阅读说明：本技术 一种螺旋纸质吸管检测方法 (Spiral paper straw detection method ) 是由 杨雄威 于 2021-08-05 设计创作，主要内容包括：本发明涉及一种吸管加工领域,尤其涉及一种螺旋纸质吸管检测方法。本发明要解决的技术问题为：提供一种螺旋纸质吸管检测方法。本发明的技术方案是：一种螺旋纸质吸管检测方法,采用如下加工设备,该加工设备包括有机板和底脚等；机板下端与八组底脚固接。本发明达到了当吸管生产设备加工后的螺旋环存在偏差之后,螺旋纸质吸管检测方法的设备能够对吸管进行限位,从而使吸管生产设备生产的吸管外壁的螺旋纸正位,同时能够对吸管进行分类裁切,对质量不达标的吸管与达标的吸管进行区分,从而防止了生产出的吸管发生饮料深入纸吸管的情况,从而使吸管使用寿命增加的效果。(The invention relates to the field of straw processing, in particular to a spiral paper straw detection method. The technical problem to be solved by the invention is as follows: provides a spiral paper straw detection method. The technical scheme of the invention is as follows: a spiral paper straw detection method adopts the following processing equipment, and the processing equipment comprises an organic plate, bottom feet and the like; the lower end of the machine plate is fixedly connected with eight groups of bottom feet. The invention achieves the effect that when the spiral ring processed by the straw production equipment has deviation, the equipment of the spiral paper straw detection method can limit the straw, so that the spiral paper on the outer wall of the straw produced by the straw production equipment is aligned, and meanwhile, the straw can be classified and cut, and the straws with unqualified quality are distinguished from the straws with qualified quality, so that the situation that the beverage penetrates into the paper straw in the produced straw is prevented, and the service life of the straw is prolonged.)

1. A spiral paper straw detection method adopts processing equipment which comprises an organic plate (1), a bottom foot (2), a first support plate (3), a control screen (4), a first support (5), a first frame (6) and a first material guide plate (7); the lower end of the machine plate (1) is fixedly connected with eight groups of bottom feet (2); the side part of the machine plate (1) is fixedly connected with the first support plate (3) and the first bracket (5) in sequence; the middle part of the machine plate (1) is fixedly connected with the first frame (6); the first support plate (3) is connected with the control screen (4) through bolts; the middle part of the first frame (6) is fixedly connected with a first material guide plate (7); the method is characterized in that: the automatic material distribution device also comprises a detection system, a cutting system, a material distribution system, a residual material collection system, a quality control system and a power system; the top of the machine plate (1) is sequentially provided with a material distribution system, a cutting system and a quality control system; a residual material collecting system is arranged at the rear part of the machine plate (1); the front part of the machine plate (1) is provided with a power system; the first bracket (5) is fixedly connected with the detection system; the first frame (6) is rotationally connected with the detection system; the first frame (6) is fixedly connected with the cutting system; the cutting system is fixedly connected with the material distributing system; the material distribution system is fixedly connected with the residual material collecting system; the front part of the quality control system is connected with a power system.

2. The spiral paper pipette detection method of claim 1, wherein: the detection system comprises a detection box (101), a second bracket (102), a third bracket (103), a box door (104), a control handle (105), a sensor (106), a thimble (107) and a heating wire (108); the detection box (101) is fixedly connected with the first bracket (5); the detection box (101) is fixedly connected with the two groups of second brackets (102); the two groups of second brackets (102) are respectively and rotatably connected with the two groups of third brackets (103) through round rods; the two groups of third brackets (103) are fixedly connected with the box door (104); the top of the detection box (101) is provided with a control handle (105); a group of sensors (106) are fixedly connected to two sides in the detection box (101); the two groups of sensors (106) are connected with a group of thimbles (107) which are connected with each other; the middle part of the detection box (101) is fixedly connected with the heating wire (108).

3. The spiral paper pipette detection method of claim 2, wherein: the cutting system comprises a first transmission rod (201), a second transmission rod (202), a first cutter (203), a sliding groove frame (204), a second support plate (205), a second cutter (206), a fourth support (207) and a fifth support (208); the first transmission rod (201) is fixedly connected with the power system; the first transmission rod (201) is in transmission connection with the second transmission rod (202); the second transmission rod (202) is in transmission connection with the first cutter (203); the upper end and the lower end of the first cutter (203) are respectively connected with a group of sliding groove frames (204) in a sliding manner; the chute frame (204) is fixedly connected with the material distributing system; the two groups of sliding groove frames (204) are fixedly connected with a second support plate (205); the second support plate (205) is fixedly connected with the material distribution system; a second cutter (206) is arranged at the side part of the first cutter (203); the second cutter (206) is fixedly connected with the material distribution system; the second support plate (205) is fixedly connected with the fourth bracket (207); the fourth bracket (207) is fixedly connected with the machine plate (1); the second cutter (206) is fixedly connected with the fifth bracket (208); the fifth bracket (208) is fixedly connected with the machine plate (1).

4. The spiral paper pipette detection method of claim 3, wherein: the material distributing system comprises a material distributing box (301), a residual material discharging hole (302), a material distributing plate (303), a material discharging guide plate (304), a support rod (305), a sixth support (306), a seventh support (307), a first electric slide rail (308), a second frame (309), a first electric push rod (3010), a first V-shaped adjusting frame (3011) and a second V-shaped adjusting frame (3012); the material distributing box (301) is fixedly connected with the residual material discharging hole (302); the material distribution box (301) is fixedly connected with the fourth bracket (207); the residual material discharge port (302) is fixedly connected with the residual material collecting system; the inner wall of the material distributing box (301) is fixedly connected with the material distributing plate (303); the material distributing box (301) is fixedly connected with the material discharging guide plate (304); the material distributing box (301) is fixedly connected with a sixth bracket (306); the bottom end of the discharging guide plate (304) is fixedly connected with the four groups of supporting rods (305); the four groups of supporting rods (305) are fixedly connected with the machine plate (1); the discharging guide plate (304) is fixedly connected with the seventh bracket (307); the top of the sixth bracket (306) is fixedly connected with the two groups of first electric slide rails (308); the two groups of first electric slide rails (308) are fixedly connected with a seventh bracket (307); the seventh bracket (307) is fixedly connected with the machine plate (1); the two groups of first electric slide rails (308) are respectively connected with the two groups of second frames (309) in a sliding way; two groups of first electric push rods (3010) are respectively fixedly connected with the two groups of second frames (309); the two groups of second frames (309) are fixedly connected with the first V-shaped positioning frame (3011); the two groups of first electric push rods (3010) are connected with the first V-shaped positioning frame (3011) in a sliding manner; two groups of first electric push rods (3010) are fixedly connected with a second V-shaped positioning frame (3012); the second V-shaped adjusting frames (3012) are respectively connected with the two groups of second frames (309) in a sliding way.

5. The spiral paper pipette detection method of claim 4, wherein: the residual material collecting system comprises an eighth support (401), a residual material collecting box (402), a ninth support (403), a third support plate (404), a second electric slide rail (405), an electric slide plate (406), a U-shaped clamping plate (407), a second material guide plate (408), a support column (409) and a material blocking disc (4010); the eighth bracket (401) is fixedly connected with the residual material collecting box (402); the eighth bracket (401) is fixedly connected with the machine plate (1); the residual material collecting box (402) is fixedly connected with a ninth bracket (403); the ninth bracket (403) is fixedly connected with the machine plate (1); the eighth bracket (401) and the ninth bracket (403) are fixedly connected with a third support plate (404); the residual material collecting box (402) is fixedly connected with the residual material discharging port (302); the third support plate (404) is fixedly connected with the second electric slide rail (405); the top of the outer surface of the second electric sliding rail (405) is connected with an electric sliding plate (406) in a sliding way; the electric skateboard (406) is fixedly connected with two groups of U-shaped splints (407); two groups of U-shaped clamping plates (407) are fixedly connected with a second material guide plate (408); the eighth bracket (401) is fixedly connected with the strut (409); the support column (409) is fixedly connected with the material blocking plate (4010).

6. The spiral paper pipette detection method of claim 5, wherein: the quality control system comprises a bearing box (501), a sliding block (502), a third electric sliding rail (503), a third frame (504), a bidirectional threaded rod (505), a first polished rod (506), a second polished rod (507), a fourth supporting plate (508), a first bevel gear (509), a first sliding plate (5010), a second sliding plate (5011), a tenth bracket (5012), a first limiting roller (5013), an eleventh bracket (5014), a second limiting roller (5015), a twelfth bracket (5016) and a third limiting roller (5017); two ends of the bearing box (501) are fixedly connected with a group of sliding blocks (502) for fixed connection; the two groups of sliding blocks (502) are respectively connected with the corresponding group of third electric sliding rails (503) in a sliding way; the two groups of third electric slide rails (503) are respectively connected with the two groups of third frames (504) through bolts; the two groups of third frames (504) are fixedly connected with the machine plate (1); a group of third frames (504) positioned at the front part are rotationally connected with the power system; the front part and the rear part of the bearing box (501) are rotationally connected with a bidirectional threaded rod (505); two sides inside the bearing box (501) are fixedly connected with the first polish rod (506) and the second polish rod (507) respectively; the middle part in the bearing box (501) is fixedly connected with a fourth support plate (508); two sides of the fourth support plate (508) are respectively and fixedly connected with the first polish rod (506) and the second polish rod (507); the bidirectional threaded rod (505) is fixedly connected with the first bevel gear (509); the front part of the outer surface and the rear part of the outer surface of the bidirectional threaded rod (505) are respectively connected with a first sliding plate (5010) and a second sliding plate (5011) through bolts; the first sliding plate (5010) is respectively connected with the first polished rod (506) and the second polished rod (507) in a sliding manner; the first bevel gear (509) is meshed with a power system; the second sliding plate (5011) is respectively connected with the first polished rod (506) and the second polished rod (507) in a sliding manner; the fourth support plate (508) is fixedly connected with the twelfth support (5016); the first sliding plate (5010) is fixedly connected with the tenth bracket (5012); the second sliding plate (5011) is fixedly connected with the eleventh bracket (5014); the tenth bracket (5012) is rotatably connected with the first limiting roller (5013); the eleventh bracket (5014) is rotatably connected with the second limiting roller (5015); the twelfth bracket (5016) is rotatably connected with the third limiting roller (5017).

7. The spiral paper pipette detection method of claim 6, wherein: the power system comprises a motor (601), a first transmission wheel (602), a second transmission wheel (603), a first rotating shaft rod (604), a second bevel gear (605), a third bevel gear (606), a fourth bevel gear (607), a shaft sleeve (608), a fifth support plate (609), a second electric push rod (6010), a second rotating shaft rod (6011), a third transmission wheel (6012), a fourth transmission wheel (6013), a third rotating shaft rod (6014), a fifth bevel gear (6015), a fifth transmission wheel (6016), a sixth transmission wheel (6017), a fourth rotating shaft rod (6018) and a sixth bevel gear (6019); the motor (601) is fixedly connected with the machine plate (1); an output shaft of the motor (601) is fixedly connected with the first transmission wheel (602); the outer surface of the first transmission wheel (602) is in transmission connection with a second transmission wheel (603) through a belt; the second transmission wheel (603) is fixedly connected with the first rotating shaft rod (604); the first rotating shaft rod (604) is fixedly connected with the second bevel gear (605); the first rotating shaft rod (604) is rotationally connected with the first frame (6); the first rotating shaft rod (604) is fixedly connected with the first transmission rod (201); a third bevel gear (606) is arranged at the lower part of the second bevel gear (605); the third bevel gear (606) is fixedly connected with the shaft sleeve (608); a fourth bevel gear (607) is fixedly connected with the shaft sleeve (608); the shaft sleeve (608) is rotatably connected with the fifth support plate (609); the fifth support plate (609) is fixedly connected with a second electric push rod (6010); the second electric push rod (6010) is fixedly connected with the machine plate (1); the shaft sleeve (608) is in transmission connection with a second rotating shaft rod (6011); the second rotating shaft rod (6011) is fixedly connected with a third driving wheel (6012) and a fifth driving wheel (6016) in sequence; the second rotating shaft rod (6011) is rotationally connected with the machine plate (1); the outer surface of the third driving wheel (6012) is in transmission connection with a fourth driving wheel (6013) through a belt; a fourth driving wheel (6013) is fixedly connected with a third rotating shaft rod (6014); the third rotating shaft rod (6014) is fixedly connected with a fifth bevel gear (6015); the third rotating shaft rod (6014) is rotationally connected with the third frame (504) through a bearing seat; the fifth driving wheel (6016) is in transmission connection with the sixth driving wheel (6017) through a belt; a sixth driving wheel (6017) is fixedly connected with a fourth rotating shaft rod (6018); the fourth rotating shaft rod (6018) is fixedly connected with a sixth bevel gear (6019); the fourth rotating shaft rod (6018) is rotationally connected with the third frame (504) through a bearing seat; the sixth bevel gear (6019) meshes with the first bevel gear (509).

8. The spiral paper pipette detection method of claim 7, wherein: the material distributing plate (303) is arranged in a V shape, and the center of the material distributing plate is close to the first frame (6).

9. The spiral paper pipette detection method of claim 8, wherein: the second material guide plate (408) is arranged in an arc shape.

10. The spiral paper pipette detection method of claim 9, wherein: the sensor (106) is internally provided with a rear elastic piece.

11. The spiral paper pipette detection method of claim 10, wherein: the spiral paper straw detection method comprises the following steps:

the method comprises the following steps: detecting the density of the suction tube thread paper, and detecting the suction tube outer ring thread paper through a detection system;

step two: cutting the suction pipe, and cutting the suction pipe into a finished product through a cutting system;

step three: waste materials are collected, and waste straws and straws with insufficient length are collected through a residual material collecting system.

Technical Field

The invention relates to the field of straw processing, in particular to a spiral paper straw detection method.

Background

When the paper straw is in production, the machine spiral ring may have the deviation after processing for a long time to lead to paper straw outer wall spiral ring butt joint problem to lead to the drink infiltration, thereby take place the condition that the paper straw becomes soft, thereby influence the result of use, make the life of paper straw reduce simultaneously, after the deviation appears in the spiral ring after processing simultaneously, straw production facility can not carry out normal position to it by oneself.

In order to solve the problems, a spiral paper straw detection method is provided.

Disclosure of Invention

In order to overcome the paper straw when carrying out production, the machine spiral ring may have the deviation after processing for a long time, thereby lead to paper straw outer wall spiral ring butt joint problem to lead to the drink infiltration, thereby take place the condition that the paper straw becomes soft, thereby influence the result of use, make the life of paper straw reduce simultaneously, after the deviation appears in the spiral ring after processing simultaneously, straw production facility can not carry out the shortcoming of normal position to it by oneself, the technical problem that solves is: provides a spiral paper straw detection method.

The technical scheme of the invention is as follows: a spiral paper straw detection method adopts processing equipment which comprises an organic plate, a footing, a first support plate, a control screen, a first support, a first frame, a first guide plate, a detection system, a cutting system, a material distribution system, a residual material collection system, a quality control system and a power system; the lower end of the machine plate is fixedly connected with eight groups of bottom feet; the side part of the machine plate is fixedly connected with the first support plate and the first bracket in sequence; the middle part of the machine plate is fixedly connected with the first frame; the top of the machine plate is sequentially provided with a material distribution system, a cutting system and a quality control system; a residual material collecting system is arranged at the rear part of the machine plate; the front part of the machine plate is provided with a power system; the first support plate is connected with the control screen through a bolt; the first bracket is fixedly connected with the detection system; the middle part of the first frame is fixedly connected with the first material guide plate; the first frame is rotationally connected with the detection system; the first frame is fixedly connected with the cutting system; the cutting system is fixedly connected with the material distributing system; the material distribution system is fixedly connected with the residual material collecting system; the front part of the quality control system is connected with a power system.

Preferably, the detection system comprises a detection box, a second support, a third support, a box door, a control handle, a sensor, a thimble and a heating wire; the detection box is fixedly connected with the first bracket; the detection box is fixedly connected with the two groups of second brackets; the two groups of second supports are respectively and rotatably connected with the two groups of third supports through round rods; the two groups of third supports are fixedly connected with the box door; the top of the detection box is provided with a control handle; a group of sensors are fixedly connected to two sides in the detection box; the two groups of sensors are connected with a group of thimbles; the middle part of the detection box is fixedly connected with the heating wire.

Preferably, the cutting system comprises a first transmission rod, a second transmission rod, a first cutter, a chute frame, a second support plate, a second cutter, a fourth support and a fifth support; the first transmission rod is fixedly connected with the power system; the first transmission rod is in transmission connection with the second transmission rod; the second transmission rod is in transmission connection with the first cutter; the upper end and the lower end of the first cutter are respectively connected with a group of sliding groove frames in a sliding manner; the chute frame is fixedly connected with the material distribution system; the two groups of sliding groove frames are fixedly connected with the second support plate; the second support plate is fixedly connected with the material distribution system; a second cutter is arranged on the side part of the first cutter; the second cutter is fixedly connected with the material distribution system; the second support plate is fixedly connected with the fourth support; the fourth bracket is fixedly connected with the machine plate; the second cutter is fixedly connected with the fifth bracket; the fifth bracket is fixedly connected with the machine plate.

Preferably, the material distributing system comprises a material distributing box, a residual material discharging port, a material distributing plate, a discharging guide plate, a support rod, a sixth support, a seventh support, a first electric slide rail, a second frame, a first electric push rod, a first V-shaped positioning frame and a second V-shaped positioning frame; the material separating box is fixedly connected with the residual material discharge port; the material distribution box is fixedly connected with the fourth bracket; the residual material discharge port is fixedly connected with the residual material collecting system; the inner wall of the material distributing box is fixedly connected with the material distributing plate; the material distributing box is fixedly connected with the material discharging guide plate; the material distributing box is fixedly connected with the sixth bracket; the bottom end of the discharging guide plate is fixedly connected with the four groups of supporting rods; the four groups of supporting rods are fixedly connected with the machine plate; the discharging guide plate is fixedly connected with the seventh bracket; the top of the sixth bracket is fixedly connected with the two groups of first electric slide rails; the two groups of first electric slide rails are fixedly connected with the seventh bracket; the seventh bracket is fixedly connected with the machine plate; the two groups of first electric sliding rails are respectively connected with the two groups of second frames in a sliding manner; the two groups of second frames are respectively fixedly connected with a group of first electric push rods; the two groups of second frames are fixedly connected with the first V-shaped positioning frame; the two groups of first electric push rods are connected with the first V-shaped positioning frame in a sliding manner; the two groups of first electric push rods are fixedly connected with the second V-shaped positioning frame; the second V-shaped positioning frames are respectively connected with the two groups of second frames in a sliding manner.

Preferably, the residual material collecting system comprises an eighth bracket, a residual material collecting box, a ninth bracket, a third support plate, a second electric slide rail, an electric slide plate, a U-shaped clamping plate, a second material guide plate, a support column and a material blocking plate; the eighth bracket is fixedly connected with the residual material collecting box; the eighth bracket is fixedly connected with the machine plate; the residual material collecting box is fixedly connected with the ninth bracket; the ninth bracket is fixedly connected with the machine plate; the eighth bracket and the ninth bracket are fixedly connected with the third support plate; the residual material collecting box is fixedly connected with the residual material discharging port; the third support plate is fixedly connected with the second electric slide rail; the top of the outer surface of the second electric sliding rail is connected with the electric sliding plate in a sliding manner; the electric skateboard is fixedly connected with two groups of U-shaped splints; the two groups of U-shaped clamping plates are fixedly connected with the second material guide plate; the eighth bracket is fixedly connected with the strut; the support is fixedly connected with the material blocking disc.

Preferably, the quality control system comprises a bearing box, a sliding block, a third electric sliding rail, a third frame, a bidirectional threaded rod, a first polished rod, a second polished rod, a fourth supporting plate, a first bevel gear, a first sliding plate, a second sliding plate, a tenth bracket, a first limiting roller, an eleventh bracket, a second limiting roller, a twelfth bracket and a third limiting roller; two ends of the bearing box are fixedly connected with a group of sliding blocks; the two groups of sliding blocks are respectively connected with the corresponding group of third electric sliding rails in a sliding manner; the two groups of third electric slide rails are respectively connected with the two groups of third frame bolts; the two groups of third frames are fixedly connected with the machine plate; a group of third frames positioned at the front part are rotationally connected with the power system; the front part and the rear part of the bearing box are rotationally connected with a bidirectional threaded rod; two sides inside the bearing box are fixedly connected with the first polish rod and the second polish rod respectively; the middle part in the bearing box is fixedly connected with a fourth support plate; two sides of the fourth support plate are fixedly connected with the first polish rod and the second polish rod respectively; the bidirectional threaded rod is fixedly connected with the first bevel gear; the front part of the outer surface of the bidirectional threaded rod and the rear part of the outer surface are respectively connected with the first sliding plate and the second sliding plate through bolts; the first sliding plate is respectively connected with the first polished rod and the second polished rod in a sliding manner; the first bevel gear is meshed with the power system; the second sliding plate is respectively connected with the first polished rod and the second polished rod in a sliding manner; the fourth support plate is fixedly connected with the twelfth support plate; the first sliding plate is fixedly connected with the tenth bracket; the second sliding plate is fixedly connected with the eleventh bracket; the tenth bracket is rotationally connected with the first limiting roller; the eleventh bracket is rotationally connected with the second limiting roller; the twelfth bracket is rotatably connected with the third limiting roller.

Preferably, the power system comprises a motor, a first driving wheel, a second driving wheel, a first rotating shaft rod, a second bevel gear, a third bevel gear, a fourth bevel gear, a shaft sleeve, a fifth support plate, a second electric push rod, a second rotating shaft rod, a third driving wheel, a fourth driving wheel, a third rotating shaft rod, a fifth bevel gear, a fifth driving wheel, a sixth driving wheel, a fourth rotating shaft rod and a sixth bevel gear; the motor is fixedly connected with the machine plate; an output shaft of the motor is fixedly connected with the first driving wheel; the outer surface of the first driving wheel is in transmission connection with a second driving wheel through a belt; the second driving wheel is fixedly connected with the first rotating shaft rod; the first rotating shaft rod is fixedly connected with the second bevel gear; the first rotating shaft rod is rotationally connected with the first frame; the first rotating shaft rod is fixedly connected with the first transmission rod; a third bevel gear is arranged at the lower part of the second bevel gear side; the third bevel gear is fixedly connected with the shaft sleeve; the fourth bevel gear is fixedly connected with the shaft sleeve; the shaft sleeve is rotatably connected with the fifth support plate; the fifth support plate is fixedly connected with the second electric push rod; the second electric push rod is fixedly connected with the machine plate; the shaft sleeve is in transmission connection with the second rotating shaft rod; the second rotating shaft rod is fixedly connected with a third driving wheel and a fifth driving wheel in sequence; the second rotating shaft rod is rotationally connected with the machine plate; the outer surface of the third driving wheel is in transmission connection with the fourth driving wheel through a belt; the fourth driving wheel is fixedly connected with the third rotating shaft rod; the third rotating shaft rod is fixedly connected with a fifth bevel gear; the third rotating shaft rod is rotationally connected with the third frame through a bearing seat; the fifth driving wheel is in transmission connection with the sixth driving wheel through a belt; the sixth driving wheel is fixedly connected with the fourth rotating shaft rod; the fourth rotating shaft rod is fixedly connected with a sixth bevel gear; the fourth rotating shaft rod is rotationally connected with the third frame through a bearing seat; the sixth bevel gear is meshed with the first bevel gear.

Preferably, the material distributing plate is arranged in a V shape, and the center of the material distributing plate is close to the first frame.

Preferably, the second guide plate is provided in an arc shape.

Preferably, the sensor is internally provided with a rear elastic member.

Preferably, the spiral paper straw detection method comprises the following steps:

the method comprises the following steps: detecting the density of the suction tube thread paper, and detecting the suction tube outer ring thread paper through a detection system;

step two: cutting the suction pipe, and cutting the suction pipe into a finished product through a cutting system;

step three: waste materials are collected, and waste straws and straws with insufficient length are collected through a residual material collecting system.

The invention has the following beneficial effects:

the method comprises the following steps of (A) in order to solve the problems that when a paper straw is produced, a machine can deviate after being processed for a long time, so that the spiral ring on the outer wall of the paper straw is butted, so that drinks permeate, the paper straw is softened, the use effect is influenced, the service life of the paper straw is shortened, and meanwhile, after the deviation occurs in the processed spiral ring, straw production equipment cannot align the paper straw automatically;

when the automatic paper straw cutting machine is used, spiral paper on the outer wall of a paper straw is detected through the detection system, then the cutting system is driven to operate through the power system, so that the paper straw is cut through the cutting system, straws with quality not reaching the standard are collected through the residual material collecting system, and when deviation occurs in a processed spiral ring, the quality control system is driven to operate through the power system, so that straw production equipment is assisted to work through the quality control system;

and thirdly, after the spiral ring processed by the straw production equipment has deviation, the spiral paper straw detection method can limit the straw, so that spiral paper on the outer wall of the straw produced by the straw production equipment is aligned, and meanwhile, the straw can be classified and cut, and the straw with unqualified quality is distinguished from the straw with qualified quality, so that the situation that the beverage goes deep into the paper straw by the produced straw is prevented, and the service life of the straw is prolonged.

Drawings

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

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

FIG. 3 is a schematic perspective view of the inspection system of the present invention;

FIG. 4 is a schematic perspective view of a portion of the detection system of the present invention;

FIG. 5 is a schematic view of a first perspective view of the cutting system of the present invention;

FIG. 6 is a schematic view of a second perspective view of the cutting system of the present invention;

FIG. 7 is a schematic perspective view of the dispensing system of the present invention;

FIG. 8 is a schematic view of a first perspective view of the residue collection system of the present invention;

FIG. 9 is a schematic diagram of a second perspective view of the residue collection system of the present invention;

FIG. 10 is a schematic perspective view of a quality control system according to the present invention;

FIG. 11 is a schematic perspective view of a first portion of the quality control system of the present invention;

FIG. 12 is a perspective view of a second portion of the quality control system of the present invention;

fig. 13 is a perspective view of the present invention and power system.

Description of reference numerals: 1_ machine plate, 2_ foot, 3_ first support plate, 4_ control screen, 5_ first support, 6_ first frame, 7_ first guide plate, 101_ detection box, 102_ second support, 103_ third support, 104_ box door, 105_ control handle, 106_ sensor, 107_ thimble, 108_ heating wire, 201_ first transmission rod, 202_ second transmission rod, 203_ first cutter, 204_ chute frame, 205_ second support plate, 206_ second cutter, 207_ fourth support, 208_ fifth support, 301_ distribution box, 302_ residue discharge hole, 303_ distribution plate, 304_ discharge guide plate, 305_ support rod, 306_ sixth support, 307_ seventh support, 308_ first electric slide rail, 309_ second frame, 3010_ first electric push rod, 3011_ first V-shaped regulation frame, 3012_ second V-shaped regulation frame, 401_ eighth regulation frame, 402_ residue regulation frame, 403_ ninth support, 404_ third support plate, 405_ second electric slide rail, 406_ electric slide plate, 407_ U-shaped clamp plate, 408_ second guide plate, 409_ pillar, 4010_ catch tray, 501_ carrying case, 502_ slider, 503_ third electric slide rail, 504_ third frame, 505_ two-way threaded rod, 506_ first polished rod, 507_ second polished rod, 508_ fourth support plate, 509_ first bevel gear, 5010_ first slide plate, 5011_ second slide plate, 5012_ tenth support, 5013_ first limit roller, 5014_ eleventh support, 5015_ second limit roller, 5016_ twelfth support, 5017_ third limit roller, 601_ motor, 602_ first driving wheel, 603_ second driving wheel, 604_ first rotating shaft, 605_ second bevel gear, 606_ third bevel gear, 607_ fourth bevel gear, 608_ shaft sleeve, 609_ fifth support plate, 6010_ second electric push rod, 6011_ second rotating shaft, 6012_ third transmission wheel, 6013_ fourth transmission wheel, 6014_ third rotating shaft rod, 6015_ fifth bevel gear, 6016_ fifth transmission wheel, 6017_ sixth transmission wheel, 6018_ fourth rotating shaft rod, 6019_ sixth bevel gear.

Detailed Description

The invention is further described with reference to the following figures and detailed description.

Example 1

As shown in fig. 1-2, a spiral paper straw detection method adopts a processing device, which comprises an organic plate 1, a footing 2, a first supporting plate 3, a control screen 4, a first bracket 5, a first frame 6, a first material guide plate 7, a detection system, a cutting system, a material distribution system, a residual material collection system, a quality control system and a power system; the lower end of the machine plate 1 is fixedly connected with eight groups of bottom feet 2; the side part of the machine plate 1 is fixedly connected with a first support 3 and a first bracket 5 in sequence; the middle part of the machine plate 1 is fixedly connected with a first frame 6; the top of the machine plate 1 is sequentially provided with a material distribution system, a cutting system and a quality control system; a residual material collecting system is arranged at the rear part of the machine plate 1; the front part of the machine plate 1 is provided with a power system; the first support plate 3 is connected with the control screen 4 through bolts; the first bracket 5 is fixedly connected with the detection system; the middle part of the first frame 6 is fixedly connected with a first material guide plate 7; the first frame 6 is rotationally connected with the detection system; the first frame 6 is fixedly connected with the cutting system; the cutting system is fixedly connected with the material distributing system; the material distribution system is fixedly connected with the residual material collecting system; the front part of the quality control system is connected with a power system.

When the device of the spiral paper suction pipe detection method is used, firstly, a power supply is externally connected, then, the device of the spiral paper suction pipe detection method is started through the control screen 4, the operation state is checked, when the operation condition has no problem, the suction pipe in the device for producing the suction pipe is manually inserted into the detection system, so that the suction pipe is heated through the detection system, and simultaneously, the distance between the outer wall of the suction pipe and the paper rings is detected, when the detected distance between the outer wall of the suction pipe and the paper rings is not problematic, the suction pipe penetrates through the quality control system and is lapped on the first material guide plate 7, so that the suction pipe is limited through the first material guide plate 7, the suction pipe is positioned at the position where the cutting system works properly, then, the power system is controlled and started through the control screen 4, so that the cutting system is driven to operate through the power system, and the suction pipe is cut into the suction pipe reaching the standard through the cutting system, at the moment, the straws fall on the material distribution system, so that the straws are arranged and conveyed out of the equipment of the spiral paper straw detection method through the material distribution system, when the detection system detects that the distance between paper rings wound on the outer wall of the straws is overlarge, the power system drives the quality control system to operate, so that the straws are limited through the quality control system, the speed of the device for processing the straws is slowed, the number of turns is recovered to be normal, at the moment, the straws are clamped through the control screen 4 to drive the straws to move at the same speed when the straws are conveyed by the straw production device, then the straws are not limited any more through the power system drive quality control system, meanwhile, the control screen 4 controls the quality control system to recover the original position, when the detection system detects that the distance between the paper rings wound on the outer wall of the straws is too small, the quality control system is conveyed to operate through the power system, after the quality control system clamps the straws, the quality control system is controlled by the control screen 4 to pull the straws to move at a speed higher than the speed of the straw conveying device until the distance between the paper rings wound on the outer wall of the straws is recovered, at the moment, the quality control system is controlled to drive the straws to move at a speed equal to that of the straw conveying device until the straws can not be limited by the power system transmission quality control system, so that the straw conveying device is assisted by the quality control system to improve the quality of the straws produced by the straw production device, at the moment, the straws are conveyed continuously, the straws are limited by the first material guide plate 7, then the detection result is transmitted by the detection system to be reflected to the control screen 4, and then the power system is controlled by the control screen 4 to cut off the qualified straws from the unqualified straws by the power system control cutting system, at the moment, the qualified straw cannot reach the length specification of a straw, the straw is conveyed into the residual material collecting system through the material distributing system, the qualified and unqualified boundary part of the other side of the straw is cut simultaneously, meanwhile, the residual material collecting system is started through the control screen 4 to collect the unqualified straw cut off, after the deviation exists in a spiral ring processed by the straw production equipment, the straw can be limited by the spiral paper straw detection method, spiral paper of the outer wall of the straw produced by the straw production equipment is in right position, the straw can be classified and cut simultaneously, the straw with unqualified quality is distinguished from the straw with qualified quality, the situation that the produced straw is deep into the paper straw is prevented, and the service life of the straw is prolonged.

As shown in fig. 3-4, the detection system comprises a detection box 101, a second bracket 102, a third bracket 103, a box door 104, a control handle 105, a sensor 106, a thimble 107 and a heating wire 108; the detection box 101 is fixedly connected with the first bracket 5; the detection box 101 is fixedly connected with the two groups of second brackets 102; the two groups of second brackets 102 are respectively connected with the two groups of third brackets 103 in a rotating way through round rods; the two groups of third brackets 103 are fixedly connected with the box door 104; the top of the detection box 101 is provided with a control handle 105; a group of sensors 106 are fixedly connected to two sides in the detection box 101; the two groups of sensors 106 are connected with a group of thimbles 107; the middle part of the detection box 101 is fixedly connected with a heating wire 108.

Earlier control handle 105 no longer carries on spacingly to chamber door 104, make chamber door 104 open, and rotate on third support 103 through third support 103, introduce into heater strip 108 with the straw that straw production facility produced afterwards in, thereby heat the straw through heater strip 108, the straw can be through between two sets of thimbles 107 this moment, thereby straw outer wall screw thread paper can extrude thimble 107, thereby squeeze into sensor 106 with thimble 107, thereby make sensor 106 detect out the distance between the straw outer wall screw thread paper through thimble 107 bounce frequency, thereby detect out whether up to standard straw produced.

As shown in fig. 5-6, the cutting system includes a first transmission rod 201, a second transmission rod 202, a first cutter 203, a chute frame 204, a second support plate 205, a second cutter 206, a fourth bracket 207, and a fifth bracket 208; the first transmission rod 201 is fixedly connected with a power system; the first transmission rod 201 is in transmission connection with the second transmission rod 202; the second transmission rod 202 is in transmission connection with the first cutter 203; the upper end and the lower end of the first cutter 203 are respectively connected with a group of chute frames 204 in a sliding way; the chute frame 204 is fixedly connected with the material distributing system; the two groups of sliding groove frames 204 are fixedly connected with a second support plate 205; the second support plate 205 is fixedly connected with the material distribution system; the side part of the first cutter 203 is provided with a second cutter 206; the second cutter 206 is fixedly connected with the material distribution system; the second support plate 205 is fixedly connected with the fourth bracket 207; the fourth bracket 207 is fixedly connected with the machine plate 1; the second cutter 206 is fixedly connected with the fifth bracket 208; the fifth bracket 208 is fixedly connected with the machine plate 1.

When the straw is required to be cut, the first transmission rod 201 is driven to rotate through the power system, so that the second transmission rod 202 is driven to swing through the first transmission rod 201, the first cutter 203 is driven to slide between the two sets of sliding groove frames 204 through the second transmission rod 202, the straw is cut through mutual matching between the first cutter and the second cutter 206, and the straw with the production quality not reaching the standard is separated.

As shown in fig. 7, the material distributing system includes a material distributing box 301, a material residue discharging port 302, a material distributing plate 303, a material discharging guide plate 304, a support rod 305, a sixth support 306, a seventh support 307, a first electric slide rail 308, a second frame 309, a first electric push rod 3010, a first V-shaped positioning frame 3011 and a second V-shaped positioning frame 3012; the material distribution box 301 is fixedly connected with a residual material discharge hole 302; the material distribution box 301 is fixedly connected with the fourth bracket 207; the residual material outlet 302 is fixedly connected with a residual material collecting system; the inner wall of the material distributing box 301 is fixedly connected with a material distributing plate 303; the material distributing box 301 is fixedly connected with the material discharging guide plate 304; the material distribution box 301 is fixedly connected with a sixth bracket 306; the bottom end of the discharging guide plate 304 is fixedly connected with four groups of supporting rods 305; four groups of supporting rods 305 are fixedly connected with the machine plate 1; the discharging guide plate 304 is fixedly connected with a seventh bracket 307; the top of the sixth bracket 306 is fixedly connected with two groups of first electric slide rails 308; the two groups of first electric slide rails 308 are fixedly connected with a seventh bracket 307; the seventh bracket 307 is fixedly connected with the machine plate 1; the two groups of first electric slide rails 308 are respectively connected with the two groups of second frames 309 in a sliding manner; two groups of the second frames 309 are respectively fixedly connected with a group of first electric push rods 3010; the two groups of second frames 309 are fixedly connected with the first V-shaped positioning frame 3011; the two groups of first electric push rods 3010 are connected with the first V-shaped positioning frame 3011 in a sliding manner; the two groups of first electric push rods 3010 are fixedly connected with the second V-shaped positioning frame 3012; the second V-shaped positioning frames 3012 are slidably connected to the two sets of second frames 309, respectively.

When qualified straws fall onto the material distribution plate 303, because the material distribution plate 303 is arranged into a V shape, the center of the material distribution plate is close to the first frame 6, the gravity center of the straws is deviated to the material discharge guide plate 304, the straws slide into the material discharge guide plate 304, when the straws slide onto the material discharge guide plate 304, the straws incline, at the same time, two groups of first electric push rods 3010 are controlled to simultaneously push the second V-shaped positioning frame 3012 to move downwards, so that the second V-shaped positioning frame 3012 is just positioned at the height of one straw of the material discharge guide plate 304, at the same time, two groups of second frames 309 are controlled to simultaneously slide on two groups of first electric slide rails 308, so that the second V-shaped positioning frame 3012 is driven to move, so that the straws are shifted to be flat, then the straws roll down through the material discharge guide plate 304, so that the spiral paper straw detection device is conveyed, when the length of one straw is not enough to cut a rule, the straws fall onto the material distribution plate 303, at this moment, the gravity center of the suction pipe is deviated to the direction of the first material guide plate 7, so that the suction pipe can slide towards the direction of the first material guide plate 7, the powder box slides into the residual material discharge hole 302, the powder box is conveyed into the residual material collecting system through the residual material discharge hole 302, the produced suction pipe is conveyed out of the spiral paper suction pipe detection method, and meanwhile, the suction pipe with the length not reaching the standard can be classified with the suction pipe.

As shown in fig. 8 to 9, the residue collecting system includes an eighth support 401, a residue collecting box 402, a ninth support 403, a third support plate 404, a second electric slide rail 405, an electric slide plate 406, a U-shaped clamp plate 407, a second material guide plate 408, a support 409 and a material blocking plate 4010; the eighth bracket 401 is fixedly connected with the residual material collecting box 402; the eighth bracket 401 is fixedly connected with the machine plate 1; the residue collecting box 402 is fixedly connected with a ninth bracket 403; the ninth bracket 403 is fixedly connected with the machine plate 1; the eighth bracket 401 and the ninth bracket 403 are both fixedly connected with the third support plate 404; the residual material collecting box 402 is fixedly connected with the residual material discharging port 302; the third support plate 404 is fixedly connected with a second electric slide rail 405; the top of the outer surface of the second electric slide rail 405 is connected with the electric slide plate 406 in a sliding way; the electric sliding plate 406 is fixedly connected with two groups of U-shaped clamping plates 407; the two groups of U-shaped clamping plates 407 are fixedly connected with the second material guide plate 408; the eighth bracket 401 is fixedly connected with the support 409; the support 409 is fixedly connected with the material blocking disc 4010.

When unqualified straws are cut, firstly, the electric slide plate 406 is controlled by the second electric slide rail 405 to slide, so that the electric slide plate 406 drives the U-shaped clamp plate 407 to move, at the moment, the U-shaped clamp plate 407 drives the second material guide plate 408 to move, so that the second material guide plate 408 can receive the straws which do not meet the specification, the straws are attached to the inner wall of the second material guide plate 408 to slide, so that the straws fall into the second material guide plate 408, then, the electric slide plate 406 is controlled by the second electric slide rail 405 to slide in the opposite direction, so that the straws are driven to move towards the direction of the material blocking disc 4010, so that the straws are propped against the straws by the material blocking disc 4010, at the moment, the electric slide plate 406 is controlled by the second electric slide rail 405 to continue to slide in the opposite direction, at the material blocking disc 4010 can block the unqualified straws, so that the straws fall into the scrap collecting box 402, so as to collect the straws, meanwhile, straws with the length less than that of the market straws are conveyed into the residue collecting box 402 through the residue discharging hole 302 and collected through the residue collecting box 402, so that unqualified straws can be collected.

As shown in fig. 10 to 12, the quality control system includes a carrying box 501, a slider 502, a third electric slide rail 503, a third frame 504, a bidirectional threaded rod 505, a first polish rod 506, a second polish rod 507, a fourth support plate 508, a first bevel gear 509, a first sliding plate 5010, a second sliding plate 5011, a tenth bracket 5012, a first limit roller 5013, an eleventh bracket 5014, a second limit roller 5015, a twelfth bracket 5016, and a third limit roller 5017; two ends of the bearing box 501 are fixedly connected with a group of sliding blocks 502; the two sets of sliding blocks 502 are respectively connected with a corresponding set of third electric sliding rails 503 in a sliding manner; the two groups of third electric slide rails 503 are respectively connected with the two groups of third frames 504 through bolts; two groups of third frames 504 are fixedly connected with the machine plate 1; the forward set of third frames 504 are in rotational connection with the powertrain; the front part and the rear part of the bearing box 501 are rotatably connected with a bidirectional threaded rod 505; two sides inside the bearing box 501 are fixedly connected with a first polish rod 506 and a second polish rod 507 respectively; the middle part in the bearing box 501 is fixedly connected with a fourth support plate 508; two sides of the fourth support plate 508 are fixedly connected with the first polish rod 506 and the second polish rod 507 respectively; the bidirectional threaded rod 505 is fixedly connected with the first bevel gear 509; the front part of the outer surface and the rear part of the outer surface of the bidirectional threaded rod 505 are respectively connected with a first sliding plate 5010 and a second sliding plate 5011 through bolts; the first slide plate 5010 is respectively connected with the first polish rod 506 and the second polish rod 507 in a sliding manner; the first bevel gear 509 is engaged with the power system; the second slide plate 5011 is respectively connected with the first polish rod 506 and the second polish rod 507 in a sliding manner; the fourth support plate 508 is fixedly connected with the twelfth bracket 5016; the first sliding plate 5010 is fixedly connected with the tenth bracket 5012; the second sliding plate 5011 is fixedly connected with an eleventh bracket 5014; the tenth bracket 5012 is rotatably connected with the first limit roller 5013; the eleventh bracket 5014 is rotatably connected with the second limit roller 5015; the twelfth bracket 5016 is rotatably connected to the third stopper roller 5017.

When the straw is produced, the straw is limited and conveyed by the third limiting roller 5017, when the detection system detects that the distance between paper rings wound on the outer wall of the straw is overlarge, the first bevel gear 509 is driven to rotate by the power system so as to drive the bidirectional threaded rod 505 to rotate, at the moment, the first sliding plate 5010 and the second sliding plate 5011 are simultaneously driven by the rotating bidirectional threaded rod 505 to simultaneously slide on the first polished rod 506 and the second polished rod 507 in opposite directions so as to drive the tenth bracket 5012 and the eleventh bracket 5014 to move in opposite directions, so that the first limiting roller 5013 and the second limiting roller 5015 are driven to approach to the middle part, the straw is clamped by the first limiting roller 5013, the second limiting roller 5015 and the third limiting roller 5017, the straw is limited, the transmission speed of the straw is reduced, and the speed of the thread paper wound in the straw production equipment is unchanged, so that the distance between the paper rings wound on the straw is recovered to be normal, at this time, the first bevel gear 509 is driven to rotate in the opposite direction by the sixth bevel gear 6019, so that the first limiting roller 5013 and the second limiting roller 5015 no longer limit the straws, and then the slider 502 is controlled to slide to the original position on the third electric slide rail 503, so that the first limiting roller 5013, the second limiting roller 5015 and the third limiting roller 5017 are driven to return to the original position by the carrying box 501, when the detection system detects that the distance between the paper loops wound on the outer wall of the straws is too small, the first limiting roller 5013 and the second limiting roller 5015 continue to clamp and limit the straws, and at the same time, the sliding speed of the slider 502 on the third electric slide rail 503 is controlled to be higher than the speed of the straw production equipment for delivering the straws, so that the distance between the paper loops wound on the straws returns to normal, and after the number of turns of paper wound on the outer wall of the straws returns to normal, the sliding speed of the slider 502 on the third electric slide rail 503 is controlled to be the same as the speed of the straw production equipment for delivering the straws, therefore, the speed of conveying the straws in the straw production equipment is kept unchanged, so that the distance between the circles of the outer wall of the recovered straws wound with paper reaches the standard, and the fifth bevel gear 6015 is driven by the first bevel gear 509 to rotate reversely until the first bevel gear 509 is meshed with the fifth bevel gear 6015, so that the first limiting roller 5013 and the second limiting roller 5015 do not limit the straws any more, and the spiral paper straw detection method can limit the straws after the spiral rings processed by the straw production equipment have deviation, so that the spiral paper righting effect of the outer wall of the straws produced by the straw production equipment is achieved.

As shown in fig. 13, the power system includes a motor 601, a first driving wheel 602, a second driving wheel 603, a first spindle rod 604, a second bevel gear 605, a third bevel gear 606, a fourth bevel gear 607, a shaft sleeve 608, a fifth support plate 609, a second electric push rod 6010, a second spindle rod 6011, a third driving wheel 6012, a fourth driving wheel 6013, a third spindle rod 6014, a fifth bevel gear 6015, a fifth driving wheel 6016, a sixth driving wheel 6017, a fourth spindle rod 6018, and a sixth bevel gear 6019; the motor 601 is fixedly connected with the machine plate 1; an output shaft of the motor 601 is fixedly connected with the first driving wheel 602; the outer surface of the first driving wheel 602 is in transmission connection with a second driving wheel 603 through a belt; the second driving wheel 603 is fixedly connected with the first rotating shaft rod 604; the first rotating shaft 604 is fixedly connected with the second bevel gear 605; the first rotating shaft 604 is rotatably connected to the first frame 6; the first rotating shaft lever 604 is fixedly connected with the first transmission rod 201; a third bevel gear 606 is arranged at the lower part of the second bevel gear 605; the third bevel gear 606 is fixedly connected with the shaft sleeve 608; the fourth bevel gear 607 is fixedly connected with a shaft sleeve 608; the sleeve 608 is rotatably connected with the fifth support plate 609; the fifth support plate 609 is fixedly connected with a second electric push rod 6010; the second electric push rod 6010 is fixedly connected with the machine plate 1; the shaft sleeve 608 is in transmission connection with the second rotating shaft 6011; the second rotating shaft rod 6011 is fixedly connected with a third driving wheel 6012 and a fifth driving wheel 6016 in sequence; the second rotating shaft 6011 is rotatably connected to the machine plate 1; the outer surface of the third driving wheel 6012 is in transmission connection with a fourth driving wheel 6013 through a belt; a fourth driving wheel 6013 is fixedly connected with the third rotating shaft 6014; the third rotating shaft 6014 is fixedly connected with a fifth bevel gear 6015; the third rotating shaft 6014 is rotatably connected to the third frame 504 via a bearing block; the fifth driving wheel 6016 is in driving connection with a sixth driving wheel 6017 through a belt; a sixth driving wheel 6017 is fixedly connected with the fourth rotating shaft 6018; the fourth rotating shaft 6018 is fixedly connected with a sixth bevel gear 6019; the fourth rotating shaft 6018 is rotatably connected to the third frame 504 via a bearing block; the sixth bevel gear 6019 meshes with the first bevel gear 509.

When the suction pipe needs to be cut by the cutting system, the control panel 4 controls the starting motor 601 to drive the first driving wheel 602 to rotate, so that the first driving wheel 602 is driven to rotate by the first driving wheel 602, the first rotating shaft rod 604 is driven to rotate by the second driving wheel 603, so that the second bevel gear 605 is driven to rotate, meanwhile, the cutting system is driven to operate by the first rotating shaft rod 604, when the distance between paper rings wound on the outer wall of the suction pipe is too small, the second electric push rod 6010 is controlled to contract to drive the fifth support plate 609 to move, so that the driving shaft sleeve 608 slides on the second rotating shaft rod 6011, so that the second bevel gear 605 and the fourth bevel gear 607 are meshed with each other, so that the fourth bevel gear 607 is driven to rotate by the second rotating bevel gear 605, and at the moment, the rotating fourth bevel gear 607 drives the shaft sleeve 608 to rotate, then, a rotating shaft sleeve 608 drives a second rotating shaft 6011 to rotate, then, the rotating second rotating shaft 6011 drives a third driving wheel 6012 and a fifth driving wheel 6016 to rotate simultaneously, at this time, a rotating fifth driving wheel 6016 drives a sixth driving wheel 6017 to rotate, so that the sixth driving wheel 6017 drives a sixth bevel gear 6019 to rotate through a fourth rotating shaft 6018, so that the sixth bevel gear 6019 drives a first bevel gear 509 to rotate through the sixth bevel gear 6019, so that the first limiting roller 5013, the second limiting roller 5015 and the third limiting roller 5017 limit the suction pipe, when the distance between the threaded paper rings wound on the outer wall of the suction pipe returns to normal, a second electric push rod 6010 is controlled to push a fifth support plate 609 to move, so that a second bevel gear 605 and a third bevel gear 606 are engaged with each other, so that the third bevel gear 606 drives the fourth bevel gear 607 to rotate in the reverse direction, therefore, the sixth bevel gear 6019 is driven to rotate reversely, so that the first limiting roller 5013, the second limiting roller 5015 and the third limiting roller 5017 do not limit the position of the suction tube any more, when the first bevel gear 509 and the fifth bevel gear 6015 are meshed with each other, the fourth driving wheel 6013 is driven to rotate by the rotating third driving wheel 6012, at the moment, the rotating fourth driving wheel 6013 drives the fifth bevel gear 6015 to rotate by the third rotating shaft 6014, so that the first bevel gear 509 is driven to rotate by the fifth bevel gear 6015, so that the first limiting roller 5013, the second limiting roller 5015 and the third limiting roller 5017 do not limit the position of the suction tube any more, and the cutting system and the quality control system can be driven to work.

Wherein the material distribution plate 303 is arranged in a V-shape with its center near the first frame 6.

The straws meeting the specification length can slide down to the discharging guide plate 304 under the action of the gravity center through the material distributing plate 303, so that the straws not meeting the specification slide down to the residue discharging hole 302, and the separation of the straws not meeting the specification length is realized.

Wherein, the second material guide plate 408 is arranged in an arc shape.

The straws with inconsistent space between the outer paper rings can slide along the second guide plate 408, so that the straws can be conveyed into the residue collecting box 402 by the second guide plate 408.

Wherein, the sensor 106 is internally provided with a rear elastic member.

The thimble 107 can be restored to the original position, so that the thimble 107 can detect the straws all the time.

The spiral paper straw detection method comprises the following steps:

the method comprises the following steps: detecting the density of the suction tube thread paper, and detecting the suction tube outer ring thread paper through a detection system;

step two: cutting the suction pipe, and cutting the suction pipe into a finished product through a cutting system;

step three: waste materials are collected, and waste straws and straws with insufficient length are collected through a residual material collecting system.

The above-mentioned embodiments are merely preferred embodiments of the present invention, which are not intended to limit the scope of the present invention, and therefore, all equivalent changes made by the contents of the claims of the present invention should be included in the claims of the present invention.