CN114407565A - Sign impression device of smooth helical bellows of inner wall - Google Patents

Abstract

The invention discloses a mark imprinting device of a spiral corrugated pipe with a smooth inner wall, which comprises a main body frame, a flexible nondestructive contact type conveying mechanism, a spraying heating pretreatment mechanism, a surrounding nondestructive imprinting mechanism, an air-liquid mixed cooling mechanism, a wrapping type and wheel disc combined packaging mechanism, an air-cooled low-temperature cutting mechanism and a control mechanism. The invention belongs to the field of mark imprinting, and particularly relates to a mark imprinting device for a spiral corrugated pipe with a smooth inner wall.

Description

Sign impression device of smooth helical bellows of inner wall

Technical Field

The invention belongs to the technical field of mark imprinting, and particularly relates to a mark imprinting device for a spiral corrugated pipe with a smooth inner wall.

Background

The corrugated pipe is a wave-like pipe with a regular shape, is mainly used for connecting the pipeline with the pipeline at the position where the pipeline is required to be stretched or is inconvenient to install by a fixed elbow, and can be bent, slightly stretched or compressed.

The method is continuously updated, and the final purpose is to demand a marking method with low cost, low consumption and convenient operation, wherein handwriting is influenced by personal factors, characters are inconsistent, handwriting is not standard, and the whole is not beautiful; the problems of character strip jet printing are as follows: the operation is inconvenient, two-person operation is needed, self-spraying paint is needed, the health of people is influenced for a long time, the printed characters are difficult to control, the phenomena of inconsistent character definition, paint ink accumulation and the like frequently occur, the printing quality is influenced, and the manufactured character bars are easy to break, so that the character bars are frequently replaced; the handheld ink-jet printer can achieve the aims of consistent fonts, standard handwriting and attractive appearance of the whole body, but has high input cost, expensive and easily damaged consumables, inconvenient after-sale maintenance and long period; problems with laser marking machines: 1. the marked mark on the pipe is gray, and the handwriting is regular and clear but not obvious; 2. the production line is dispersed, the movement and the use are inconvenient, and the manufacturing cost is high; 3. the equipment needs to be moved frequently in the using process, and the focusing is inconvenient.

Therefore, there is a strong need for an imprint apparatus that is easy to operate, easy to maintain, and low in cost.

Disclosure of Invention

Aiming at the situation and overcoming the defects of the prior art, the invention provides a mark imprinting device of a spiral corrugated pipe with a smooth inner wall, which adopts a mode of spraying styrene thermoplastic elastomer in advance and heating imprinting according to the contradictory characteristic that the corrugated pipe is damaged if the imprinting is clear during the imprinting of the corrugated pipe, utilizes the characteristics of stability, controllability and high efficiency of light wave heating, realizes the technical effect of nondestructive imprinting the mark on the corrugated pipe, solves the contradictory technical problem that the clear and durable mark can be imprinted without damaging the pipe wall, solves the problem that the imprinting type of the corrugated pipe is easy to slide, utilizes the characteristics of flexibility and skid resistance of a flexible air bag, realizes the technical effect of flexible skid resistance, nondestructive bearing and transporting the corrugated pipe, and achieves the effects of cooling, cleaning and heating the corrugated pipe, drying the outer wall of the corrugated pipe and recycling cooling liquid through an air-liquid cooling and circulating system, the whole device is simple to operate, the production line is integrated, and the corrugated pipes with different calibers are adaptive to imprinting.

The technical scheme adopted by the invention is as follows: the invention provides an identification imprinting device of a spiral corrugated pipe with a smooth inner wall, which comprises a main body frame, a flexible lossless contact type conveying mechanism, a spraying heating pretreatment mechanism, a surrounding lossless imprinting mechanism, a wind-liquid mixed cooling mechanism, a wrapping and wheel disc combined packaging mechanism, an air-cooled low-temperature cutting mechanism and a control mechanism, wherein the flexible lossless contact type conveying mechanism, the spraying heating pretreatment mechanism, the surrounding lossless imprinting mechanism, the wind-liquid mixed cooling mechanism, the wrapping and wheel disc combined packaging mechanism and the air-cooled low-temperature cutting mechanism are sequentially arranged on the main body frame from left to right; the flexible lossless contact type conveying mechanism comprises a conveying mechanism shell and a telescopic lossless flexible contact type conveying device, the conveying mechanism shell is arranged on a main body framework, the telescopic lossless flexible contact type conveying device is annularly and uniformly arranged on the inner side wall of the conveying mechanism shell at intervals, the telescopic lossless flexible contact type conveying device comprises a hydraulic telescopic arm, a trapezoidal fixed block, a rubber belt energy supply motor, a rubber belt driving wheel, a transmission rubber belt, a fixed nut group, a fixed disc A, a fixed disc B, a rotating disc, a fixed screw group and a fixed rotating shaft, the hydraulic telescopic arm is arranged on the inner wall of the conveying mechanism shell, the trapezoidal fixed block is arranged at the movable end of the hydraulic telescopic arm, the fixed rotating shaft is rotatably arranged on the trapezoidal fixed block, the rubber belt energy supply motor is arranged on the trapezoidal fixed block, the rubber belt driving wheel is arranged on the fixed rotating shaft, the transmission rubber belt is sleeved on the rubber belt energy supply motor and the rubber belt transmission wheel, the fixed disc A is arranged on a fixed rotating shaft, the fixed disc B is arranged on the fixed rotating shaft, the rotating disc is provided with a cylindrical flexible bag, the fixed disc A is arranged on the right side of the rotating disc, the fixed disc B is arranged on the left side of the rotating disc, the fixed screw is assembled on the fixed disc B, the fixed nut is assembled on the fixed disc A, when the transmission rubber belt works, the hydraulic telescopic arm is adjusted to adapt to a corrugated pipe with a non-caliber at the same time, the cylindrical flexible bag has good friction and support, and the corrugated pipe can be transported while being well protected; the telescopic nondestructive flexible contact transportation device is provided with six groups.

Further, the spraying and heating pretreatment mechanism comprises a pretreatment mechanism shell, an annular rotating wheel, a gear energy supply device, a pretreatment material spraying device and a light wave heating device, the pretreatment mechanism shell is arranged on the main body frame, the gear energy supply device is arranged in the pretreatment mechanism shell, the annular rotating wheel is connected with the gear energy supply device, the pretreatment material spraying device is arranged on the annular rotating wheel, the light wave heating device is arranged on the annular rotating wheel, during work, the gear energy supply device drives the annular rotating wheel to rotate, the pretreatment material spraying device and the light wave heating device rotate along with the annular rotating wheel, the pretreatment material spraying device firstly sprays hot melt materials on the outer wall of the corrugated pipe, then the light wave heating device starts to heat when rotating to the position of the hot melt materials, and only 360 degrees of rotation are needed to complete pretreatment before impression, the pretreatment time is greatly reduced, and meanwhile, the spraying pretreatment can not damage the outer wall of the corrugated pipe, so that the quality of a finished product is ensured; the gear energy supply device is provided with six groups, the structures of the six groups are completely the same, and the six groups are arranged in an annular array; the pretreatment material spraying devices are provided with two groups, have the same structure and are arranged in an annular array; the optical wave heating devices are provided with two groups, have the same structure and are arranged in an annular array; gear energy supply device includes transmission toothed disc, conical gear G, toothed disc fixed axle, toothed disc energy supply motor and motor gear G, the toothed disc fixed axle is located on the preliminary treatment mechanism shell, conical gear G is located on the toothed disc fixed axle, the transmission toothed disc is located on the toothed disc fixed axle, toothed disc energy supply motor is located on the preliminary treatment mechanism shell, motor gear G is located on the toothed disc energy supply motor, motor gear G links to each other with conical gear G meshing.

Further, light wave heating device includes light wave heater and flexible braced system A, flexible braced system A locates on the annular rotates the wheel inside wall, light wave heater locates on the flexible braced system A, flexible braced system A includes the fixed head, adjusts the rotor arm, folding flexible arm, the spacing box of flexible arm, axle A, axle B and axle C, the fixed head is located on the annular rotates the wheel, axle A locates on the fixed head, adjust the rotor arm and locate axle A's one end, axle B locates and adjusts the rotor arm middle part, the other end of adjusting the rotor arm is located to axle C, the spacing box of flexible arm is located on the annular rotates the wheel, the spacing box of flexible arm is located to folding flexible arm's one end in the spacing box of flexible arm, the other end of folding flexible arm is located on axle B, light wave heater locates on the axle C.

Further, the pretreatment material spraying device comprises a double-pipe sprayer and a telescopic supporting system B, the telescopic supporting system B is arranged on the annular rotating wheel, and the double-pipe sprayer is arranged on the telescopic supporting system B; the telescopic supporting system B and the telescopic supporting system A are identical in structure.

Further, the encircling type lossless stamping mechanism comprises a stamping mechanism shell, an energy supply gear, a transmission gear set, a telescopic encircling type stamping assembly, an encircling contact type auxiliary fixed stamping assembly A and an encircling contact type auxiliary fixed stamping assembly B, wherein the stamping mechanism shell is arranged on the main body frame, the energy supply gear is arranged on the stamping mechanism shell, the transmission gear set is arranged between the energy supply gears, the telescopic encircling type stamping assembly is arranged on the transmission gear set, the encircling contact type auxiliary fixed stamping assembly A is arranged on the transmission gear set, the encircling contact type auxiliary fixed stamping assembly B is arranged on the transmission gear set, during stamping, the working mode of the telescopic encircling type stamping assembly is stamping, a specially-made plug to be stamped is inserted into the telescopic encircling type stamping assembly, the encircling contact type auxiliary fixed stamping assembly A and the encircling contact type auxiliary fixed stamping assembly B are arranged in an auxiliary fixing mode, the impression can be completed only by rotating a circle during the impression, the impression time is greatly reduced, and meanwhile, the telescopic structure can be used for impressing corrugated pipes with different calibers, so that the equipment replacement cost is reduced.

Furthermore, the energy supply gears are six groups, have the same structure and are arranged in an annular array.

Furthermore, the telescopic surrounding type embossing assembly comprises a linkage type self-adaptive supporting system A and a multipurpose roller, the linkage type self-adaptive supporting system A is arranged on the transmission gear set, and the multipurpose roller is arranged on the linkage type self-adaptive supporting system A; the linkage type self-adaptive support system A comprises a shaft D, a square thick telescopic arm A, a limiting sheet A, a square thin telescopic arm A, a shaft E, a cylindrical telescopic arm, a limiting sheet B, a square thin telescopic arm B, a square thick telescopic arm B, a bevel gear A, a shaft F, a small bevel gear and a stamping wheel energy supply motor, wherein the shaft E is arranged on a transmission gear set, the shaft F is arranged on the transmission gear set, one end of the square thick telescopic arm A is arranged on the shaft F, one end of the shaft D is arranged at the other end of the square thick telescopic arm A, one end of the square thin telescopic arm A is arranged on the shaft E, the other end of the square thin telescopic arm A is arranged on the shaft D, one end of the limiting sheet A is arranged on the shaft E, the small bevel gear is arranged on the shaft D, the stamping wheel energy supply motor is arranged on the square thin telescopic arm A, and the bevel gear A is arranged on the stamping wheel energy supply motor, simultaneously conical tooth wheel A and small-size conical tooth wheel meshing, on axle F was located to spacing thin slice A's the other end, on axle E was located to the one end of the flexible arm of cylindricality, on axle F was located to the other end of the flexible arm of cylindricality, axle D middle part was located to the multi-purpose type gyro wheel axle E was located to spacing thin slice B's one end, on axle F was located to spacing thin slice B's the other end, on axle E was located to the one end of square thin flexible arm B, on axle D was located to the other end of square thin flexible arm B, on axle F was located to the one end of square thick flexible arm B, on the other end of axle D was located to the other end of square thick flexible arm B.

Furthermore, the encircling contact type auxiliary fixed imprinting assembly A comprises a linkage type self-adaptive supporting system B and a supporting concave wheel, wherein the linkage type self-adaptive supporting system B is arranged on the transmission gear set, and the supporting concave wheel is arranged on the linkage type self-adaptive supporting system B; the linkage type self-adaptive support system B and the linkage type self-adaptive support system A are identical in structure, and the surrounding contact type auxiliary fixed embossing assembly A and the surrounding contact type auxiliary fixed embossing assembly B are identical in structure.

Further, the mixed cooling body of geomantic omen liquid is including transportation fixing device, coolant liquid circulation heat sink and the dry cleaning device of blowing formula, transportation fixing device locates on the main body frame upper wall, coolant liquid circulation heat sink and dry cleaning device of blowing formula locate respectively on the transportation fixing device.

Further, transportation fixing device includes unable adjustment base, over-and-under type nondestructive support transport arm A and over-and-under type nondestructive support transport arm B, unable adjustment base sets firmly on the main body frame upper wall, unable adjustment base front end upper wall is located to over-and-under type nondestructive support transport arm A, unable adjustment base rear end upper wall is located to over-and-under type nondestructive support transport arm B, coolant liquid circulation heat sink and blow dry cleaning device locate respectively between over-and-under type nondestructive support transport arm A and the harmless transport arm B of over-and-under type.

Further, the lifting type nondestructive supporting transport arm A comprises a supporting telescopic arm, an installation base, a supporting energy supply motor, a supporting thin wall, a supporting fixed shaft, a supporting disc transmission gear, a gear protection shell, a conical gear E, a supporting disc and a flexible ball bag, wherein the supporting telescopic arm is arranged on the fixed base, the installation base is arranged on the supporting telescopic arm, the supporting energy supply motor is arranged on the installation base, the supporting thin wall is arranged on the installation base, the supporting fixed shaft is arranged on the supporting thin wall, the supporting disc transmission gear is arranged on the supporting fixed shaft, the conical gear E is arranged on the supporting energy supply motor, the supporting disc transmission gear is meshed with the conical gear E, the supporting disc is arranged on the supporting fixed shaft, the flexible ball bag is annularly and uniformly arranged on the circumferential side wall of the outer side of the supporting disc at intervals, and the supporting telescopic arm is lifted to the height of the outer wall of the corrugated pipe which can be contacted when in work, at the moment, the flexible saccule is in contact with the outer wall of the corrugated pipe, then the energy supply motor is supported to drive the support disc to rotate, the conveying of the corrugated pipe is started to advance between the devices, and the flexible saccule has a good contact area on the pipe wall, so that the pipe is prevented from being damaged while the stable transportation is ensured; the lifting type nondestructive support transport arm B and the lifting type nondestructive support transport arm A are completely the same in structure.

Furthermore, the cooling liquid circulating and cooling device comprises a cooling liquid collecting and transporting pipe, a cooling liquid collecting square pool, a pressure pump, a cooling liquid circulating and processing system, a supporting stand column, a cooling liquid discharging pipe, a cooling liquid spray head, a cooling head telescopic arm, a contraction type corrugated pipe and a top fixing plate from bottom to top, wherein the cooling liquid collecting square pool is arranged on the fixed base, the cooling liquid circulating and processing system is arranged on the fixed base, the supporting stand column is arranged on the fixed base, the top fixing plate is arranged on the supporting stand column, the contraction type corrugated pipe is arranged on the bottom wall of the top fixing plate, the cooling liquid spray head is arranged on the contraction type corrugated pipe, cooling liquid is sprayed out from the cooling liquid spray head to cool the pipe wall after imprinting, one end of the cooling head telescopic arm is arranged on the bottom wall of the top fixing plate, and the other end of the cooling head telescopic arm is arranged on the cooling liquid spray head, one end of the cooling liquid collecting and conveying pipe is arranged at the bottom end of the side wall of the cooling liquid collecting square pool in a penetrating manner, the other end of the cooling liquid collecting and conveying pipe is arranged on the cooling liquid circulating treatment system in a penetrating manner, the pressure pump is arranged on the fixed base and is connected with the cooling liquid collecting and conveying pipe in a penetrating manner, one end of the cooling liquid discharging pipe is arranged on the cooling liquid circulating treatment system in a penetrating manner, and the other end of the cooling liquid discharging pipe is connected with the contraction type corrugated pipe in a penetrating manner; coolant liquid circulation processing system includes suction pump, coolant liquid hutch, piece filtration collection room and circulation system shell, the circulation system shell is located on unable adjustment base, the coolant liquid hutch is located in the circulation system shell, the piece filters and collects the room and locates on the coolant liquid hutch, the suction pump is located coolant liquid hutch top, the suction pump is located on the coolant liquid discharge pipe, and the coolant liquid that the coolant liquid was collected in the square pool and is collected discharge to coolant liquid circulation processing system, filters the back and goes into the coolant liquid shower nozzle again to the coolant liquid, accomplishes the coolant liquid circulation, has both accomplished timely cooling, can reduce the coolant liquid again extravagant, has practiced thrift the cost.

Further, blow dry cleaning device of formula of blowing includes fan motor, piece recovery pond, prevent wind backup pad, fan fixed roof and horizontal fan, prevent wind the backup pad and locate on unable adjustment base, prevent that the garrulous bits recovery pond is located on unable adjustment base, the fan fixed roof is located and is prevented wind in the backup pad, fan motor locates on the fan fixed roof, horizontal fan locates on fan motor, and on the during operation, horizontal fan rotates, blows in the piece recovery pond with the remaining piece in the pipe wall outside and liquid, prevents to pollute operational environment.

Further, parcel formula and rim plate combination packagine machine construct including singly supporting conveyer, packaging film fixing device, bottom paste device and supplementary packing plant, singly support the conveyer and locate on the main body frame, packaging film fixing device locates on singly supporting the conveyer, the bottom pastes the device and locates on singly supporting the conveyer, supplementary packing plant locates on the bottom pastes the device.

Furthermore, the single-support conveying device comprises a packaging mechanism base and a lifting type nondestructive supporting conveying arm C, wherein the packaging mechanism base is arranged on the main body framework, and the lifting type nondestructive supporting conveying arm C is arranged on the packaging mechanism base; the packaging film fixing device comprises a packaging support column, a packaging film rotating shaft and a packaging film fixing shaft, the packaging support column is arranged on a packaging mechanism base, the packaging film rotating shaft is arranged on the packaging support column, the packaging film fixing shaft is arranged on the packaging film rotating shaft, and when the packaging film fixing device works, packaging films of different materials and lengths can be arranged on the packaging film fixing shaft according to requirements; the lifting type nondestructive support transportation arm C and the lifting type nondestructive support transportation arm A are completely the same in structure.

Further, the bottom pasting device comprises a square energy supply box, a sliding limiting plate, a U-shaped sliding frame, a vertical telescopic arm, a horizontal rotating disc, a transmission chamber, a threaded rotating shaft, a square limiting shaft rotating block, a horizontal threaded shaft transmission bevel gear, a horizontal threaded shaft motor, a bevel gear B, a small motor, a small gear, a small transmission shaft and a sliding wheel, wherein the square energy supply box is arranged on a base of the packaging mechanism, the horizontal threaded shaft motor is arranged in the square energy supply box, one end of the threaded rotating shaft is arranged on the square energy supply box, the sliding limiting plate is arranged on the square energy supply box, the square limiting shaft rotating block is arranged in the middle of the sliding limiting plate, the other end of the threaded rotating shaft is arranged on the square limiting shaft rotating block, a sliding limiting groove is arranged on the sliding limiting plate, the U-shaped sliding frame is arranged on the threaded rotating shaft, the U-shaped sliding frame is meshed with the threaded rotating shaft, the sliding wheel is rotatably arranged on the U-shaped sliding frame, the sliding wheel is clamped and slidably arranged in the sliding limiting groove, the U-shaped sliding frame is slidably connected with the sliding limiting plate through the sliding wheel, the vertical telescopic arm is arranged on the upper wall of the U-shaped sliding frame, the transmission chamber is arranged on the vertical telescopic arm, the small motor is arranged on the bottom wall of the inner side of the transmission chamber, the small transmission shaft is rotatably arranged in the transmission chamber, the small transmission gear is arranged on the small transmission shaft, the small gear is arranged on the small motor, the small transmission gear is meshed with the small gear, the horizontal rotating disc is arranged on the small transmission shaft, when the U-shaped sliding frame works, the vertical telescopic arm rises, meanwhile, the horizontal position of the U-shaped sliding frame is adjusted by the cooperation of the horizontal threaded shaft motor, and the two ends of the horizontal rotating disc, which are positioned in the middle of the corrugated pipe, are tightly attached to a packaging film for wrapping the corrugated pipe, along with the bellows constantly sends into, the small-size motor drives horizontal rotating disc and rotates, and vertical flexible arm begins to descend and horizontal screw shaft motor cooperation adjustment U type sliding frame is close to the limiting plate middle part that slides simultaneously, and the outer wall of lower part in the bellows is drawn close to the packaging film outside to horizontal rotating disc, and when horizontal rotating disc reachd the bellows bottom, horizontal rotating disc hugs closely and pastes the bellows left and right sides packaging film, reaches the purpose of packing.

Further, supplementary packing plant includes fixed frame, the flexible arm of level, arc auxiliary arm, rolling ball and rolling ball bearing, fixed frame erects on square energy supply box, the flexible arm of level is located on the fixed frame, the expansion end of the flexible arm of level is located to the arc auxiliary arm, the rolling ball bearing is located on the arc auxiliary arm, on the rolling ball bearing was located to the rolling ball, the flexible arm of during operation level constantly extended, and supplementary packaging film covers the bellows first part, and the packaging film residual part of not wrapping up the bellows is flagging naturally, avoids the packaging film skew in supplementary packing.

Further, the air-cooled low-temperature cutting mechanism comprises a cluster type blowing device, a lifting type cutting device and a cutting base, wherein the cutting base is arranged on the main body frame, the lifting type cutting device is arranged on the cutting base, and the cluster type blowing device is arranged on the lifting type cutting device.

Further, the cluster type blowing device comprises an air pump shell, a cylindrical air pump, an air guide tube and a cluster air outlet, wherein the air pump shell is arranged on the lifting type cutting device, the cylindrical air pump is arranged in the air pump shell, the air guide tube is arranged on the cylindrical air pump, and the cluster air outlet is arranged on the air guide tube.

Further, the lifting type cutting device comprises a cutting mechanism shell, a vertical threaded shaft energy supply motor, a threaded shaft transmission bevel gear, a vertical threaded shaft, a vertical limiting shaft, a cutting strip fixing box, a cutting chain saw, a cutting transmission wheel disc, a cutting disc rotating shaft, a chain saw energy supply motor, a chain saw transmission bevel gear, a bevel gear C and a bevel gear D, wherein the cutting mechanism shell is arranged on the cutting base, the vertical threaded shaft energy supply motor is arranged on the cutting mechanism shell, the vertical threaded shaft is rotatably arranged on the cutting mechanism shell, the vertical limiting shaft is arranged on the cutting mechanism shell, the threaded shaft transmission bevel gear is arranged on the vertical threaded shaft, the bevel gear C is arranged on the vertical threaded shaft energy supply motor, the threaded shaft transmission bevel gear is meshed with the bevel gear C, and the cutting strip fixing box is arranged on the vertical threaded shaft, cutting strip fixed box links to each other with vertical type screw shaft meshing, cutting strip fixed box cup joints the slip and locates vertical spacing epaxially, vertical spacing axle plays the effect of spacing direction to cutting strip fixed box, chain saw energy supply motor is located in the cutting strip fixed box, in cutting strip fixed box is located in the cutting dish pivot rotation, chain saw transmission conical gear locates in the cutting dish pivot, conical gear D locates on the chain saw energy supply motor, chain saw transmission conical gear simultaneously with conical gear D cutting drive wheel dish is located in the cutting dish pivot, the cutting chain saw cup joints to rotate and locates on the cutting drive wheel dish, and during operation, cutting strip fixed box from the bottom up cuts the bellows, and the while bundling type blows the device and cools off and the piece blows the clearance to the bellows.

The invention with the structure has the following beneficial effects: the scheme provides an identification imprinting device of a spiral corrugated pipe with a smooth inner wall, according to the contradictory characteristic that corrugated pipe damage can be caused if imprinting is clear during corrugated pipe imprinting, a mode of spraying styrene thermoplastic elastomer in advance and heating imprinting is adopted, the characteristics of stability, controllability and high efficiency of light wave heating are utilized, the technical effect of nondestructive imprinting identification of the corrugated pipe is realized, the contradictory technical problem that the pipe wall is not damaged while clear and durable identification can be imprinted is solved, in order to solve the problem that the corrugated pipe is easy to slide in an imprinting mode, the technical effect of flexibly, skid-proof and nondestructive bearing and transportation of the corrugated pipe is realized by utilizing the characteristics of flexibility and skid resistance of a flexible air bag, the effect that the corrugated pipe after cooling, cleaning and heating can be cooled, the outer wall of the corrugated pipe can be dried, and the cooling liquid can be recycled is realized through an air-liquid cooling circulation system, the operation of the whole device is simple, The production line is integrated and is adaptive to the imprinting of corrugated pipes with different calibers.

Drawings

FIG. 1 is a schematic structural view of a mark embossing device of a spiral corrugated pipe with a smooth inner wall according to the present invention;

FIG. 2 is a schematic view of a part of the structure of a mark embossing device of a spiral corrugated pipe with smooth inner wall according to the present invention;

FIG. 3 is a schematic view of a flexible lossless contact transfer mechanism of the present invention;

FIG. 4 is an exploded view of the telescopic nondestructive flexible contact transportation device of the present invention;

FIG. 5 is a schematic view of a circular type non-destructive embossing mechanism according to the present invention;

FIG. 6 is a partial structural view of the ring press of the present invention

FIG. 7 is a schematic view of a light wave heating apparatus according to the present invention;

FIG. 8 is a schematic view of a pretreatment material spray apparatus of the present invention;

FIG. 9 is a schematic view of a wrap-around non-destructive embossing mechanism of the present invention;

FIG. 10 is a schematic view of a part of the structure of the surrounding type nondestructive imprinting mechanism of the present invention;

FIG. 11 is an exploded view of the coordinated type lossless adaptive imprinting apparatus of the present invention;

FIG. 12 is a schematic view of a wind-liquid hybrid cooling mechanism according to the present invention;

FIG. 13 is a schematic view of a blowing type drying and cleaning device according to the present invention;

FIG. 14 is a schematic view of the wrapping and wheel disc combination packing mechanism of the present invention;

FIG. 15 is a schematic view of the bottom applicator mechanism of the present invention;

FIG. 16 is a schematic structural view of a part of the mechanism of the bottom pasting device of the present invention;

FIG. 17 is a cross-sectional view of a U-shaped slide frame construction of the present invention;

FIG. 18 is a cross-sectional view of the arcuate auxiliary arm structure of the present invention;

FIG. 19 is a schematic view of the gas-cooled cryogenic cutting mechanism of the present invention;

FIG. 20 is a cross-sectional view of the air cooled cryogenic cutting mechanism of the present invention;

FIG. 21 is a cross-sectional view of the cutting strip retention cartridge of the present invention;

FIG. 22 is a schematic structural view of an elevating type nondestructive supporting transportation arm A of the present invention;

FIG. 23 is a schematic view of a coolant circulation system according to the present invention;

FIG. 24 is a schematic diagram of a partial structure of the gas-cooled cryogenic cutting mechanism of the present invention.

Wherein, 1, a main body frame, 2, a flexible lossless contact type transmission mechanism, 3, a spraying heating pretreatment mechanism, 4, a surrounding lossless impressing mechanism, 5, an air-liquid mixing cooling mechanism, 6, a wrapping type and wheel disc combined packaging mechanism, 7, an air-cooled low-temperature cutting mechanism, 8, a control mechanism, 101, a transmission mechanism shell, 102, a telescopic lossless flexible contact transportation device, 108, a hydraulic telescopic arm, 109, a trapezoidal fixed block, 110, a rubber belt energy supply motor, 111, a rubber belt transmission wheel, 112, a transmission rubber belt, 113, a fixed nut group, 114, a fixed disk A, 115, a rotating disk, 116, a cylindrical flexible bag, 117, a fixed screw group, 118, a fixed rotating shaft, 119, a fixed disk B, 201, a pretreatment mechanism shell, 202, an annular rotating wheel, 203, a pretreatment material spraying device A, 204, a light wave heating device A, 205 and a pretreatment material spraying device B, 206. light wave heating devices B, 207, gear energy supply devices, 208, transmission gear discs, 209, bevel gears G, 210, gear disc fixing shafts, 211, gear disc energy supply motors, 212, motor gears G, 213, fixing heads, 214, adjusting rotating arms, 215, folding telescopic arms, 216, telescopic arm limiting boxes, 217, light wave heaters, 218, shafts A, 219, shafts B, 220, shafts C, 221, telescopic supporting systems A, 222, telescopic supporting systems B, 223, double-pipe sprayers, 301, stamping mechanism shells, 302, transmission gear sets, 303, energy supply gears A, 304, energy supply gears B, 305, energy supply gears C, 306, telescopic encircling stamping components, 307, encircling contact auxiliary fixed stamping components A, 308, encircling contact auxiliary fixed stamping components B, 309, shafts D, 310, square thick telescopic arms A, 311, limiting sheets A, 312, square thin telescopic arms A, 313. shafts E, 314, a cylindrical telescopic arm, 315, limiting sheets B, 316, square thin telescopic arms B, 317, square thick telescopic arms B, 318, a multipurpose roller, 319, shafts F, 320, a small-sized bevel gear, 321, an impression wheel energy supply motor, 322, a bevel gear A, 323, a linkage type self-adaptive support system A, 324, a support concave wheel, 325, a linkage type self-adaptive support system B, 401, a transportation fixing device, 402, a cooling liquid circulating cooling device, 403, a blowing type drying and cleaning device, 404, a fixing base, 405, lifting type nondestructive support transportation arms A, 406, lifting type nondestructive support transportation arms B, 407, a cooling liquid collection and transportation pipe, 408, a cooling liquid collection square pool, 409, a pressure pump, 410, a cooling liquid circulating processing system, 411, a support upright post, 412, a cooling liquid discharge pipe, 413, a cooling liquid spray head, 414 and a cooling head telescopic arm, 415. a contraction type corrugated pipe, 416, a top fixing plate, 417, a windproof supporting plate, 418, a fan fixing top plate, 419, a horizontal fan, 420, a debris recovery pool, 421, a fan motor, 422, a water pump, 423, a cooling liquid storage box, 424, a debris filtering and collecting chamber, 425, a circulating system shell, 501, a single-support conveying device, 502, a packaging film fixing device, 503, a bottom pasting device, 504, an auxiliary packaging device, 505, a packaging mechanism base, 506, an elevating type nondestructive supporting and conveying arm C, 507, a packaging supporting column, 508, a packaging film rotating shaft, 509, a packaging film fixing shaft, 510, a square energy supply box, 511, a sliding limiting plate, 512, a U-shaped sliding frame, 513, a vertical telescopic arm, 514, a horizontal rotating disc, 515, a transmission chamber, 516, a threaded rotating shaft, 517, a square limiting shaft rotating block, 518, a horizontal threaded shaft transmission bevel gear, 519. a horizontal screw shaft motor 520, a small motor 521, a small transmission gear 522, a small transmission shaft 523, a sliding wheel 524, a fixed frame 525, a horizontal telescopic arm 526, an arc auxiliary arm 527, a rotating ball 528, a rotating ball bearing 529, a bevel gear B, 530, a small motor gear 601, a cluster type blowing device 602, a lifting type cutting device 603, a cutting base 604, an air pump housing 605, a cylindrical air pump 606, an air duct 607, a cluster air outlet 608, a cutting mechanism housing 609, a vertical screw shaft energy supply motor 610, a screw shaft transmission bevel gear 611, a vertical screw shaft 612, a vertical limit shaft 613, a cutting strip fixing box 614, a cutting chain saw 615, a cutting transmission wheel disc 616, a cutting disc rotating shaft 617, a chain saw energy supply motor 618, a chain saw transmission bevel gear 619, a bevel gear C, 620. the device comprises a bevel gear D, 701, a support telescopic arm, 702, an installation bottom table, 703, a support energy supply motor, 704, a support fixing shaft, 705, a support disc transmission gear, 706, a gear protection shell, 707, a support disc, 708, a flexible balloon, 709, a support thin wall, 710 and a bevel gear E.

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

Detailed Description

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

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus should not be construed as limiting the present invention.

As shown in fig. 1 and fig. 2, the mark imprinting device for the helical bellows with smooth inner wall provided by the invention comprises a main body frame 1, a flexible nondestructive contact type conveying mechanism 2, a spraying heating pretreatment mechanism 3, a surrounding nondestructive imprinting mechanism 4, an air-liquid mixing and cooling mechanism 5, a wrapping type and wheel disc combined packaging mechanism 6, an air-cooling low-temperature cutting mechanism 7 and a control mechanism 8, wherein the flexible nondestructive contact type conveying mechanism 2 is arranged at the left end of the main body frame 1, the spraying heating pretreatment mechanism 3 is arranged on the main body frame 1, the spraying heating pretreatment mechanism 3 is simultaneously arranged at the right side of the flexible nondestructive contact type conveying mechanism 2, the surrounding nondestructive imprinting mechanism is arranged on the main body frame 1, the surrounding imprinting mechanism is simultaneously arranged at the right side of the spraying heating pretreatment mechanism 3, and the air-liquid mixing and cooling mechanism 5 is arranged on the main body frame 1, the air-liquid mixed cooling mechanism 5 is arranged on the right side of the surrounding type nondestructive stamping mechanism, the wrapping type and wheel disc combined packaging mechanism 6 is arranged on the main body frame 1, the wrapping type and wheel disc combined packaging mechanism 6 is arranged on the right side of the air-liquid mixed cooling mechanism 5, the air-cooled low-temperature cutting mechanism 7 is arranged on the main body frame 1, and the air-cooled low-temperature cutting mechanism 7 is arranged on the right side of the wrapping type and wheel disc combined packaging mechanism 6.

As shown in fig. 3, the flexible nondestructive contact type transfer mechanism 2 includes a transfer mechanism casing 101 and a telescopic nondestructive flexible contact transportation device 102. the transfer mechanism casing 101 is provided on the main body frame 1, and the telescopic nondestructive flexible contact transportation device 102 is provided on the transfer mechanism casing 101.

As shown in fig. 3 and 4, the telescopic nondestructive flexible contact transportation device 102 includes a hydraulic telescopic arm 108, a trapezoid fixing block 109, a rubber belt energy supply motor 110, a rubber belt driving wheel 111, a transmission rubber belt 112, a fixing nut set 113, a fixing disk a114, a fixing disk B119, a rotating disk 115, a cylindrical flexible bag 116, a fixing screw set 117, and a fixing rotating shaft 118, wherein the hydraulic telescopic arm 108 is disposed on the transmission mechanism casing 101, the trapezoid fixing block 109 is disposed on the hydraulic telescopic arm 108, the fixing rotating shaft 118 is disposed on the trapezoid fixing block 109, the rubber belt driving wheel 111 is disposed on the fixing rotating shaft 118, the fixing disk a114 is disposed on the fixing rotating shaft 118, the fixing disk B119 is disposed on the fixing rotating shaft 118, the rubber belt energy supply motor 110 is disposed on the trapezoid fixing block 109, the transmission rubber belt 112 is disposed on the rubber belt energy supply motor 110, the transmission rubber belt 112 is disposed on the rubber belt driving wheel 111 at the same time, the cylindrical flexible bag 116 is arranged on the rotating disc 115, the fixing screw group 117 is arranged on the fixing disc B119, the fixing nut group 113 is arranged on the fixing screw group 117, and the fixing nuts are simultaneously arranged on the fixing disc A114; the telescopic nondestructive flexible contact transportation device 102 is of a bilateral symmetry structure.

As shown in fig. 5 and 6, the spraying and heating pretreatment mechanism 3 includes a pretreatment mechanism housing 201, an annular rotary wheel 202, a gear power supply device 207, a pretreatment material spraying device a203, a pretreatment material spraying device B205, a light wave heating device a204, and a light wave heating device B206, the pretreatment mechanism housing 201 is provided on the main body frame 1, the gear power supply device 207 is provided on the pretreatment mechanism housing 201, the gear power supply device 207 is provided with six sets, the annular rotary wheel 202 is provided between the gear power supply devices 207, the pretreatment material spraying device a203 is provided on the annular rotary wheel 202, the pretreatment material spraying device B205 is provided on the annular rotary wheel 202, the light wave heating device a204 is provided on the annular rotary wheel 202, the light wave heating device B206 is provided on the annular rotary wheel 202, the pretreatment material spraying device a203 and the pretreatment material spraying device B205 are identical in structure, the structure of the optical wave heating device A204 is completely the same as that of the optical wave heating device B206; gear energy supply device 207 is including drawing together transmission gear dish 208, conical gear G209, gear dish fixed axle 210, gear dish energy supply motor 211 and motor gear G212, pre-treatment mechanism shell 201 is located to gear dish fixed axle 210, conical gear G209 is located on gear dish fixed axle 210, transmission gear dish 208 is located on gear dish fixed axle 210, gear dish energy supply motor 211 is located on pre-treatment mechanism shell 201, motor gear G212 is located on gear dish energy supply motor 211, motor gear G212 links to each other with conical gear G209 meshing.

As shown in fig. 7, the light wave heating device a204 comprises a light wave heater and a telescopic support system a221, the telescopic supporting system A221 is arranged on the annular rotating wheel 202, the light wave heater is arranged on the telescopic supporting system A221, the telescopic supporting system A221 comprises a fixed head 213, an adjusting rotating arm 214, a folding telescopic arm 215, a telescopic arm limit box 216, a shaft A218, a shaft B219 and a shaft C220, the fixed head 213 is provided on the annular rotating wheel 202, the shaft a218 is provided on the fixed head 213, the adjusting rotary arm 214 is provided at one end of the axis a218, the axis B219 is provided at the middle of the adjusting rotary arm 214, the shaft C220 is arranged at the other end of the adjusting rotating arm 214, the telescopic arm limiting box 216 is arranged on the annular rotating wheel 202, one end of the folding telescopic arm 215 is arranged in the telescopic arm limiting box 216, the other end of the folding telescopic arm 215 is arranged on a shaft B219, and the optical wave heater 217 is arranged on a shaft C220.

As shown in fig. 8, the spraying device a203 for pretreatment materials according to the present invention includes a double-pipe sprayer 223 and a telescopic support system B222, the telescopic support system B222 is disposed on the annular rotating wheel 202, the spraying device a203 for pretreatment materials is disposed on the telescopic support system B222, and the telescopic support system B222 and the telescopic support system a221 have the same structure.

As shown in fig. 9 and 10, the surrounding type lossless impression mechanism 4 includes an impression mechanism housing 301, an energizing gear a303, an energizing gear B304, an energizing gear C305, a transmission gear group 302, a telescopic surrounding type impression assembly 306, a surrounding contact type auxiliary stationary impression assembly a307 and a surrounding contact type auxiliary stationary impression assembly B308, the stamping mechanism shell 301 is arranged on the main body frame 1, the energy supply gear A303, the energy supply gear B304 and the energy supply gear C305 are completely the same in structure, the telescopic encircling imprinting assembly 306, the encircling contact auxiliary stationary imprinting assembly a307 and the encircling contact auxiliary stationary imprinting assembly B308 are identical in structure, the energy supply gear A303 is arranged on the stamping mechanism shell 301, the transmission gear set 302 is arranged among the three groups of energy supply gears, the telescopic surrounding type stamping assembly 306, the surrounding contact type auxiliary fixed stamping assembly A307 and the surrounding contact type auxiliary fixed stamping assembly B308 are arranged on the transmission gear set 302; the telescopic surrounding type impressing assembly 306 comprises a linkage type self-adaptive supporting system A323 and a multipurpose roller 318, the linkage type self-adaptive supporting system A323 is arranged on the transmission gear set 302, and the multipurpose roller 318 is arranged on the linkage type self-adaptive supporting system A323; the linkage type self-adaptive support system B325 is arranged on the transmission gear set 302, and the support concave wheel 324 is arranged on the linkage type self-adaptive support system B325; the linkage type self-adaptive support system B325 and the linkage type self-adaptive support system A323 have the same structure, and the surrounding contact type auxiliary fixed stamping assembly A307 and the surrounding contact type auxiliary fixed stamping assembly B308 have the same structure.

The telescopic surrounding type impressing assembly 306 comprises a linkage type self-adaptive supporting system A323 and a multipurpose roller 318, the linkage type self-adaptive supporting system A323 is arranged on the transmission gear set 302, and the multipurpose roller 318 is arranged on the linkage type self-adaptive supporting system A323; the linkage type self-adaptive support system B325 is arranged on the transmission gear set 302, and the support concave wheel 324 is arranged on the linkage type self-adaptive support system B325; the linkage type self-adaptive support system B325 and the linkage type self-adaptive support system A323 are identical in structure, and the surrounding contact type auxiliary fixed stamping assembly A307 and the surrounding contact type auxiliary fixed stamping assembly B308 are identical in structure.

As shown in fig. 11, the linkage type adaptive support system a includes a shaft D309, a square thick telescopic arm a310, a limiting sheet a311, a square thin telescopic arm a312, a shaft E313, a cylindrical telescopic arm 314, a limiting sheet B315, a square thin telescopic arm B316, a square thick telescopic arm B317, a shaft F319, a bevel gear a322, a small bevel gear 320 and a platen energy supply motor 321, the shaft E313 is disposed on the transmission gear set 302, the shaft F319 is disposed on the transmission gear set 302, one end of the square thick telescopic arm a310 is disposed on the shaft F319, one end of the shaft D309 is disposed on the other end of the square thick telescopic arm a310, one end of the square thin telescopic arm a312 is disposed on the shaft E313, the other end of the square thin telescopic arm a312 is disposed on the shaft D309, one end of the limiting sheet a311 is disposed on the shaft E313, the small bevel gear 320 is disposed on the shaft D309, the platen energy supply motor 321 is disposed on the square thin telescopic arm a312, on the impression wheel energy supply motor 321 was located to conical tooth wheel A322, conical tooth wheel A322 and the meshing of small-size toper tooth 320 simultaneously, on axle F319 was located to the other end of spacing thin slice A311, on axle E313 was located to the one end of the flexible arm 314 of cylindricality, on axle F319 was located to the other end of the flexible arm 314 of cylindricality, axle D309 middle part was located to multi-purpose type gyro wheel 318, on axle E313 was located to the one end of spacing thin slice B315, on axle F319 was located to the other end of spacing thin slice B315, on axle E313 was located to the one end of the flexible arm B316 of square thin, on axle D309 was located to the other end of the flexible arm B316 of square thin, on axle F319 was located to the one end of the flexible arm B317 of square thick, the other end of the flexible arm B317 of square thick is located on the other end of axle D309.

As shown in fig. 12 and 13, the air-liquid mixed cooling mechanism includes a fixing base 401, a cooling liquid circulation cooling device 402, and a blowing type drying and cleaning device 403, wherein the fixing base 401 is disposed at the middle portion of the main body frame, the cooling liquid circulation cooling device 402 is disposed at the front portion of the fixing base 401, and the blowing type drying and cleaning device 403 is disposed at the rear portion of the fixing base 401.

As shown in fig. 12, the coolant circulation cooling device 402 comprises, from bottom to top, a coolant collection and transportation pipe 407, a coolant collection square pool 408, a pressure pump 409, a coolant circulation processing system 410, a support column 411, a coolant discharge pipe 412, a coolant spray nozzle 413, a coolant expansion arm 414, a contraction type corrugated pipe 415 and a top fixing plate 416, wherein the coolant collection square pool 408 is arranged on the fixed base 401, the coolant circulation processing system 410 is arranged on the fixed base 401, the support column 411 is arranged on the fixed base 401, the top fixing plate 416 is arranged on the support column 411, the contraction type corrugated pipe 415 is arranged on the top fixing plate 416, the coolant spray nozzle 413 is arranged on the contraction type corrugated pipe 415, one end of the coolant expansion arm 414 is arranged on the top fixing plate 416, and the other end of the coolant expansion arm 414 is arranged on the coolant spray nozzle 413, one end of the cooling liquid collecting and transporting pipe 407 is arranged at the bottom of the cooling liquid collecting square pool 408, the other end of the cooling liquid collecting and transporting pipe 407 is arranged on the cooling liquid circulation processing system 410, the pressure pump 409 is arranged on the fixed base 401, the pressure pump 409 is simultaneously arranged on the cooling liquid collecting and transporting pipe 407, the cooling liquid discharge pipe 412 is arranged on the cooling liquid circulation processing system 410, and the other end of the cooling liquid discharge pipe 412 is arranged on the contraction type corrugated pipe 415.

As shown in fig. 23, the coolant circulation system 410 includes a suction pump 422, a coolant storage tank 423, a debris filtering and collecting chamber 424, and a circulation system housing 425, wherein the circulation system housing 425 is disposed on the transport fixture 401, the coolant storage tank 423 is disposed in the circulation system housing 425, the debris filtering and collecting chamber 424 is disposed on the coolant storage tank 423, and the suction pump 422 is disposed above the coolant storage tank 423.

As shown in fig. 13, the blowing type drying and cleaning device 403 includes a debris collection tank 420, a wind-proof support plate 417, a fan fixing top plate 418, a fan motor 421 and a horizontal fan 419, the wind-proof support plate 417 is disposed on the fixing base 401, the debris collection tank 420 is disposed on the fixing base 401, the fan fixing top plate 418 is disposed on the wind-proof support plate 417, the fan motor 421 is disposed on the fan fixing top plate 418, and the horizontal fan 419 is disposed on the fan motor 421.

As shown in fig. 14, the wrapping and wheel disc combination packaging mechanism includes a single-support transportation device 501, a packaging film fixing device 502, a bottom pasting device 503 and an auxiliary packaging device 504, wherein the single-support transportation device 501 is disposed on the main body frame 1, the packaging film fixing device 502 is disposed on the single-support transportation device 501, the bottom pasting device 503 is disposed on the single-support transportation device 501, and the auxiliary packaging device 504 is disposed on the bottom pasting device 503; the single-support transportation device 501 comprises a packaging mechanism base 505 and a lifting type nondestructive supporting transportation arm C, wherein the packaging mechanism base 505 is arranged on the main body frame, and the lifting type nondestructive supporting transportation arm C506 is arranged on the packaging mechanism base 505.

As shown in fig. 14, 15, 16 and 17, the bottom pasting device 503 comprises a square energy supply box 510, a sliding limit plate 511, a U-shaped sliding frame 512, a vertical telescopic arm 513, a horizontal rotating disc 514, a transmission chamber 515, a threaded rotating shaft 516, a square limit shaft rotating block 517, a horizontal threaded shaft transmission bevel gear 518, a horizontal threaded shaft motor 519, a small motor 520, a small transmission gear 521, a small transmission shaft 522, a sliding wheel 523 bevel gear B529 and a small motor gear 530, the single-support transportation device 501 is arranged on a main body frame, the packaging film fixing device 502 is arranged on the single-support transportation device 501, the bottom pasting device 503 is arranged on the single-support transportation device 501, the auxiliary packaging device 504 is arranged on the bottom pasting device 503, the packaging support column 507 is arranged on a packaging mechanism base 505, the packaging film 508 is arranged on the packaging support column 507, the packaging film fixing shaft 509 is arranged on the packaging film rotating shaft 508, the square energy supply box 510 is arranged on the packaging mechanism base 505, the horizontal threaded shaft motor 519 is arranged in the square energy supply box 510, one end of the threaded rotating shaft 516 is arranged on the square energy supply box 510, the bevel gear B529 is arranged on the horizontal threaded shaft motor 519, the horizontal threaded shaft transmission bevel gear 518 is arranged on the threaded rotating shaft 516, the bevel gear B529 is meshed with the threaded rotating shaft 516, the sliding limiting plate 511 is arranged on the square energy supply box 510, the square limiting shaft rotating block 517 is arranged in the middle of the sliding limiting plate 511, the other end of the threaded rotating shaft 516 is arranged on the square limiting shaft rotating block 517, the sliding wheel 523 is arranged on the sliding limiting plate 511, the U-shaped sliding frame 512 is arranged on the sliding wheel 523, the U-shaped sliding frame 512 is arranged on the threaded rotating shaft 516, and the vertical telescopic arm 513 is arranged on the U-shaped sliding frame 512, the transmission chamber 515 is arranged on the vertical telescopic arm 513, the small motor gear 530 is arranged on the small motor 520, the small motor 520 is arranged in the transmission chamber 515, the small transmission shaft 522 is arranged in the transmission chamber 515, the small transmission gear 521 is arranged on the small transmission shaft 522, the small transmission gear 521 is meshed with the small motor gear 5300, and the horizontal rotating disc 514 is arranged on the small transmission shaft 522.

As shown in fig. 14 and 18, the auxiliary packing device 504 includes a fixed frame 524, a horizontal telescopic arm 525, an arc-shaped auxiliary arm 526, a rotating ball 527, and a rotating ball bearing 528, wherein the fixed frame 524 is disposed on the square energy supply box 510, the horizontal telescopic arm 525 is disposed on the fixed frame 524, the arc-shaped auxiliary arm 526 is disposed on the horizontal telescopic arm 525, the rotating ball bearing 528 is disposed on the arc-shaped auxiliary arm 526, and the rotating ball 527 is disposed on the rotating ball bearing 528.

As shown in fig. 19, the air-cooled cryogenic cutting mechanism 7 includes a cluster type blowing device 601, an elevation type cutting device 602, and a cutting base 603, the cutting base 603 is disposed on the main body frame 1, the elevation type cutting device 602 is disposed on the cutting base 603, and the cluster type blowing device 601 is disposed on the elevation type cutting device 602.

As shown in fig. 19, 20 and 24, the cluster type blowing device 601 includes an air pump housing 604, a cylindrical air pump 605, an air duct 606 and a cluster air outlet 607, the air pump housing 604 is disposed on the lifting type cutting device 602, the cylindrical air pump 605 is disposed in the air pump housing 604, the air duct 606 is disposed on the cylindrical air pump 605, and the cluster air outlet 607 is disposed on the air duct 606.

As shown in fig. 20 and 21, the lifting cutting device 602 includes a cutting mechanism housing 608, a vertical screw shaft power supply motor 609, a screw shaft transmission bevel gear 610, a vertical screw shaft 611, a vertical limit shaft 612, a cutting strip fixing box 613, a cutting chain saw 614, a cutting transmission wheel disc 615, a cutting disc rotating shaft 616, a chain saw power supply motor 617, a chain saw transmission bevel gear 618, a bevel gear C620 and a bevel gear D619, the cutting mechanism housing 608 is disposed on the cutting base 603, the vertical screw shaft power supply motor 609 is disposed on the cutting mechanism housing 608, the vertical screw shaft 611 is disposed on the cutting mechanism housing 608, the vertical limit shaft 612 is disposed on the cutting mechanism housing 608, the screw shaft transmission bevel gear 610 is disposed on the vertical screw shaft 611, the bevel gear C620 is disposed on the vertical screw shaft power supply motor 609, the screw shaft transmission bevel gear 610 and the bevel gear C620, the cutting strip fixing box 613 is arranged on the vertical threaded shaft 611, the cutting strip fixing box 613 is arranged on the vertical limiting shaft 612, the chain saw power supply motor 617 is arranged in the cutting strip fixing box 613, the cutting disc rotating shaft 616 is arranged on the cutting strip fixing box 613, the chain saw transmission bevel gear 618 is arranged on the cutting disc rotating shaft 616, the bevel gear D619 is arranged on the chain saw power supply motor 617, the chain saw transmission bevel gear 618 is meshed with the bevel gear D619 at the same time, the cutting transmission wheel disc 615 is arranged on the cutting disc rotating shaft 616, and the cutting chain saw 614 is arranged on the cutting transmission wheel disc 615.

As shown in fig. 22, the lifting type nondestructive supporting transportation arm a405 comprises a supporting telescopic arm 701, a mounting base 702, a supporting energy supply motor 703, a supporting thin wall 709, a supporting fixed shaft 704, a supporting disc transmission gear 705, a gear protection shell 706, a conical gear E610, a supporting disc 707 and a flexible balloon 708, the supporting telescopic arm 701 is arranged on different bases, the mounting base 702 is arranged on the supporting telescopic arm 701, the support energy supply motor 703 is arranged on the installation base 702, the support thin wall 709 is arranged on the installation base 702, the supporting fixed shaft 704 is arranged on the supporting thin wall 709, the supporting disc transmission gear 705 is arranged on the supporting fixed shaft 704, the bevel gear E610 is arranged on the supporting energy supply motor 703, the supporting disk drive gear 705 is meshed with the bevel gear E610, the support disc 707 is disposed on the support fixing shaft 704, and the flexible balloon 708 is disposed on the support disc 707.

When the device is used, firstly, the heights of the lifting type nondestructive support transportation arm A, the lifting type nondestructive support transportation arm B and the lifting type nondestructive support transportation arm C are adjusted simultaneously, then the corrugated pipe is sent into the flexible nondestructive contact type conveying mechanism 2, meanwhile, the hydraulic telescopic arm 108 of the telescopic nondestructive flexible contact type conveying device 102 is adjusted, the hydraulic telescopic arm 108 stretches and retracts to drive the trapezoidal fixed block 109 to move, the trapezoidal fixed block 109 drives the fixed rotating shaft 118 to move, the fixed rotating shaft 118 drives the rotating disc 115 to move, when the cylindrical flexible bag 116 on the rotating disc 115 just contacts with the outer wall of the corrugated pipe, the rubber belt energy supply motor 110 starts to work, the transmission rubber belt 112 drives the fixed rotating shaft 118 to rotate, the fixed rotating disc 118 drives the rotating disc 115 to start to rotate, the corrugated pipe starts to be sent into the spraying and heating pretreatment mechanism 3, after the corrugated pipe enters the spraying and heating pretreatment mechanism 3, the folding telescopic arm 215 on the telescopic support system B222 stretches and retracts, the double-tube sprayer 223 is sent to the outer wall of the corrugated pipe to start spraying heating materials, the folding telescopic arm 215 on the telescopic support system A221 is telescopic, the light wave heater 217 is sent to the outer wall of the corrugated pipe, the wheel disc energy supply motor 211 drives the motor gear G212 to rotate, the motor gear G212 drives the conical gear G209 to rotate, the conical gear G209 drives the gear disc fixing shaft 210 to rotate, the gear disc fixing shaft 210 drives the transmission gear disc 208 to rotate, the transmission gear disc 208 drives the annular rotating wheel 202 to rotate, after the annular rotating wheel 202 rotates 90 degrees, the light wave heater 217 starts to heat, then the annular rotating wheel 202 rotates 180 degrees to finish pretreatment, then the corrugated pipe is sent to the surrounding type nondestructive imprinting mechanism 4, the working mode of the telescopic surrounding type imprinting assembly 306 is imprinting, the content to be imprinted is made into a special plug bolt to be inserted on the multipurpose type roller 318, the rest surrounding type contact type auxiliary fixed imprinting assembly A307 and the surrounding type auxiliary fixed imprinting assembly B308 are auxiliary fixed, adjusting a square thin telescopic arm A312, a square thin telescopic arm B316, a square thick telescopic arm A310, a square thick telescopic arm B317 and a cylindrical telescopic arm 314 to change the distance between a multipurpose roller 318 and the outer wall of the corrugated pipe, when the multipurpose roller 318 is tightly attached to the outer wall of the corrugated pipe, starting to work an energy supply gear A303, an energy supply gear B304 and an energy supply gear C305, the energy supply gear A, the energy supply gear B304 and the energy supply gear C305 drive a transmission gear set 302 to rotate, so as to drive a telescopic surrounding type stamping component 306, a surrounding contact type auxiliary fixed stamping component A307 and a surrounding contact type auxiliary fixed stamping component B308 to rotate, a stamping wheel energy supply motor 321 drives the multipurpose roller 318 to rotate, stamping on the multipurpose roller 318 is assisted, the transmission gear set 302 only needs to rotate for one circle to complete stamping during stamping, the corrugated pipe is sent to an air-liquid mixed cooling mechanism 5 after stamping, a cooling liquid spray nozzle 413 cools and cleans the pipe wall at the same time, after the coolant waste liquid flows into the coolant collection square pool 408, the coolant waste liquid is pumped into the coolant circulation processing system 410 through the pressure pump 409, in the coolant circulation processing system 410, the chips are collected through the chip filtering and collecting chamber 424, the coolant is injected into the coolant storage box 423, the coolant is conveyed from the coolant discharge pipe 412 to the coolant spray nozzle 413 through the water pump 422, then the horizontal fan 419 blows and dries the chips with wind, the cleaning is completed, before the corrugated pipe is conveyed into the packaging type and wheel disc combination packaging mechanism 6, the provided packaging film on the packaging film fixing shaft 509 is pulled to the packaging mechanism base 505 from the packaging film rolling shaft, at the moment, the packaging type and wheel disc combination packaging mechanism 6 is started, the packaging film is continuously pulled out along with the corrugated pipe, meanwhile, the auxiliary packaging device 504 is adjusted to cover the upper half part of the corrugated pipe, the bottom pasting device 503 is operated to cover the lower half part of the corrugated pipe and simultaneously complete pasting, the vertical telescopic arm 513 rises, the horizontal threaded shaft motor 519 is matched with and adjusts the horizontal position of the U-shaped sliding frame 512, the two ends of the rotating disc, which are positioned in the middle of the threaded pipe, are tightly attached to a packaging film wrapping the corrugated pipe, the small motor 520 drives the rotating disc to rotate along with the continuous feeding of the corrugated pipe, the vertical telescopic arm begins to fall, the horizontal threaded shaft motor 519 is matched with and adjusts the middle part of the sliding limiting plate 511 of the U-shaped sliding frame 512 to be close to, the rotating disc draws the outer side of the packaging film to the outer wall of the middle lower part of the corrugated pipe, when the rotating disc reaches the bottom of the corrugated pipe, the two rotating discs tightly attach and stick the packaging films on the left side and the right side of the corrugated pipe, the purpose of packaging is achieved, finally the corrugated pipe is fed into the air-cooling low-temperature cutting mechanism 7, the cutting is started after the corrugated pipe with the required length passes through, the threaded shaft drives the conical gear 610 to work to drive the vertical threaded shaft 611 to rotate, the cutting strip fixing box 613 is controlled to lift from bottom to top, meanwhile, the chain saw energy supply motor 617 drives the cutting chain saw 614 to cut the corrugated pipe, the cylindrical air pump 605 of the cylindrical air pump 605 sends cold air out of the technical air outlet to cool the pipe wall, and cutting and packaging are completed.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

The present invention and its embodiments have been described above, and the description is not intended to be limiting, and the drawings are only one embodiment of the present invention, and the actual structure is not limited thereto. In summary, those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiments as a basis for designing or modifying other structures for carrying out the same purposes of the present invention without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. The utility model provides a smooth helical bellows's of inner wall sign impression device which characterized in that: comprises a main body framework (1), a flexible nondestructive contact type conveying mechanism (2), a spraying heating pretreatment mechanism (3), an annular imprinting mechanism (4), an air-liquid mixed cooling mechanism (5), a wrapping type and wheel disc combined packaging mechanism (6), an air-cooled low-temperature cutting mechanism (7) and a control device (8), wherein the flexible nondestructive contact type conveying mechanism (2), the spraying heating pretreatment mechanism (3), the annular imprinting mechanism, the air-liquid mixed cooling mechanism (5), the wrapping type and wheel disc combined packaging mechanism (6) and the air-cooled low-temperature cutting mechanism (7) are sequentially arranged on the main body framework (1) from left to right, the flexible nondestructive contact type conveying mechanism (2) is arranged on the leftmost side of the main body framework (1), the spraying heating pretreatment mechanism (3) is arranged on the right side of the flexible nondestructive contact type conveying mechanism (2), the annular imprinting mechanism (4) is arranged on the right side of the spraying heating pretreatment mechanism (3), the air-liquid mixed cooling mechanism (5) is arranged on the right side of the annular imprinting mechanism (4), the wrapping type and wheel disc combined packaging mechanism (6) is arranged on the right side of the air-liquid mixed cooling mechanism (5), the air-cooled low-temperature cutting mechanism (7) is arranged on the right side of the wrapping type and wheel disc combined packaging mechanism (6), and the control device (8) is arranged on the outer side of the main body frame (1); the spraying and heating pretreatment mechanism (3) comprises a pretreatment mechanism shell (201), an annular rotating wheel (202), a gear energy supply device (207), a spraying device A (203), a spraying device B (205), a light wave heating device A (204) and a light wave heating device B (206), wherein the pretreatment mechanism shell (201) is arranged on a main body frame (1), the gear energy supply device (207) is arranged on the pretreatment mechanism shell (201), the annular rotating wheel (202) is arranged between the gear energy supply devices (207), the spraying device A (203) and the spraying device B (205) are arranged on the annular rotating wheel (202), and the light wave heating device A (204) and the light wave heating device B (206) are arranged on the annular rotating wheel (202); the gear energy supply device (207) comprises a transmission gear disc (208), a bevel gear G (209), a gear disc fixing shaft (210), a gear disc energy supply motor (211) and a motor gear G (212), wherein the gear disc fixing shaft (210) is arranged on the pretreatment mechanism shell (201), the bevel gear G (209) is arranged on the gear disc fixing shaft (210), the transmission gear disc (208) is arranged on the gear disc fixing shaft (210), the gear disc energy supply motor (211) is arranged on the pretreatment mechanism shell (201), the motor gear G (212) is arranged on the gear disc energy supply motor (211), and the motor gear G (212) is meshed with the bevel gear G (209); the annular imprinting mechanism (4) comprises an imprinting mechanism shell (301), an energy supply gear A (303), an energy supply gear B (304), an energy supply gear C (305), a transmission gear set (302), a telescopic surrounding type imprinting assembly (306), a surrounding contact type auxiliary fixed imprinting assembly A (307) and a surrounding contact type auxiliary fixed imprinting assembly B (308), wherein the structures of the energy supply gear A (303), the energy supply gear B (304) and the energy supply gear C (305) are completely the same, the structures of the telescopic surrounding type imprinting assembly (306), the surrounding contact type auxiliary fixed imprinting assembly A (307) and the surrounding contact type auxiliary fixed imprinting assembly B (308) are completely the same, the imprinting mechanism shell (301) is arranged on a main body frame (1), and the structures of the energy supply gear A (303), the energy supply gear B (304) and the energy supply gear C (305) are completely the same, energy supply gear A (303), energy supply gear B (304) and energy supply gear C (305) locate on coining mechanism shell (301), drive gear group (302) are located between the energy supply gear, flexible surrounding coining subassembly (306), encircle the supplementary fixed coining subassembly A of contact (307) and encircle the supplementary fixed coining subassembly B of contact (308) and be the annular array and locate on drive gear group (302).

2. The marking and embossing device for the smooth helical bellows with the inner wall as claimed in claim 1, wherein: the flexible lossless contact type conveying mechanism (2) comprises a conveying mechanism shell (101) and a telescopic lossless flexible contact type conveying device (102), wherein the conveying mechanism shell (101) is arranged on the main body frame (1), and the telescopic lossless flexible contact type conveying device (102) is arranged on the conveying mechanism shell (101); the telescopic lossless flexible contact conveying device (102) comprises a hydraulic telescopic arm (108), a trapezoidal fixed block (109), a rubber belt energy supply motor (110), a rubber belt driving wheel (111), a transmission rubber belt (112), a fixed nut group (113), a fixed disc A (114), a fixed disc B (119), a rotating disc (115), a cylindrical flexible bag (116), a fixed screw group (117) and a fixed rotating shaft (118), wherein the hydraulic telescopic arm (108) is arranged on a conveying mechanism shell (101), the trapezoidal fixed block (109) is arranged on the hydraulic telescopic arm (108), the fixed rotating shaft (118) is arranged on the trapezoidal fixed block (109), the rubber belt energy supply motor (110) is arranged on the trapezoidal fixed block (109), the rubber belt driving wheel (111) is arranged on the fixed rotating shaft (118), the transmission rubber belt (112) is arranged on the rubber belt energy supply motor (110), the rubber belt transmission device is characterized in that the transmission rubber belt (112) is arranged on the rubber belt transmission wheel (111) at the same time, the fixed disc is arranged on the fixed rotating shaft (118), the rotating disc (115) is arranged on the fixed rotating shaft (118), the cylindrical flexible bag (116) is arranged on the rotating disc (115), the fixed screw group (117) is arranged on the fixed disc B (119), and the fixed nut group (113) is arranged on the fixed disc A (114).

3. The marking and embossing device for the smooth helical bellows with the inner wall as claimed in claim 2, wherein: the optical wave heating device A (204) comprises an optical wave heater 217 and a telescopic supporting system A (221), the telescopic supporting system A (221) comprises a fixed head (213), an adjusting rotating arm (214), a folding telescopic arm (215), a telescopic arm limiting box (216), a shaft A (218), a shaft B (219) and a shaft C (220), the fixed head (213) is arranged on the annular rotating wheel (202), the shaft A (218) is arranged on the fixed head (213), the adjusting rotating arm (214) is arranged at one end of the shaft A (218), the telescopic arm limiting box (216) is arranged on the annular rotating wheel (202), one end of the folding telescopic arm (215) is arranged in the telescopic arm limiting box (216), the other end of the folding telescopic arm (215) is arranged on the shaft B (219), the shaft B (219) is arranged in the middle of the adjusting rotating arm (214), and the shaft C (220) is arranged at the other end of the adjusting rotating arm (214), the optical wave heater (217) is arranged on the shaft C (220); the spraying device A (203) comprises a double-pipe sprayer (223) and a telescopic supporting system B (222), the telescopic supporting system B (222) and the telescopic supporting system A (221) are identical in structure, the telescopic supporting system B (222) is arranged on the annular rotating wheel (202), and the double-pipe sprayer (223) is arranged on the telescopic supporting system B (222).

4. The marking and embossing device for the smooth helical bellows with the inner wall as claimed in claim 3, wherein: the telescopic surrounding type impressing assembly (306) comprises a linkage type self-adaptive supporting system A (323), a supporting concave wheel (324), a linkage type self-adaptive supporting system B (325) and a multipurpose roller, wherein the linkage type self-adaptive supporting system A (323) is arranged on the transmission gear set (302), and the multipurpose roller is arranged on the linkage type self-adaptive supporting system A (323); the linkage type self-adaptive support system B (325) is arranged on the transmission gear set (302), and the support concave wheel (324) is arranged on the linkage type self-adaptive support system B (325); the linkage type self-adaptive support system A (323) comprises a shaft D (309), a square thick telescopic arm A (310), a limiting sheet A (311), a square thin telescopic arm A (312), a shaft E (313), a cylindrical telescopic arm (314), a limiting sheet B (315), a square thin telescopic arm B (316), a square thick telescopic arm B (317), a shaft F (319), a small bevel gear (320), a bevel gear A (322) and a stamping wheel energy supply motor (321), wherein the shaft E (313) is arranged on a transmission gear set (302), the shaft F (319) is arranged on the transmission gear set (302), one end of the square thick telescopic arm A (310) is arranged on the shaft F (319), one end of the shaft D (309) is arranged at the other end of the square thick telescopic arm A (310), one end of the square thin telescopic arm A (312) is arranged on the shaft E (313), and the other end of the square thin telescopic arm A (312) is arranged on the shaft D (309), the one end of spacing thin slice A (311) is located on axle E (313), small-size conical gear (320) is located on axle D (309), stamp wheel energy supply motor (321) is located on square thin flexible arm A (312), conical gear A (322) is located on stamp wheel energy supply motor (321), conical gear A (322) and small-size conical gear (320) meshing simultaneously the other end of spacing thin slice A (311) is located on axle F (319), the one end of cylindricality flexible arm (314) is located on axle E (313), the other end of cylindricality flexible arm (314) is located on axle F (319), the one end of spacing thin slice B (315) is located on axle E (313), the other end of spacing thin slice B (315) is located on axle F (319), the one end of square thin flexible arm B (316) is located on axle E (313), the other end of square thin flexible arm B (316) is located on axle D (309), one end of a square thick telescopic arm B (317) is arranged on the shaft F (319), and the other end of the square thick telescopic arm B (317) is arranged on the other end of the shaft D (309).

5. The marking and embossing device for the smooth helical bellows with the inner wall as claimed in claim 4, wherein: the air-liquid mixed cooling mechanism (5) comprises a transportation fixing device (401), a cooling liquid circulating cooling device (402) and a blowing type drying and cleaning device (403), wherein the transportation fixing device (401) is arranged in the middle of the main body frame (1), the cooling liquid circulating cooling device (402) is arranged at the front part of the transportation fixing device (401), and the blowing type drying and cleaning device (403) is arranged behind the transportation fixing device (401); the transportation fixing device (401) comprises a supporting plate (404), a lifting type nondestructive support transportation arm A (405) and a lifting type nondestructive support transportation arm B (406), the supporting plate (404) is fixedly arranged in the middle of the main body frame (1), the lifting type nondestructive support transportation arm A (405) is arranged at the front end of the supporting plate (404), and the lifting type nondestructive support transportation arm B (406) is arranged at the rear end of the supporting plate (404); the cooling liquid circulating and cooling device (402) comprises a cooling liquid collecting and conveying pipe (407), a cooling liquid collecting square pool (408), a pressure pump (409), a cooling liquid circulating treatment system (410), a supporting upright post (411), a cooling liquid discharge pipe (412), a cooling liquid spray head (413), a cooling head telescopic arm (414), a contraction type corrugated pipe (415) and a top fixing plate (416), wherein the cooling liquid collecting square pool (408) is arranged on the conveying fixing device (401), the supporting upright post (411) is arranged on the conveying fixing device (401), the cooling liquid circulating treatment system (410) is arranged on the conveying fixing device (401), the top fixing plate (416) is arranged on the supporting upright post (411), one end of the cooling head telescopic arm (414) is arranged on the top fixing plate (416), the other end of the cooling head telescopic arm (414) is arranged on the cooling liquid spray head (413), the contraction type corrugated pipe (415) is arranged on the top fixing plate (416), the cooling liquid spray head (413) is arranged on the contraction type corrugated pipe (415), one end of the cooling liquid collecting and transporting pipe (407) is arranged at the bottom of the cooling liquid collecting square pool (408), the other end of the cooling liquid collecting and transporting pipe (407) is arranged on the cooling liquid circulation processing system (410), the pressure pump (409) is arranged on the transportation fixing device (401), the pressure pump (409) is simultaneously arranged on the cooling liquid collecting and transporting pipe (407), one end of the cooling liquid discharge pipe (412) is arranged on the cooling liquid circulation processing system (410), and the other end of the cooling liquid discharge pipe (412) is arranged on the contraction type corrugated pipe (415); the cooling liquid circulation treatment system (410) comprises a water suction pump (422), a cooling liquid storage box (423), a debris filtration collection chamber (424) and a circulation system shell (425), wherein the circulation system shell (425) is arranged on the transportation fixing device (401), the cooling liquid storage box (423) is arranged in the circulation system shell (425), the debris filtration collection chamber (424) is arranged on the cooling liquid storage box (423), and the water suction pump (422) is arranged above the cooling liquid storage box (423); blow dry cleaning device of formula (403) including piece recovery pond (420), prevent wind backup pad (417), fan motor (421), the fixed roof of fan (418) and horizontal fan (419), prevent wind backup pad (417) and locate on transportation fixing device (401), the fixed roof of fan (418) is located on preventing wind backup pad (417), prevent that piece recovery pond (420) is located on transportation fixing device (401), fan motor (421) are located on the fixed roof of fan (418) horizontal fan (419) are located on fan motor (421).

6. The marking and embossing device for the smooth helical bellows with the inner wall as claimed in claim 5, wherein: the packaging type and wheel disc combined packaging mechanism (6) comprises a single-support conveying device (501), a packaging film fixing device (502), a bottom pasting device (503) and an auxiliary packaging device (504), wherein the single-support conveying device (501) is arranged on the main body frame (1), the bottom pasting device (503) is arranged on the single-support conveying device (501), the auxiliary packaging device (504) is arranged on the bottom pasting device (503), and the packaging film fixing device (502) is arranged on the single-support conveying device (501); the single-support conveying device (501) comprises a packaging mechanism base (505) and a lifting type nondestructive support conveying arm C (506), wherein the packaging mechanism base (505) is arranged on the main body frame (1), and the lifting type nondestructive support conveying arm C (506) is arranged on the packaging mechanism base (505); packaging film fixing device (502) is including packing support column (507), packaging film axis of rotation (508) and packaging film fixed axle (509), packagine machine constructs base (505) on packaging is located in packing support column (507), on packaging film axis of rotation (508) are located packaging support column (507), on packaging film axis of rotation (508) are located in packaging film fixed axle (509).

7. The marking and embossing device for the smooth helical bellows with the inner wall as claimed in claim 6, wherein: the bottom pasting device (503) comprises a square energy supply box (510), a sliding limiting plate (511), a U-shaped sliding frame (512), a vertical telescopic arm (513), a horizontal rotating disc (514), a transmission chamber (515), a thread rotating shaft (516), a square limiting shaft rotating block (517), a horizontal thread shaft transmission bevel gear (518), a horizontal thread shaft motor (519), a small motor (520), a small transmission gear (521), a small transmission shaft (522), a sliding wheel (523), a bevel gear B (529) and a small motor gear (530), wherein the square energy supply box (510) is arranged on a packaging mechanism base (505), the horizontal thread shaft motor (519) is arranged in the square energy supply box (510), the bevel gear B (529) is arranged on the horizontal thread shaft motor (519), the sliding limiting plate (511) is arranged on the square energy supply box (510), the sliding wheel (523) is arranged on a sliding limiting plate (511), the U-shaped sliding frame (512) is arranged on the sliding wheel (523), the U-shaped sliding frame (512) is arranged on a threaded rotating shaft (516), a square limiting shaft rotating block (517) is arranged in the middle of the sliding limiting plate (511), one end of the threaded rotating shaft (516) is arranged on a square energy supply box (510), a horizontal threaded shaft transmission bevel gear (518) is arranged on the threaded rotating shaft (516), the horizontal threaded shaft transmission bevel gear (518) is meshed with a bevel gear B (529), the other end of the threaded rotating shaft (516) is arranged on the square limiting shaft rotating block (517), a vertical telescopic arm (513) is arranged on the U-shaped sliding frame (512), a transmission chamber (515) is arranged on the vertical telescopic arm (513), and the small-sized motor (520) is arranged in the transmission chamber (515), the small-sized transmission shaft (522) is arranged in the transmission chamber (515), the small-sized transmission gear (521) is arranged on the small-sized transmission shaft (522), the small-sized motor gear (530) is arranged on the small-sized motor (520), the small-sized transmission gear (521) is meshed with the small-sized motor gear (530), and the horizontal rotating disc (514) is arranged on the small-sized transmission shaft (522).

8. The marking and embossing device for the smooth helical bellows with the inner wall as claimed in claim 7, wherein: supplementary packing plant (504) are including fixed frame (524), the flexible arm of level (525), arc auxiliary arm (526), rolling ball (527) and rolling ball bearing (528), fixed frame (524) are located on square energy supply box (510), the flexible arm of level (525) is located on fixed frame (524), the flexible arm of level (526) is located on the flexible arm of level (525), rolling ball bearing (528) is located on arc auxiliary arm (526), rolling ball (527) is located on rolling ball bearing (528).

9. The marking and embossing device for the smooth helical bellows with the inner wall as claimed in claim 8, wherein: the air-cooled low-temperature cutting mechanism (7) comprises a cluster type blowing device (601), a lifting type cutting device (602) and a cutting base (603), wherein the cutting base (603) is arranged on the main body frame (1), the lifting type cutting device (602) is arranged on the cutting base (603), and the cluster type blowing device (601) is arranged on the lifting type cutting device (602); the cluster type blowing device (601) comprises an air pump shell (604), a cylindrical air pump (605), an air guide pipe (606) and a cluster air outlet (607), the air pump shell (604) is arranged on the lifting type cutting device (602), the cylindrical air pump (605) is arranged in the air pump shell (604), the air guide pipe (606) is arranged on the cylindrical air pump (605), and the cluster air outlet (607) is arranged on the air guide pipe (606); the lifting type cutting device (602) comprises a cutting mechanism shell (608), a vertical threaded shaft energy supply motor (609), a threaded shaft transmission bevel gear (610), a vertical threaded shaft (611), a vertical limiting shaft (612), a cutting strip fixing box (613), a cutting chain saw (614), a cutting transmission wheel disc (615), a cutting disc rotating shaft (616), a chain saw energy supply motor (617), a chain saw transmission bevel gear (618), a bevel gear C (620) and a bevel gear D (619), wherein the cutting mechanism shell (608) is arranged on a cutting base (603), the vertical threaded shaft energy supply motor (609) is arranged on the cutting mechanism shell (608), the threaded shaft transmission bevel gear (610) is arranged on the vertical threaded shaft (611), the bevel gear C (620) is arranged on the vertical threaded shaft energy supply motor (609), and the threaded shaft transmission bevel gear (610) is meshed with the bevel gear C (620), the cutting strip fixing box (613) is arranged on a vertical threaded shaft (611), the vertical limiting shaft (612) is arranged on a cutting mechanism shell (608), the cutting strip fixing box (613) is arranged on the vertical limiting shaft (612) at the same time, the cutting strip fixing box (613) is arranged on a cutting disc rotating shaft (616), a chain saw energy supply motor (617) is arranged on the cutting strip fixing box (613), a chain saw transmission bevel gear (618) is arranged on the cutting disc rotating shaft (616), a bevel gear D (619) is arranged on the chain saw energy supply motor (617), the chain saw transmission bevel gear (618) is meshed with a bevel gear D (619) at the same time, the cutting transmission wheel disc (615) is arranged on the cutting disc rotating shaft (616), and the cutting chain saw (614) is arranged on the cutting transmission wheel disc (615).

10. The marking and embossing device for the smooth helical bellows with the inner wall as claimed in claim 9, wherein: the lifting type lossless supporting and transporting arm A (405), the lifting type lossless supporting and transporting arm B (406) and the lifting type lossless supporting and transporting arm C (506) are completely the same in structure and are symmetrical structures, the lifting type lossless supporting and transporting arm A (405) comprises a supporting telescopic arm (701), an installation base (702), a supporting energy supply motor (703), a supporting thin wall (709), a supporting fixed shaft (704), a supporting disc transmission gear (705), a gear protection shell (706), a supporting disc (707) and a flexible balloon (708), the supporting telescopic arm (701) is arranged on different bases, the installation base (702) is arranged on the supporting telescopic arm (701), the supporting energy supply motor (703) is arranged on the installation base (702), the supporting thin wall (709) is arranged on the installation base (702), the supporting fixed shaft (704) is arranged on the supporting thin wall (709), the supporting disc transmission gear (705) is arranged on the supporting fixing shaft (704), the supporting disc transmission gear (705) is meshed with the supporting energy supply motor (703), the supporting disc (707) is arranged on the supporting fixing shaft (704), and the flexible saccule (708) is arranged on the supporting disc (707).

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