1053, a third electric push rod 1054, a clamping plate 1055 and a slide bar 1056; a straight slide rail 1051 is fixedly connected below the right side of the grid frame 104; a sliding rod 1056 is fixedly connected above the straight sliding rail 1051; the straight sliding rail 1051 is connected with a first sliding block 1053 in a sliding manner; a spring rod 1052 is fixedly connected to the right end part of the sliding rod 1056; the left side of the spring rod 1052 is fixedly connected with a first slide block 1053; the first sliding block 1053 is connected with the sliding rod 1056 in a sliding way; a third electric push rod 1054 is fixedly connected above the first sliding block 1053; a clamp plate 1055 is fixed to the rear side of the moving end of the third electric push rod 1054.

The cross bars in the grid frame 104 are equidistant, so that pressure equalizing and stress bearing are realized conveniently.

The radius of the extrusion roller in the extrusion fitting assembly 1011 is larger than the thickness of the cross beam in the middle of the grid frame 104, so that the non-woven fabric can be conveniently embedded.

The device also comprises a power system, wherein the power system comprises a first power motor 201, a first transmission wheel 202, a second transmission wheel 203, a screw rod 204 and a third transmission wheel 205; a first power motor 201 is fixedly connected to the left part of the first fixing frame 102; a first driving wheel 202 is fixedly connected above an output shaft of the first power motor 201; a screw rod 204 is rotatably connected below the right first portal frame 106; a screw rod 204 is rotatably connected below the left first portal frame 106; the screw rod 204 on the right side is fixedly connected with a second transmission wheel 203; the second driving wheel 203 is a double-track wheel; a third transmission wheel 205 is fixedly connected with the screw rod 204 at the left side; the outer ring surface of the first transmission wheel 202 is in transmission connection with a second transmission wheel 203 through a belt; the outer circumferential surface of the second transmission wheel 203 is in driving connection with a third transmission wheel 205 through a belt.

Firstly, a first servo motor 101 is powered on, a worker installs and positions non-woven fabrics on four clamping assemblies 105, when the corners of the non-woven fabrics are clamped, the clamping modes of the four corners are completely consistent, a third electric push rod 1054 is firstly controlled to drive a clamping plate 1055 to move, and the clamping plate 1055 moves towards the surface of a first sliding block 1053 to clamp the corners of the non-woven fabrics; then controlling the first servo motor 101 to operate, an output shaft of the first servo motor 101 drives the first fixing frame 102 to rotate ninety degrees on the first supporting frame 5, at the moment, the two first fixing frames 102 are both in a vertical state, meanwhile, the clamped non-woven fabric is in a horizontally placed state and attached to the grid frame 104, controlling the four first electric push rods 103 to operate simultaneously, the four first electric push rods 103 drive the grid frame 104 to move downwards and enable the lower surface of the grid frame 104 to press the upper surface of the composite perforated gluing transfer material, at the moment, the grid frame 104 extrudes the spring telescopic rods 1012 in the downward movement process, the spring telescopic rods 1012 are in a contracted state, at the moment, controlling the two second electric push rods 109 to operate simultaneously, the two second electric push rods 109 drive the fixing beam 1010 to move downwards, the fixing beam 1010 drives the extrusion attachment assembly 1011 to move downwards, and the extrusion rollers in the extrusion attachment assembly 1011 drive the non-woven fabric to be embedded from the rear side of the grid frame 104 first to realize the embedding with the composite perforated gluing transfer material The materials are jointed, at the moment, a first power motor 201 of a power system is powered on, the first power motor 201 drives a first transmission wheel 202 to rotate, the first transmission wheel 202 drives a second transmission wheel 203 to drive a lead screw 204 on the right side of a first fixed frame 102 to rotate, because the second transmission wheel 203 is a double-track wheel, the second transmission wheel 203 drives a third transmission wheel 205 to drive the lead screw 204 on the left side of the first fixed frame 102 to rotate, at the moment, each lead screw 204 respectively drives a moving block 108 to move, the moving block 108 drives a second electric push rod 109 to move when moving forwards on a limiting rod 107, five extrusion rollers in an extrusion jointing assembly 1011 moving along with the second electric push rod completely embed the non-woven fabric into a grid frame 104, in the process, four corners of the non-woven fabric are clamped by a first sliding block 1053 and a clamping plate 1055 in a matching manner, and during embedding, the first sliding block 1053 simultaneously slides on a straight sliding rail 1051 and a sliding rod 1056, at the moment, the spring rod 1052 is gradually stretched to complete the distance compensation when the non-woven fabric is embedded, so that the non-woven fabric is prevented from being broken; when the non-woven fabric and the holes in the composite perforated gluing transfer material are extruded, the first power motor 201 is controlled to rotate clockwise and anticlockwise at regular time, multiple times of extrusion are achieved, glue on the base film of the composite perforated gluing transfer material overflows to the lower surface of the non-woven fabric from the holes, the return stroke of the first electric push rod 103 is controlled at the moment, the non-woven fabric is completely lifted up on the grid frame 104, the embedded part of the non-woven fabric is not controlled by adhesive force when the non-woven fabric is separated from the composite perforated gluing transfer material, and therefore the non-woven fabric is straightened again in the retraction process of the spring rod 1052, and gluing operation of point glue on the surface of the non-woven fabric is achieved.

Example 3

On the basis of the embodiment 2, as shown in fig. 1 and fig. 8-10, the device further comprises a second support frame 6, a third support frame 7 and a support clamping system; a second support frame 6 is arranged in the middle of the right side above the bottom plate 4; a third support frame 7 is arranged in the middle of the left side above the bottom plate 4; a supporting and clamping system is connected above the bottom plate 4; a supporting and clamping system is connected above the second supporting frame 6; a supporting and clamping system is connected above the third supporting frame 7.

The supporting and clamping system comprises a workbench 301, a positioning block 302, a first rotating shaft 303, a first clamping plate 304, a fourth driving wheel 305, a fifth driving wheel 306, a first bevel gear 307, a second power motor 308, a second bevel gear 309, a third bevel gear 3010, a second rotating shaft 3011, a sixth driving wheel 3012, a seventh driving wheel 3013, a third rotating shaft 3014, an eighth driving wheel 3015, a ninth driving wheel 3016, a fourth rotating shaft 3017 and a second clamping plate 3018; a workbench 301 is arranged on the front side above the bottom plate 4; two positioning blocks 302 are respectively arranged on the front side and the rear side above the workbench 301; a first rotating shaft 303 is rotatably connected above the second supporting frame 6; a first clamping plate 304 is fixedly connected to the outer annular surface of the first rotating shaft 303; a fourth driving wheel 305 is fixedly connected to the rear part of the outer annular surface of the first rotating shaft 303; a second power motor 308 is arranged in the middle of the right side of the lower end face of the bottom plate 4; a second bevel gear 309 is fixedly connected to the right part of an output shaft of the second power motor 308; the rear side of the first bevel gear 307 is rotationally connected with the bottom plate 4 through a short rotating shaft; the first bevel gear 307 is connected with a fifth driving wheel 306 through a short rotating shaft; the outer annular surface of the fourth driving wheel 305 is in driving connection with a fifth driving wheel 306 through a belt; a second rotating shaft 3011 is rotatably connected to the right side below the bottom plate 4; a third bevel gear 3010 and a sixth transmission wheel 3012 are fixedly connected to the outer ring surface of the second rotating shaft 3011; the second bevel gear 309 is engaged with the first bevel gear 307; the second bevel gear 309 is meshed with the third bevel gear 3010; a third rotating shaft 3014 is rotatably connected to the left side below the bottom plate 4; a seventh driving wheel 3013 and an eighth driving wheel 3015 are fixedly connected to the outer ring surface of the third rotating shaft 3014; the outer ring surface of the sixth driving wheel 3012 is in transmission connection with the seventh driving wheel 3013 through a belt; a fourth rotating shaft 3017 is rotatably connected above the third supporting frame 7; a second clamping plate 3018 is fixedly connected to the outer ring surface of the fourth rotating shaft 3017; a ninth driving wheel 3016 is fixedly connected to the rear part of the outer ring surface of the fourth rotating shaft 3017; the outer ring surface of the eighth driving wheel 3015 is in transmission connection with the ninth driving wheel 3016 through a belt.

The positioning block 302 is an L-shaped plate.

The pressure plates of the first clamp plate 304 and the second clamp plate 3018 are made of rubber plates, so as to protect the bottom composite perforated rubberized transfer material.

When the composite perforated gluing transfer material needs to be fixed, the second power motor 308 is powered on, a worker firstly positions the composite perforated gluing transfer material on the workbench 301, places the composite perforated gluing transfer material on the position basis of the four positioning blocks 302, then controls the second power motor 308 to operate, an output shaft of the second power motor 308 drives the second bevel gear 309 to rotate, the second bevel gear 309 simultaneously engages with the first bevel gear 307 and the third bevel gear 3010, the first bevel gear 307 drives the fifth transmission wheel 306 to rotate through a short rotating shaft, the fifth transmission wheel 306 drives the fourth transmission wheel 305 to drive the first rotating shaft 303 to rotate ninety degrees on the second supporting frame 6, the first rotating shaft 303 drives the first clamping plate 304 to rotate ninety degrees, the first clamping plate 304 finishes clamping the composite perforated gluing transfer material on the right side, and meanwhile, the third bevel gear 3010 drives the second rotating shaft 3011 to rotate under the bottom plate 4, second pivot 3011 drives sixth drive wheel 3012 transmission seventh drive wheel 3013, seventh drive wheel 3013 drives third pivot 3014 and rotates in bottom plate 4 below, third pivot 3014 drives eighth drive wheel 3015 transmission ninth drive wheel 3016, ninth drive wheel 3016 drives fourth pivot 3017 and rotates on third support frame 7, fourth pivot 3017 drives second pinch-off blades 3018 and rotates ninety degrees, second pinch-off blades 3018 accomplish the clamp to the compound foraminiferous rubber coating transfer material in left side.

Example 4

On the basis of embodiment 3, as shown in fig. 1 and 11, a leveling and righting system is further included, and the leveling and righting system includes a supporting plate 401, an electric slide rail 402, a second slide block 403, a second fixing frame 404, a fourth electric push rod 405, a second portal frame 406, a squeezing roller 407, a second servo motor 408, a connecting frame 409, a supporting beam 4010, and a suction cup 4011; a supporting plate 401 is fixedly connected to the middle part of the front side of the top cover 8; an electric slide rail 402 is fixedly connected to the rear side of the support plate 401; a second sliding block 403 is connected to the rear side of the electric sliding rail 402 in a sliding manner; a second fixing frame 404 is fixedly connected to the rear side of the second sliding block 403; a fourth electric push rod 405 is fixedly connected to the rear side of the second fixing frame 404; a second portal frame 406 is fixedly connected below the moving end part of the fourth electric push rod 405; a pushing roller 407 is rotatably connected to the lower part in the second portal frame 406; a second servo motor 408 is fixedly connected to the rear part of the left side of the second portal frame 406; the front side and the rear side of the left side of the second portal frame 406 are respectively connected with a connecting frame 409 in a rotating way; a connecting frame 409 is fixedly connected below the output shaft of the second servo motor 408; the left sides of the two connecting frames 409 are fixedly connected with supporting beams 4010; six suckers 4011 are fixedly connected to the left side of the supporting beam 4010.

After the composite perforated gluing transfer material is clamped, local bulges and holes are not parallel in the clamping process of the composite perforated gluing transfer material, so that the bulges and the holes of the composite perforated gluing transfer material need to be eliminated and positioned, at the moment, an electric slide rail 402 fixedly connected with a control support plate 401 is powered on, a fourth electric push rod 405 is controlled to operate, the fourth electric push rod 405 drives a second portal frame 406 to move downwards, the second portal frame 406 drives a pushing roller 407 to move downwards and contacts the composite perforated gluing transfer material first, at the moment, the electric slide rail 402 is controlled to operate, the electric slide rail 402 drives a second slide block 403 to move towards the left side, the second slide block drives the fourth electric push rod 405 to move towards the left side through a second fixing frame 404, and the pushing roller 407 is rotationally connected with the second portal frame 406, therefore, the pushing roller 407 continuously pushes the composite perforated gluing transfer material in the following moving process, when the composite perforated gluing transfer material is locally raised in the flattening process, the electric slide rail 402 is controlled to stop running at the moment, six groups of suckers 4011 are used for lifting the composite perforated gluing transfer material on the left side of the pushing roller 407, the left side of the composite perforated gluing transfer material is separated from the constraint of the second clamping plate 3018 at the moment, then the fourth electric push rod 405 slightly lifts the composite perforated gluing transfer material in a short distance in the return stroke, the raised part is released for two times, at the moment, the second servo motor 408 is controlled to be powered on, the second servo motor 408 is controlled to slightly rotate, the second servo motor 408 drives a connecting frame 409 on the rear side to rotate, the connecting frame 409 drives the supporting beam 4010 to move according to the offset angle of the composite perforated gluing transfer material to complete deflection adjustment, after the composite perforated gluing and transferring material is righted, the composite perforated gluing and transferring material is released again, the fourth electric push rod 405 is controlled to enter a working state, and then secondary lamination of the remaining composite perforated gluing and transferring material is finished under the operation of the electric slide rail 402 so as to avoid influencing the transfer of the point glue of the non-woven fabric.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.