CN110948220B - Core pipeline assembling mechanism of automatic production line for anesthesia evaporator cores - Google Patents

Abstract

The utility model provides an anesthesia evaporator core automatic production line's core pipeline assembly devices, is equipped with the workstation including vibration dish, cotton parcel subassembly, ridge roof beam skeleton material loading subassembly, stationary blade welded subassembly and stationary blade material loading subassembly between stationary blade welded subassembly and the stationary blade material loading subassembly, cotton parcel subassembly is equipped with the support riser of vertical setting including cotton parcel part, rubber coating compress part, pay-off platform, support, pay-off cylinder and automatic cutout part, one side of pay-off platform, and the top of support is equipped with two guide rails. According to the invention, the ridge beam framework can be automatically wrapped by the cotton cloth wheel through the cotton cloth wrapping assembly, the ridge beam framework is wrapped by the cotton cloth on the cotton cloth wheel, the storage and the sequential feeding of the fixing pieces can be realized through the fixing piece feeding assembly, and the ridge beam framework can be taken out and wrapped by the ridge beam framework in a horizontal state through the ridge beam framework feeding assembly.

Description

Core pipeline assembling mechanism of automatic production line for anesthesia evaporator cores

Technical Field

The invention relates to the technical field of medical equipment production equipment for anesthesia departments, in particular to a core pipeline assembling mechanism of an automatic production line of an anesthetic evaporator core.

Background

An anesthetic vaporizer (also known as an anesthetic evaporation tank) is an important component of an anesthesia machine, anesthetic drugs are changed into vaporized gas by utilizing the change of the temperature of the surrounding environment and a heat source, and a part of the vaporized gas carries away saturated anesthetic gas through a certain amount of carrier gas to form gas flow of anesthetic vapor with a certain concentration and directly enters an anesthesia loop. The free evaporation of the anesthetic liquid is not sufficient to provide a high concentration of anesthetic vapor and is not easily controlled, and therefore, a cartridge is generally installed in the evaporation chamber, at least a portion of which is immersed in the anesthetic liquid. The evaporation area is increased by the core, and high-concentration anesthetic vapor is obtained.

The core comprises a core seat, a core pipeline, a fixing piece, inner-layer core cotton and outer-layer core cotton, and the assembling process of the traditional anesthetic evaporator core comprises the steps of manually assembling the core pipeline, welding the core pipeline and the fixing piece, fixing the welded core pipeline on the core seat, installing the outer-layer cotton core on the outer side of the core pipeline, and installing the inner-layer cotton core on the inner side; the core pipeline comprises a ridge beam framework and cotton cloth, the ridge beam framework is wrapped by the cotton cloth to form the core pipeline, and the ridge beam framework plays a supporting role, so that the core pipeline cannot be blocked due to collapse of the cotton cloth; the prior art backbone typically uses square springs. The assembly of traditional core pipeline all is that the manual work uses extra device to fix the ridge roof beam skeleton, later the manual work uses the cotton to wrap up the ridge roof beam skeleton, is carrying out the rubber coating and cutting to the cotton, and whole process needs the worker to spend more energy and time, and degree of automation is lower, and long-time work can bring great intensity of labour for the worker.

Disclosure of Invention

The invention aims to provide a core pipeline assembling mechanism of an automatic production line of an anesthetic evaporator core, which aims to solve the technical problems of low automation degree and low production efficiency of core pipeline assembling in the prior art.

The invention provides a core pipeline assembling mechanism of an automatic production line of anesthetic evaporators, which comprises a vibration disc, a cotton cloth wrapping assembly, a ridge beam framework feeding assembly, a fixed sheet welding assembly and a fixed sheet feeding assembly, wherein the ridge beam framework feeding assembly is arranged between the cotton cloth wrapping assembly and the vibration disc, a workbench is arranged between the fixed sheet welding assembly and the fixed sheet feeding assembly, the cotton cloth wrapping assembly comprises a cotton cloth wrapping component, a gluing and pressing component, a feeding table, a support, a feeding cylinder and an automatic cutting component, the gluing and pressing component and the cotton cloth wrapping component are both arranged at the top of the feeding table, a vertically arranged supporting vertical plate is arranged on one side of the feeding table, the automatic cutting component is arranged at the top of the supporting vertical plate, the feeding cylinder is horizontally arranged at the top of the support, two horizontally arranged guide rails are arranged at the top of the support, the bottom of the feeding table is in sliding fit with the two guide rails, and the output end of the feeding air cylinder is fixedly connected with the side wall of the feeding table.

Compared with the prior art, the invention has the beneficial effects that:

the invention comprises a vibration disc, a cotton cloth wrapping component, a ridge beam framework feeding component, a fixing piece welding component and a fixing piece feeding component, wherein a cotton cloth wheel can be automatically wrapped on the ridge beam framework through the cotton cloth wrapping component, the cotton cloth on the cotton cloth wheel wraps the ridge beam framework, a cloth pressing strip can tightly press one end of the cotton cloth, a spraying pipeline can spray glue solution on the cotton cloth, the vibration disc can complete the feeding operation on the ridge beam framework, the fixing pieces can be stored and sequentially fed through the fixing piece feeding component, the arranged fixing pieces can be sequentially taken out, the fixing pieces can be rotated to be in a horizontal state, the fixing pieces can be conveniently arranged at the top of a core pipeline, a welding machine can complete the welding operation on the fixing pieces and the core pipeline, the ridge beam framework feeding component can place the wrapped ridge beam framework at the top of a storage table, the core pipeline feeding mechanism moves the wrapped core pipeline to the top of the workbench to complete the assembly of the core pipeline and the fixing sheet, so that the technical problems of low automation degree and low production efficiency of core pipeline assembly in the prior art are solved.

Secondly, the invention is provided with a cotton cloth wrapping component which comprises a cotton cloth wrapping part, a gluing and cloth pressing part, a feeding table, a bracket, a feeding cylinder and an automatic cutting part, the cotton cloth wheel can automatically wrap the ridge beam framework through the cotton cloth wrapping part, the cotton cloth on the cotton cloth wheel can wrap the ridge beam framework, the fourth rotary cylinder can work to enable the ridge beam framework to be in a horizontal state, the axis of the ridge beam framework and the axis of the rotary ring are positioned on the same straight line, the rotary motor can work to drive one rotary shaft to rotate, the synchronous rotation of four rotation axes can be realized under the effect of hold-in range, the synchronous rotation of four drive wheels is realized, makes rotatory ring can carry out the rotation, makes rotatory ring can drive the cotton wheel and rotate around the axis of rotatory ring, makes the cotton wheel can wind the cotton on the ridge roof beam skeleton at the pivoted in-process.

Thirdly, the gluing and cloth pressing component is arranged, the third rotary cylinder works to enable the cloth pressing strip to move the cotton cloth to rotate, the end portion of the cotton cloth can be abutted against the surface of the ridge beam framework, the cotton cloth can be wound on the ridge beam framework in the rotating process of the cotton cloth wheel, the glue solution can be sprayed on the surface of the cotton cloth by the spraying pipeline, and the core pipeline can be wrapped by the cotton cloth in the winding process in a bonding mode.

The fixing sheet feeding assembly is arranged, the fixing sheets can be stored and sequentially fed through the fixing sheet feeding assembly, the placed fixing sheets can be sequentially taken out, the fixing sheets can rotate to be in a horizontal state, the fixing sheets are conveniently installed at the top of the core pipeline, and a welding machine can complete welding operation of the fixing sheets and the core pipeline.

The ridge frame feeding assembly is arranged, the second screw rod sliding table can drive the third clamping cylinder to move to the position above the ridge frame in the conveying channel, the tensioning plates on the third clamping cylinder can move into the ridge frame through the operation of the second screw rod sliding table, the two tensioning plates are far away from each other through the operation of the third clamping cylinder to clamp the ridge frame, the ridge frame feeding assembly can take out the ridge frame and wrap the ridge frame in a horizontal state, and the ridge frame can be moved to the top of the storage table.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a schematic perspective view of an anesthetic vaporizer wick;

FIG. 2 is an exploded view of the anesthetic evaporator core;

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

FIG. 4 is a schematic top view of the present invention;

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

FIG. 6 is a schematic structural diagram of an inner core cotton assembling mechanism and a conveying belt;

FIG. 7 is a schematic structural diagram of an outer core cotton assembling mechanism;

FIG. 8 is a schematic structural view of a core tube feed mechanism;

FIG. 9 is an enlarged view taken at A in FIG. 8;

FIG. 10 is a schematic structural view of a core tube feeding mechanism and a core tube assembling mechanism;

FIG. 11 is a partial schematic structural view of a core conduit assembly mechanism;

FIG. 12 is a schematic view of a cotton cloth wrapping assembly;

FIG. 13 is a schematic view of a partial structure of a cotton wrapping assembly;

FIG. 14 is a schematic structural view of a spine skeleton loading assembly;

FIG. 15 is a schematic view showing the construction of the anchor sheet welding module and the anchor sheet feeding module.

Reference numerals:

an anesthetic evaporator core 1, a core base 11, a core pipeline 12, a ridge beam framework 13, a fixing plate 14, inner core cotton 15, outer core cotton 16, a conveyor belt 2, a core base fixing component 21, a limiting ring 22, a core pipeline feeding mechanism 3, a fixing frame 31, a sliding table 32, a first sliding rail 321, a sliding block 322, a guide rod 323, a third lifting cylinder 33, a connecting table 34, a transverse conveying component 35, a conveying motor 351, a rotating shaft 352, a synchronizing wheel 353, a synchronizing belt 354, a driving frame 36, a core pipeline clamping component 37, a driving motor, a supporting rail 372, a material moving strip 373, a driving gear 374, a tooth groove 375, an extending frame 38, a clamping block 381, an arc-shaped groove 382, an inner core cotton assembling mechanism 4, an inner core cotton storage component 41, a conveyor belt 42, a pushing electric cylinder 43, a driving transverse strip 431, a storage box 432, a partition plate 433, a conveying channel 434, a supporting table 44, a pushing plate 45, a material moving component 46, a bearing frame 461, a first lifting cylinder 462, a material taking cylinder 47, a first screw rod sliding table 471, a lifting table 48, a first rotating cylinder 49, a first clamping cylinder 491, an arc-shaped fixing plate 492, an outer core cotton assembly mechanism 5, a fixing table 51, an outer core cotton conveying component 52, a stepping motor 521, a limiting plate 522, a supporting rod 523, a conveying screw rod 53, a feeding plate 54, a first conveying cylinder 55, a second lifting cylinder 56, a supporting bracket 57, a material moving table 58, a mounting table 581, a second rotating cylinder 582, a second clamping cylinder 583, an arc-shaped clamping plate 59, a core pipeline assembly mechanism 6, a vibrating disc 61, a cotton cloth wrapping component 7, a feeding table 71, a supporting vertical plate 72, a guide rail 721, a support 73, a feeding cylinder 74, a cotton cloth wrapping component 75, a rotating motor 751, a cotton wheel 752, a rotating ring 753, a rotating shaft 754, a driving wheel 755, a belt pulley 756, a synchronous belt 757, a gluing and cloth pressing component 76, a third rotating cylinder 761, a double-rod cylinder 762, a connecting plate 763, a fixed vertical plate 764, a cloth pressing strip 765, a spraying pipeline 77, a spraying nozzle 771, an automatic cutting component 78, a fourth lifting cylinder 781, a transverse plate 782, a knife holder 783, a cutting blade 784, a ridge beam framework feeding component 8, a storage table 81, a second screw rod sliding table 82, a rotating cylinder 83, a fourth rotating cylinder 84, a connecting transverse plate 85, a third clamping cylinder 851, a tensioning plate 852, a feeding channel 86, a rotating component 87, a rotating motor 871, a turbine 872, a connecting seat 873, a worm 874, a storage table 88, a fixed piece feeding component 9, a bearing table 91, a fifth rotating cylinder 92, a rotating table 93, a mounting frame 94, a sliding table 941, a bearing seat 942, a rotating cylinder 943, a connecting strip 944, a fourth clamping cylinder 945, a material taking block 946, a limiting groove 947, a workbench 95, a stepping motor 951, a limiting strip 952, a bearing rod 953, extension plate 954, feeding screw 955, feeding plate 96, fixing piece welding assembly 97, padding frame 971, second conveying cylinder 972, feeding table 973, welding machine 98, second slide rail 981 and feeding block 982.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention.

The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention.

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 should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1 to 15, an automatic production line for anesthetic evaporator cores 1 is provided in an embodiment of the present invention, and includes a conveyor belt 2, a core duct assembly mechanism 6, a core duct feeding mechanism 3, an inner core cotton assembly mechanism 4, and an outer core cotton assembly mechanism 5, where the inner core cotton assembly mechanism 4 and the outer core cotton assembly mechanism 5 are disposed on the right side of the conveyor belt 2 at intervals, the core duct feeding mechanism 3 is disposed above the conveyor belt 2, the core duct assembly mechanism 6 is disposed on the left side of the conveyor belt 2, the inner core cotton assembly mechanism 4 includes an inner core cotton storage component 41, a material transfer component 46, and a conveyor belt 42, the conveyor belt 42 is disposed between the inner core cotton storage component 41 and the conveyor belt 2, the material transfer component 46 is disposed above the conveyor belt 2 and the conveyor belt 42, the conveyor belt 2 is provided with a plurality of core holder fixing components 21 disposed at intervals along the conveying direction thereof, each core print fixing component 21 comprises three limiting rings 22 which are distributed circumferentially; the inner core cotton assembly mechanism 4 can automatically arrange a plurality of inner core cotton 15 in sequence, the inner core cotton 15 can be assembled on the core print 11 on the conveyor belt 2 in sequence, the inner core cotton 15 can be assembled on the core print 11 automatically, the three spacing rings 22 can realize spacing operation on the core print 11, the outer core cotton assembly mechanism 5 can realize automatic feeding on the outer core cotton 16, the outer core cotton 16 can be taken out in sequence, the feed plate 54 can horizontally move by the work of the stepping motor 521, the outer core cotton 16 can move to a position clamped by the second clamping cylinder 583, the second clamping cylinder 583 can relatively move two arc-shaped clamping plates 59 by the work of the second clamping cylinder 583, the two arc-shaped plates can finish clamping the outer core cotton 16, the core pipeline feeding mechanism 3 is used for moving the wrapped core pipeline 12 on the storage table 81 to the working table 95, the core pipeline 12 can be welded with the fixing sheet 14, the welded core pipeline 12 can be assembled on the core base 11, manual material moving is not needed, the position of each placing is accurate, the assembling accuracy is improved, and the driving mode that the driving gear 374 is meshed with the material moving strip 373 has the advantages of being high in accuracy and capable of avoiding damage to the core pipeline 12 due to the fact that excessive force collides with the core pipeline 12; core pipeline assembly devices 6 can accomplish the material loading and the cotton of backbone skeleton 13 to the parcel of backbone skeleton 13 automatically to can carry out the material loading to the stationary blade 14 and weld the stationary blade 14 on backbone skeleton 13, degree of automation is higher, is worth promoting.

Specifically, the inner-layer core cotton storage assembly 41 comprises an electric pushing cylinder 43, a driving cross bar 431 and a storage box 432 with an upward opening, the interior of the storage box 432 is partitioned by a plurality of partition plates 433, the interior of the storage box 432 is partitioned into a plurality of conveying channels 434 by the plurality of partition plates 433, a support table 44 is arranged on the side wall of the storage box 432, the electric pushing cylinder 43 is horizontally arranged at the top of the support table 44, the driving cross bar 431 is horizontally arranged above the storage box 432, a vertically arranged material pushing plate 45 is arranged at the bottom of the driving cross bar 431 corresponding to each conveying channel 434, and the output end of the electric pushing cylinder 43 is fixedly connected with the side wall of the material pushing plate 45; the pushing electric cylinder 43 is operated to move a plurality of pushing plates 45 along the length direction of the conveying channel 434, so that the inner core cotton 15 in the conveying channel 434 can move towards the conveying belt 42, a row of inner core cotton 15 close to the conveying belt 42 can move onto the conveying belt 42, and the conveying belt 42 is operated to move the inner core cotton 15 below the material moving assembly 46.

Specifically, the material moving assembly 46 includes a carrier 461, a first lifting cylinder 462, a controller, an image collecting unit and a first lead screw sliding table 471 arranged at the top of the carrier 461, the controller is electrically connected with the image collecting unit, the image collecting unit is arranged right above the conveyor belt 2, the first lifting cylinder 462 is vertically arranged at the top of the moving end of the first lead screw sliding table 471, a lifting table 48 is fixed at the output end of the first lifting cylinder 462, a first rotary cylinder 49 is arranged at the bottom of the lifting table 48, a first clamping cylinder 491 is fixed at the rotating end of the first rotary cylinder 49, and two symmetrically arranged arc fixing plates 492 are arranged at the clamping end of the first clamping cylinder 491; first lead screw slip table 471 removes and to make first lift cylinder 462 remove to the top of inlayer core cotton 15, first lift cylinder 462 work can make the elevating platform 48 drive first centre gripping cylinder 491 and remove to the top of inlayer core cotton 15, first centre gripping cylinder 491 work can make two arc fixed plates 492 near each other, make two arc fixed plates 492 can carry out the tight operation of clamp to inlayer core cotton 15, first lead screw slip table 471 work can remove inlayer core cotton 15 to the top of core print 11, can gather the orientation of part on the stationary blade 14 and inlayer core cotton 15 under the effect of image acquisition unit, make first revolving cylinder 49 can adjust the orientation of core cotton 15, make inlayer core cotton 15 can avoid touching with the part on the stationary blade 14 in the in-process of assembly.

Specifically, the outer-layer core cotton assembling mechanism 5 comprises a fixed table 51, an outer-layer core cotton conveying assembly 52, a stepping motor 521, a limiting plate 522 and two horizontally arranged support rods 523, wherein the limiting plate 522 is arranged at the end parts of the two support rods 523, a conveying screw 53 in rotary fit with the limiting plate 522 and the fixed table 51 is arranged between the limiting plate 522 and the fixed table 51, a feeding plate 54 in threaded fit with the conveying screw 53 is arranged on the conveying screw 53, and the output end of the stepping motor 521 is fixedly connected with the end part of the conveying screw 53; can realize the automatic feeding to outer core cotton 16 through outer core cotton assembly devices 5, make outer core cotton 16 can be taken out in proper order to step motor 521 work can make feeding plate 54 horizontal migration, makes outer core cotton 16 can move to the position that is pressed from both sides tightly by second centre gripping cylinder 583.

Specifically, the outer core cotton conveying assembly 52 comprises a first conveying cylinder 55, a second lifting cylinder 56 and a support bracket 57 arranged at the side of the conveyor belt 2, the first conveying cylinder 55 is horizontally arranged at one side of the support bracket 57, a material moving table 58 in sliding fit with the support bracket 57 is arranged at the top of the support bracket 57, the output end of the first conveying cylinder 55 is fixedly connected with the side wall of the material moving table 58, the second lifting cylinder 56 is vertically arranged at the top of the material moving table 58, an installation table 581 is fixed at the output end of the second lifting cylinder 56, a second rotating cylinder 582 vertically arranged is arranged on the installation table 581, a second clamping cylinder 583 is arranged at the rotating end of the second rotating cylinder 582, and an arc-shaped clamping plate 59 is arranged at the clamping end of the second clamping cylinder 583; the second clamping cylinder 583 can make the two arc-shaped clamping plates 59 move relatively, so that the two arc-shaped plates can clamp the outer-layer core cotton 16, the clamped outer-layer core cotton 16 can be moved to the upper side of the conveyor belt 2 under the action of the first conveying cylinder 55, the second rotating cylinder 582 can make the vertical outer-layer core cotton 16 in a horizontal state, and the second lifting cylinder 56 can make the clamped outer-layer core cotton 16 assembled on the core base 11 to complete the assembly operation of the anesthetic evaporator core 1.

Specifically, the core pipe feeding mechanism 3 includes a fixed frame 31, a sliding table 32, a transverse conveying assembly 35, a third lifting cylinder 33, a core pipe clamping assembly 37 and a connecting table 34, the core pipe clamping assembly 37 is arranged on the connecting table 34, two first sliding rails 321 horizontally arranged are arranged at the top of the fixed frame 31, each first sliding rail 321 is provided with a sliding block 322 in sliding fit with the first sliding rail, the sliding table 32 is fixed at the tops of the two sliding blocks 322, the third lifting cylinder 33 is vertically arranged at the top of the sliding table 32, the output end of the third lifting cylinder 33 is fixedly connected with the top of the connecting table 34, the top of the connecting table 34 is provided with a vertically arranged guide rod 323, and the top of the sliding table 32 is provided with a through hole for the guide rod 323 to pass through; the first slide rail 321 is used for guiding and supporting the slide block 322, the third lifting cylinder 33 is used for vertically moving the connecting table 34, so that the core tube clamping assembly 37 on the connecting table 34 can be lifted to a position capable of clamping the core tube 12, and the guide rod 323 is used for guiding the lifting of the connecting table 34.

Specifically, the transverse conveying assembly 35 includes a conveying motor 351 and two rotating shafts 352 horizontally arranged, the two rotating shafts 352 are respectively arranged at two sides of the fixing frame 31, two ends of each rotating shaft 352 are rotatably matched with the fixing frame 31, each rotating shaft 352 is sleeved with a synchronizing wheel 353, the two synchronizing wheels 353 are in transmission connection through a synchronizing belt 36, a driving frame fixedly connected with the synchronizing belt 36 is arranged at the bottom of the sliding table 32, and an output end of the conveying motor 351 is fixedly connected with one of the rotating shafts 352; the conveying motor 351 is capable of driving one of the rotating shafts 352 to rotate, so that the synchronizing wheel 353 can drive the synchronizing belt 36 to move, the synchronizing belt 36 can drive the sliding table 32 to move along the conveying direction of the synchronizing belt 36 through the driving frame, and the sliding table 32 can drive the core pipe clamping assembly 37 to move transversely.

Specifically, the core pipe clamping assembly 37 includes a driving motor 371, two supporting rails 372 arranged on the connecting table 34 at intervals, and two horizontally arranged material moving strips 373, wherein the two material moving strips 373 are respectively in sliding fit with the two supporting rails 372, the driving motor 371 is arranged at the top of the connecting table 34, a driving gear 374 is sleeved on an output end of the driving motor 371, the driving gear 374 is arranged between the two material moving strips 373, tooth grooves 375 meshed with the driving gear 374 are respectively arranged on the two material moving strips 373, an extending frame 38 is arranged at one end of each material moving strip 373 opposite to the other end, a clamping block 381 is arranged at the bottom of each extending frame 38, and an arc-shaped groove 382 is arranged at one end of each clamping block 381 opposite to the clamping block 381; the driving motor 371 is capable of enabling the driving gear 374 to rotate in the working process, the driving gear 374 is capable of driving the two material moving strips 373 to be close to each other, the two clamping blocks 381 are capable of being close to each other to complete clamping operation on the core pipeline 12, the supporting tracks 372 are used for guiding and supporting the material moving strips 373, and the tooth grooves 375 are used for enabling the driving gear 374 to drive the material moving strips 373 to move.

Specifically, core pipeline assembly devices 6 includes vibration dish 61, cotton parcel subassembly 7, ridge roof beam skeleton material loading subassembly 8, stationary blade welding subassembly 97 and stationary blade material loading subassembly 9, ridge roof beam skeleton material loading subassembly 8 sets up between cotton parcel subassembly 7 and vibration dish 61, be equipped with workstation 95 between stationary blade welding subassembly 97 and the stationary blade material loading subassembly 9, cotton parcel subassembly 7 is including cotton parcel part 75, rubber coating compress part 76, pay-off platform 71, support 73, feeding cylinder 74 and automatic cutout part 78, rubber coating compress part 76 and cotton parcel part 75 all set up the top at pay-off platform 71, one side of pay-off platform 71 is equipped with vertical support riser 72 of setting, automatic cutout part 78 sets up the top at support riser 72, feeding cylinder 74 level sets up the top at support 73, the top of the bracket 73 is provided with two horizontally arranged guide rails 721, the bottom of the feeding table 71 is in sliding fit with the two guide rails 721, and the output end of the feeding cylinder 74 is fixedly connected with the side wall of the feeding table 71; the cotton cloth wheel 752 can automatically wrap the ridge beam framework 13 through the cotton cloth wrapping assembly 7, the cotton cloth on the cotton cloth wheel 752 wraps the ridge beam framework 13, the cloth pressing strip 765 can press one end of the cotton cloth, the spraying pipeline 77 can spray glue solution to the cotton cloth, automatic cutting of the cotton cloth can be completed under the action of the automatic cutting component 78, the automation degree is high, manual wrapping operation of workers on the cotton cloth is not needed, storage and sequential feeding of the fixing pieces 14 can be achieved through the fixing piece feeding assembly 9, the placed fixing pieces 14 can be sequentially taken out, the fixing pieces 14 can be rotated to be in a horizontal state, the fixing pieces 14 can be conveniently installed at the top of the core pipeline 12, welding operation of the fixing pieces 14 and the core pipeline 12 can be completed through the welding machine 98, the feeding cylinder 74 can enable the feeding table 71 to horizontally move, the cotton cloth wheel 752 can move to a position where the core pipeline 12 can be wound, the spine skeleton feeding assembly 8 can place the wrapped spine skeleton 13 at the top of the storage table 81, so that the core pipeline feeding mechanism 3 moves the wrapped core pipeline 12 to the top of the workbench 95, and the assembly of the core pipeline 12 and the fixing piece 14 is completed.

Specifically, the cotton cloth wrapping part 75 comprises a rotating motor 751, a cotton cloth wheel 752, a vertically arranged rotating ring 753 and four rotating shafts 754 circumferentially distributed on the side wall of the supporting vertical plate 72, each rotating shaft 754 is rotatably connected with the side wall of the supporting vertical plate 72, a driving wheel 755 is sleeved at the end of each rotating shaft 754, the rotating ring 753 is in transmission fit with the four driving wheels 755, the cotton cloth wheel 752 is horizontally arranged on the side wall of the driving wheel 755, a belt pulley 756 is sleeved at the end of each rotating shaft 754, the four belt pulleys 756 are in transmission connection through a synchronous belt 757, and the output end of the rotating motor 751 is connected with the end of one of the rotating shafts 754 through a coupler; the ridge beam framework 13 can be automatically wrapped by the cotton cloth wheel 752 through the cotton cloth wrapping component 7, the ridge beam framework 13 can be wrapped by the cotton cloth on the cotton cloth wheel 752, the cloth pressing strip 765 can press one end of the cotton cloth tightly, the spraying pipeline 77 can spray glue solution to the cotton cloth, automatic cutting of the cotton cloth can be completed under the action of the automatic cutting component 78, the automation degree is high, manual wrapping operation of the cotton cloth by workers is not needed, great convenience is brought to the workers, the ridge beam framework 13 can be in a horizontal state due to the work of the fourth rotary cylinder 84, the axis of the ridge beam framework 13 and the axis of the rotary ring 753 are located on the same straight line, the rotary motor 751 can drive one rotary shaft 754 to rotate, synchronous rotation of the four rotary shafts 754 can be achieved under the action of the synchronous belt 757, synchronous rotation of the four driving wheels 755 is achieved, and the rotary ring 753 can rotate, the rotating ring 753 is enabled to drive the cotton cloth wheel 752 to rotate around the axis of the rotating ring 753, and the cotton cloth wheel 752 can wind cotton cloth on the ridge beam framework 13 in the rotating process.

Specifically, the gluing and cloth pressing component 76 comprises a third rotary cylinder 761, a double-rod cylinder 762 and a fixed vertical plate 764 arranged at the top of the feeding table 71, the third rotary cylinder 761 is mounted on a side wall of the fixed vertical plate 764, the double-rod cylinder 762 is arranged at a rotating end of the third rotary cylinder 761, a through hole is formed in the supporting vertical plate 72, a connecting plate 763 is arranged at an output end of the double-rod cylinder 762, a spraying pipeline 77 is arranged on the connecting plate 763, a spraying nozzle 771 is arranged on the spraying pipeline 77, and a cloth pressing strip 765 is fixed on a side wall of the connecting plate 763; third revolving cylinder 761 work can make cloth pressing strip 765 drive the cotton and rotate, makes the tip of cotton can contradict with the surface of ridge roof beam skeleton 13, makes cotton wheel 752 can wind the cotton on ridge roof beam skeleton 13 at the pivoted in-process, and spraying pipeline 77 can be with the glue solution spraying on the surface of cotton, makes the cotton can bind at the winding in-process and accomplish the parcel to core pipeline 12.

Specifically, the automatic cutting component 78 includes a fourth lifting cylinder 781 and a transverse plate 782 horizontally disposed on the top of the supporting vertical plate 72, the fourth lifting cylinder 781 is vertically disposed on the top of the transverse plate 782, a horizontally disposed tool holder 783 is fixed on an output end of the fourth lifting cylinder 781, and a cutting blade 784 is disposed at the bottom of the tool holder 783; the fourth lifting cylinder 781 is operated to drive the cutting blade 784 to move, so that the cutting blade 784 can cut cotton cloth.

Specifically, the ridge beam framework feeding assembly 8 comprises a rotating part 87, a fixed frame, a second lead screw sliding table 82 and a rotating cylinder 83 vertically arranged at the top of the fixed frame, the bottom end of the rotating cylinder 83 is connected with the top of the fixed frame through a bearing, the second lead screw sliding table 82 is vertically arranged at the top of the rotating cylinder 83, a fourth rotating cylinder 84 is arranged at the moving end of the second lead screw sliding table 82, a connecting transverse plate 85 fixedly connected with the fourth rotating cylinder 84 is arranged at the rotating end of the fourth rotating cylinder 84, a third clamping cylinder 851 is arranged at the end part of the connecting transverse plate 85, two tensioning plates 852 are arranged at the clamping end of the third clamping cylinder 851, cambered surfaces are arranged at the opposite ends of the two tensioning plates 852, the rotating part 87 is arranged at the top of the fixed frame, and a feeding channel 86 communicated with the vibrating plate 61 is arranged on the vibrating plate; the fourth rotary cylinder 84 can make the ridge beam framework 13 be the horizontality in work, the axis that makes the ridge beam framework 13 and the axis of rotatory ring 753 are located same straight line, the second lead screw slip table 82 can drive the third centre gripping cylinder 851 and move to the top of the ridge beam framework 13 in the transfer passage 434, the work of the second lead screw slip table 82 can make the tensioning plate 852 on the third centre gripping cylinder 851 move to the ridge beam framework 13 in, the work of the third centre gripping cylinder 851 makes two tensioning plates 852 keep away from each other and clamp the ridge beam framework 13.

Specifically, the rotating part 87 comprises a rotating motor 871, a worm wheel 872 sleeved on the rotating cylinder 83 and two connecting seats 873 arranged at the top of the fixing frame at intervals, a worm 874 which is in rotating fit with the two connecting seats 873 is arranged between the two connecting seats 873, the worm 874 is meshed with the worm wheel 872, the output end of the rotating motor 871 is fixedly connected with the end part of the worm wheel 874, and a storage table 81 is arranged beside the fixing frame; the work of rotating motor 871 can drive worm 874 and rotate, makes worm 874 drive rather than the worm wheel 872 of meshing and rotates, makes the worm wheel 872 drive rotatory section of thick bamboo 83 and rotates, makes rotatory section of thick bamboo 83 can drive second lead screw slip table 82 and remove, deposits the platform 81 and is used for depositing temporarily to the core pipeline 12 after the parcel.

Specifically, the fixed plate feeding assembly 9 includes a bearing table 91, a fifth rotary cylinder 92, a rotary table 93 and an installation frame 94 arranged at the top of the bearing table 91, a sliding table 941 in sliding fit with the installation frame 94 is arranged in the installation frame 94, two bearing seats arranged at intervals are arranged at the bottom of the sliding table 941, a rotary cylinder 943 rotationally connected with the bearing seats is arranged between the two bearing seats, the rotary end of the fifth rotary cylinder 92 is fixedly connected with the end of the rotary cylinder 943, two connecting bars 944 arranged at intervals and fixedly connected with the rotary table 93 are sleeved on the rotary cylinder 943, a fourth clamping cylinder 945 is arranged at the bottom of the rotary table 93, two material taking blocks 946 are arranged at the clamping end of the fourth clamping cylinder 945, and the back parts of the two material taking blocks 946 are provided with limiting grooves; the fixed sheets 14 can be stored and sequentially loaded through the fixed sheet loading assembly 9, so that the placed fixed sheets 14 can be sequentially taken out, and the fixing plate 14 can be rotated to be in a horizontal state, so that the fixing plate 14 can be conveniently installed at the top of the core pipeline 12, the welding machine 98 can complete the welding operation of the fixing plate 14 and the core pipeline 12, the fourth clamping cylinder 945 works to enable the material fetching block 946 to realize the clamping operation of the fixing plate 14, the turning of the rotary cylinder 943 and the fourth clamping cylinder 945 can be realized under the action of the fifth rotary cylinder 92, so that the fixing plate 14 can be turned to be in a horizontal state, the fixing plate 14 is convenient to mount at the top of the core pipeline 12, the fixing plate 14 can be clamped by the limiting groove, and the fixing plate 14 for the anesthetic evaporator core 1 in the prior art is generally in an annular structure, so that the fixing plate 14 cannot deviate in the clamping process.

Specifically, the fixed sheet feeding assembly 9 further includes a stepping motor 951, a limiting strip 952 and a bearing rod 953, the stepping motor 951 is arranged on a side wall of the mounting frame 94, the limiting strip 952 and the bearing rod 953 are both horizontally arranged on a side wall of the bearing table 91, two extending plates 954 arranged at intervals are arranged on the side wall of the mounting frame 94, a feeding screw 955 is arranged between the two extending plates 954, an output end of the stepping motor 951 is fixedly connected with the feeding screw 955, a feeding plate 96 in threaded fit with the feeding screw 955 is arranged on the feeding screw 955, and the feeding plate 96 is fixedly connected with the sliding table 941; step motor 951 work can drive pay-off lead screw 955 and take place to rotate, makes pay-off lead screw 955 can drive feed plate 96 and remove, makes feed plate 96 can drive slip table 941 horizontal migration, makes slip table 941 can drive and rotate a section of thick bamboo 943 and fourth centre gripping cylinder 945 and move, makes fourth centre gripping cylinder 945 can move to the position that can carry out the centre gripping to stationary blade 14.

Specifically, the fixing plate welding assembly 97 comprises a heightening frame 971, a second conveying cylinder 972, a feeding table 973, a welding machine 98 and two second slide rails 981 horizontally arranged at the top of the heightening frame 971, each second slide rail 981 is provided with a feeding block 982 in sliding fit with the second slide rail, the output end of the second conveying cylinder 972 is connected with the side wall of the feeding table 973, the feeding table 973 is fixed at the tops of the two feeding blocks 982, and the welding machine 98 is vertically arranged at the top of the feeding table 973; the second conveying cylinder 972 can enable the feeding table 973 to move horizontally, the feeding table 973 can drive the welding machine 98 to move above the fixing plate 14, the welding machine 98 can weld the fixing plate 14 and the core pipe 12, and the second sliding rail 981 is used for supporting and guiding the feeding table 973.

The working principle of the invention is as follows: the worker manually places the core seat 11 on the conveyor belt 2, so that the three limiting rings 22 can limit the core seat 11, the worker places the ridge beam framework 13 in the vibration disc 61, sequentially places the plurality of fixing pieces 14 on the bearing rod 953 and the limiting strips 952, the limiting strips 952 can limit the fixing pieces 14, places the inner core cotton 15 in the conveying channel 434 in the storage box 432, sleeves the plurality of outer core cotton 16 on the supporting rod 523, the vibration disc 61 can convey the ridge beam framework 13 to the tail end of the conveying channel 86, the ridge beam framework 13 can be taken out of the vibration disc 61 through the ridge beam framework feeding assembly 8, the ridge beam framework 13 can be rotated to the horizontal state, the cotton cloth wrapping assembly 7 can wrap the ridge beam framework 13 conveniently, the wrapped ridge beam framework 13 can be placed at the top of the storage table 81, and the core pipeline feeding mechanism 3 can move the wrapped core pipeline 12 conveniently, the rotation motor 871 can drive the worm 874 to rotate, so that the worm 874 can drive the worm gear 872 engaged with the worm gear 872 to rotate, the worm gear 872 can drive the rotary cylinder 83 to rotate, the rotary cylinder 83 can drive the second lead screw sliding table 82 to move, the second lead screw sliding table 82 can drive the third clamping cylinder 851 to move to the upper part of the ridge beam framework 13 in the vibration disc 61, the second lead screw sliding table 82 can drive the tension plate 852 on the third clamping cylinder 851 to move to the ridge beam framework 13, the third clamping cylinder 851 works to enable the two tension plates 852 to be far away from each other to clamp the ridge beam framework 13, the cotton cloth wheel 752 can automatically wrap the ridge beam framework 13 through the cotton cloth wrapping component 7, the cotton cloth on the cotton wheel 752 wraps the ridge beam framework 13, the cloth pressing strip 765 can press one end of the cotton cloth, and the spraying pipeline 77 can spray the cotton glue solution, the cotton cloth can be automatically cut under the action of the automatic cutting part 78, the degree of automation is high, the cotton cloth is not required to be wrapped manually by workers, great convenience is brought to the workers, the fourth rotary cylinder 84 can enable the ridge beam framework 13 to be in a horizontal state, the axis of the ridge beam framework 13 and the axis of the rotary ring 753 are located on the same straight line, the rotary motor 751 can drive one rotary shaft 754 to rotate when working, the four rotary shafts 754 can synchronously rotate under the action of the synchronous belt 757 to realize the synchronous rotation of the four transmission wheels 755, the rotary ring 753 can rotate, the rotary ring 753 can drive the cotton cloth wheel 752 to rotate around the axis of the rotary ring 753, the double-rod cylinder 762 can push the cloth pressing strip 765 to the direction of the rotary ring 753 when working, and the third rotary cylinder 761 can enable the cloth pressing strip 765 to drive the cotton cloth to rotate, the end part of the cotton cloth can be abutted against the surface of the ridge beam framework 13, the cotton cloth can be wound on the ridge beam framework 13 by the cotton cloth wheel 752 in the rotating process, the glue solution can be sprayed on the surface of the cotton cloth by the spraying pipeline 77, the cloth pressing strip 765 can be separated from the ridge beam framework 13 by the double-rod cylinder 762 working again, the cutting blade 784 can be driven to move by the fourth lifting cylinder 781 working, the cotton cloth can be cut by the cutting blade 784, the ridge beam framework feeding assembly 8 can place the wrapped ridge beam framework 13 on the top of the storage table 81, the core pipeline feeding mechanism 3 can move the wrapped core pipeline 12 to the top of the workbench 95 to complete the assembly of the core pipeline 12 and the fixing sheet 14, one rotating shaft 352 can be driven to rotate by the conveying motor 351 working, the synchronizing wheel 353 can drive the synchronizing belt 36 to move, and the synchronizing belt 36 can drive the sliding table 32 to move along the conveying direction of the synchronizing belt 36 by the driving frame, the sliding table 32 can drive the core pipeline clamping assembly 37 to move transversely, the driving motor 371 can drive the driving gear 374 to rotate when working, the driving gear 374 can drive the two material moving strips 373 to approach each other, the two clamping blocks 381 can approach each other to complete the clamping operation on the core pipeline 12, the fixing sheet feeding assembly 9 can be used for storing and sequentially feeding the fixing sheets 14, the placed fixing sheets 14 can be sequentially taken out, the fixing sheets 14 can be rotated to be in a horizontal state, the fixing sheets 14 are conveniently installed at the top of the core pipeline 12, and the welding machine 98 can complete the welding operation of the fixing sheets 14 and the core pipeline 12; the stepping motor 951 can drive the feeding screw rod 955 to rotate, the feeding screw rod 955 can drive the feeding plate 96 to move, the feeding plate 96 can drive the sliding table 941 to move horizontally, the sliding table 941 can drive the rotating cylinder 943 and the fourth clamping cylinder 945 to move, the fourth clamping cylinder 945 can move to a position where the fixed plate 14 can be clamped, the fourth clamping cylinder 945 can work to clamp the fixed plate 14, the fixed plate 14 can be taken out after the stepping motor 951 works again, the rotating cylinder 943 and the fourth clamping cylinder 945 can be turned over under the action of the fifth rotating cylinder 92, the fixed plate 14 can be turned over to be in a horizontal state, the fixed plate 14 can be conveniently installed at the top of the core pipeline 12, the feeding table 973 can move horizontally by the second conveying cylinder 972, the feeding table 973 can drive the welding machine 98 to move above the fixed plate 14, enabling the welder 98 to perform a welding operation on the stator 14 and the core tube 12; the welded core pipeline 12 can be moved to the core base 11 under the secondary action of the core pipeline feeding mechanism 3, so that the core pipeline 12 can be clamped on the core base 11, the inner core cotton assembly mechanism 4 can automatically arrange a plurality of inner core cotton 15 in sequence, so that the inner core cotton 15 can be sequentially assembled on the core base 11 on the conveyor belt 2, so that the inner core cotton 15 can be automatically assembled on the core base 11, the pushing electric cylinder 43 can work to enable a plurality of pushing plates 45 to move along the length direction of the conveying channel 434, so that the inner core cotton 15 in the conveying channel 434 can move to the conveyor belt 42, so that a row of inner core cotton 15 close to the conveyor belt 42 can move to the conveyor belt 42, the conveyor belt 42 can work to move the inner core cotton 15 to the lower part of the material moving component 46, the first lead screw sliding table 471 can move to enable the first lifting cylinder 462 to move to the upper part of the inner core cotton 15, the first lifting cylinder 462 can make the lifting platform 48 drive the first clamping cylinder 491 to move to the upper part of the inner core cotton 15, the first clamping cylinder 491 can make the two arc fixing plates 492 to approach each other, the two arc fixing plates 492 can clamp the inner core cotton 15, the first screw sliding platform 471 can make the inner core cotton 15 move to the upper part of the core base 11, the parts on the fixing plate 14 and the orientation of the inner core cotton 15 can be collected under the action of the image collecting unit, the first rotary cylinder 49 can adjust the orientation of the inner core cotton 15, so that the inner core cotton 15 can avoid touching the parts on the fixing plate 14 in the assembling process, the outer core cotton 16 can be automatically fed through the outer core cotton assembling mechanism 5, the outer core cotton 16 can be taken out in sequence, and the stepper motor 951 can make the feeding plate 54 move horizontally, the outer-layer core cotton 16 can move to the position clamped by the second clamping cylinder 583, the second clamping cylinder 583 can enable the two arc-shaped clamping plates 59 to move relatively when working, the two arc-shaped plates can clamp the outer-layer core cotton 16, the clamped outer-layer core cotton 16 can move to the upper side of the conveyor belt 2 under the action of the first conveying cylinder 55, the second rotating cylinder 582 can enable the vertical outer-layer core cotton 16 to be in a horizontal state when working, and the second lifting cylinder 56 can enable the clamped outer-layer core cotton 16 to be assembled on the core base 11 when working, so that the assembling operation of the anesthetic evaporator core 1 is completed.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (8)

1. A core pipeline assembling mechanism of an automatic production line of an anesthetic evaporator core is characterized by comprising a vibration disc (61), a cotton cloth wrapping component (7), a ridge beam framework feeding component (8), a fixing piece welding component (97) and a fixing piece feeding component (9), wherein the ridge beam framework feeding component (8) is arranged between the cotton cloth wrapping component (7) and the vibration disc (61), a workbench (95) is arranged between the fixing piece welding component (97) and the fixing piece feeding component (9), the cotton cloth wrapping component (7) comprises a cotton cloth wrapping component (75), a gluing cloth pressing component (76), a feeding table (71), a support (73), a feeding air cylinder (74) and an automatic cutting component (78), the gluing cloth pressing component (76) and the cotton cloth wrapping component (75) are arranged at the top of the feeding table (71), one side of the feeding table (71) is provided with a vertically-arranged supporting vertical plate (72), the automatic cutting part (78) is arranged at the top of a supporting vertical plate (72), the feeding air cylinder (74) is horizontally arranged at the top of a support (73), two horizontally arranged guide rails (721) are arranged at the top of the support (73), the bottom of the feeding table (71) is in sliding fit with the two guide rails (721), the output end of the feeding air cylinder (74) is fixedly connected with the side wall of the feeding table (71), the cotton cloth wrapping part (75) comprises a rotating motor (751), a cotton cloth wheel (752), a vertically arranged rotating ring (753) and four rotating shafts (754) which are circumferentially distributed on the side wall of the supporting vertical plate (72), each rotating shaft (754) is in rotating connection with the side wall of the supporting vertical plate (72), a driving wheel (755) is sleeved at the end of each rotating shaft (754), and the rotating ring (753) is in driving fit with the four driving wheels (755), the cotton cloth wheel (752) is horizontally arranged on the side wall of the transmission wheel (755), a belt pulley (756) is sleeved at the end of each rotating shaft (754), the four belt pulleys (756) are in transmission connection through a synchronous belt (757), and the output end of the rotating motor (751) is connected with the end of one rotating shaft (754) through a coupling.

2. The core pipe assembling mechanism of the anesthesia evaporator core automatic production line according to claim 1, wherein the gluing and cloth pressing component (76) comprises a third rotary cylinder (761), a double-rod cylinder (762) and a fixed vertical plate (764) arranged at the top of the feeding table (71), the third rotary cylinder (761) is installed on the side wall of the fixed vertical plate (764), the double-rod cylinder (762) is arranged at the rotating end of the third rotary cylinder (761), a through hole is arranged on the supporting vertical plate (72), a connecting plate (763) is arranged at the output end of the double-rod cylinder (762), a spraying pipe (77) is arranged on the connecting plate (763), a spraying nozzle (771) is arranged on the spraying pipe (77), and a cloth pressing strip (765) is fixed on the side wall of the connecting plate (763).

3. The core pipe assembling mechanism of the anesthesia evaporator core automatic production line of claim 1, wherein the automatic cutting component (78) comprises a fourth lifting cylinder (781) and a cross plate (782) horizontally arranged on the top of the supporting vertical plate (72), the fourth lifting cylinder (781) is vertically arranged on the top of the cross plate (782), a horizontally arranged cutter holder (783) is fixed on the output end of the fourth lifting cylinder (781), and a cutting blade (784) is arranged at the bottom of the cutter holder (783).

4. The core pipe assembling mechanism of the anesthesia evaporator core automatic production line according to claim 1, wherein the ridge beam framework feeding assembly (8) comprises a rotating part (87), a fixed frame, a second lead screw sliding table (82) and a rotating cylinder (83) vertically arranged at the top of the fixed frame, the bottom end of the rotating cylinder (83) is connected with the top of the fixed frame through a bearing, the second lead screw sliding table (82) is vertically arranged at the top of the rotating cylinder (83), a fourth rotating cylinder (84) is arranged at the moving end of the second lead screw sliding table (82), a connecting transverse plate (85) fixedly connected with the fourth rotating cylinder (84) is arranged at the rotating end of the fourth rotating cylinder (84), a third clamping cylinder (851) is arranged at the end part of the connecting transverse plate (85), two tensioning plates (852) are arranged at the clamping end of the third clamping cylinder (851), two the one end that tensioning plate (852) carried on the back mutually all is equipped with the cambered surface, rotary part (87) set up the top at the mount, be equipped with on vibration dish (61) rather than pay-off passageway (86) of intercommunication.

5. The core pipeline assembling mechanism of the anesthesia evaporator core automatic production line of claim 4, wherein the rotating component (87) comprises a rotating motor (871), a turbine (872) sleeved on the rotating cylinder (83) and two connecting seats (873) arranged at the top of the fixing frame at intervals, a worm (874) in rotating fit with the connecting seats (873) is arranged between the two connecting seats, the worm (874) is meshed with the turbine (872), the output end of the rotating motor (871) is fixedly connected with the end part of the worm (874), and a storage table (81) is arranged beside the fixing frame.

6. The core pipe assembling mechanism of the anesthesia evaporator core automatic production line according to claim 1, wherein the fixing plate feeding assembly (9) comprises a bearing table (91), a fifth rotary cylinder (92), a rotary table (93) and a mounting frame (94) arranged at the top of the bearing table (91), a sliding table (941) in sliding fit with the mounting frame (94) is arranged in the mounting frame (94), two bearing seats arranged at intervals are arranged at the bottom of the sliding table (941), a rotary cylinder (943) in rotary connection with the bearing seats is arranged between the two bearing seats, the rotary end of the fifth rotary cylinder (92) is fixedly connected with the end of the rotary cylinder (943), two connecting strips (944) which are arranged at intervals and are fixedly connected with the rotary table (93) are sleeved on the rotary cylinder (943), a fourth clamping cylinder (945) is arranged at the bottom of the rotary table (93), two material taking blocks (942) are arranged on the clamping end of the fourth clamping cylinder (945), and limiting grooves are formed in the back parts of the two material taking blocks (942).

7. The core pipe assembling mechanism of the anesthesia evaporator core automatic production line of claim 6, characterized in that the fixing sheet feeding assembly (9) further comprises a stepping motor (521), a limiting strip (952) and a bearing rod (953), the stepping motor (521) is arranged on the side wall of the mounting frame (94), the limiting strip (952) and the bearing rod (953) are horizontally arranged on the side wall of the bearing table (91), two extending plates (954) are arranged at intervals on the side wall of the mounting frame (94), a feeding screw rod (955) is arranged between the extending plates (954), the output end of the stepping motor (521) is fixedly connected with the feeding screw rod (955), a feeding plate (96) in threaded fit with the feeding screw rod (955) is arranged on the feeding screw rod (955), and the feeding plate (96) is fixedly connected with the sliding table (941).

8. The core pipe assembling mechanism of the anesthesia evaporator core automatic production line according to claim 6, wherein the fixing plate welding assembly (97) comprises an elevating frame (971), a second conveying cylinder (972), a feeding table (973), a welding machine (98) and two second slide rails (981) horizontally arranged at the top of the elevating frame (971), each second slide rail (981) is provided with a feeding block (982) in sliding fit with the second slide rail, the output end of the second conveying cylinder (972) is connected with the side wall of the feeding table (973), the feeding table (973) is fixed at the top of the two feeding blocks (982), and the welding machine (98) is vertically arranged at the top of the feeding table (973).

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