阅读说明：本技术 一种耐高温铝箔伸缩风管制造加工工艺 (Manufacturing and processing technology of high-temperature-resistant aluminum foil telescopic air duct ) 是由 李奉喜 钱昌杰 于 2020-05-30 设计创作，主要内容包括：本发明公开了一种耐高温铝箔伸缩风管制造加工工艺,涉及耐高温设备加工技术领域,该耐高温铝箔伸缩风管制造加工工艺采用一种耐高温铝箔伸缩风管制造加工装置配合完成,该耐高温铝箔伸缩风管制造加工装置包括底座,所述底座的顶端设有直立于底座顶端的支撑板,所述支撑板的顶端左侧设有圆柱形结构的轴杆套筒,所述轴杆套筒的轴线位置开设有贯通的轴孔。本发明通过上包壳与下包壳扣合,上包壳的半圆弧槽与下包壳的半圆弧槽拼接为贯通的圆孔将伸缩骨架抱紧,使放置在下包壳半圆弧槽内的铝箔布沿圆孔内壁将伸缩骨架包裹,使伸缩骨架的外圆面包裹严实,提高对伸缩骨架的包裹严密性。(The invention discloses a manufacturing and processing technology of a high-temperature-resistant aluminum foil telescopic air pipe, and relates to the technical field of high-temperature-resistant equipment processing. According to the invention, the upper and lower casings are buckled, and the semi-arc grooves of the upper and lower casings are spliced into the through round hole to hold the telescopic framework tightly, so that the aluminum foil cloth placed in the semi-arc grooves of the lower casing wraps the telescopic framework along the inner wall of the round hole, the outer circular surface of the telescopic framework is tightly wrapped, and the wrapping tightness of the telescopic framework is improved.)

1. The utility model provides a processing technology is made to flexible tuber pipe of high temperature resistant aluminium foil, this technology is applied to flexible tuber pipe and makes in the processing, wraps up the aluminium foil cloth to the flexible skeleton in the flexible tuber pipe, and this processing technology is made to flexible tuber pipe of high temperature resistant aluminium foil adopts a processing apparatus cooperation completion is made to flexible tuber pipe of high temperature resistant aluminium foil, and this processing apparatus is made to flexible tuber pipe of high temperature resistant aluminium foil includes base, its characterized in that: the top end of the base is provided with a supporting plate which is upright at the top end of the base, the left side of the top end of the supporting plate is provided with a shaft lever sleeve with a cylindrical structure, a through shaft hole is formed in the axis position of the shaft lever sleeve, a shaft lever is installed in the shaft hole of the shaft lever sleeve in a sliding fit mode, the top end of the shaft lever installed in the shaft hole is provided with a coupler, the right side of the supporting plate is fixedly provided with a servo motor, the top end of an output shaft of the servo motor is fixedly connected with the shaft lever through the coupler, the left end of the shaft lever is provided with a cylindrical roller, and the;

the top end of the base is provided with a square block-shaped lower cladding base, the top end of the lower cladding base is fixedly provided with a tile-shaped lower cladding, the top end of the lower cladding is provided with a semi-arc groove with an upward opening, the bottom end of the lower cladding is fixed on the lower cladding base, the top end of the lower cladding base is hinged with a tile-shaped upper cladding, the top end of the upper cladding is provided with a semi-arc groove, the semi-arc groove of the upper cladding and the semi-arc groove of the lower cladding are spliced into a through round hole, and the semi-arc groove of the lower cladding is arranged at the sagging position of the top end of the aluminum;

the outer wall of the upper cladding is provided with a hinged support, the top end of the base of the lower cladding behind the lower cladding is hinged with a hydraulic rod, and the top end of the hydraulic rod is hinged and fixed on the hinged support;

the top end of the base is provided with a support rib plate standing upright at the top end of the base, the middle part of the support rib plate is provided with a square block-shaped sliding hole, a square rod-shaped sliding block is embedded in the sliding hole of the support rib plate in a sliding fit mode, the bottom end of the sliding block is provided with a rack, the side wall of the support rib plate close to the rack is fixedly provided with a third servo motor, an output shaft extends out of the third servo motor, the top end of the output shaft of the third servo motor is fixedly provided with a driving gear, and the driving gear is connected with a rack meshing strip at the bottom end of the sliding block;

the middle part of the sliding block is provided with a through shaft hole, a second shaft lever is arranged in the middle shaft hole of the sliding block through a bearing, the right end of the second shaft lever extends out of the right end of the sliding block, a second gear is arranged at the top end of the second shaft lever extending out of the right end of the sliding block, a second servo motor is fixedly arranged at the right end of the sliding block, the second servo motor is fixedly arranged on the sliding block through a motor fixing frame, a first gear is arranged at the top end of an output shaft of the second servo motor, and the first gear is meshed with the second gear;

a compression roller with a cylindrical structure is arranged on the outer wall of the left end of the second shaft lever, two ends of the compression roller are symmetrically hinged to the supporting frames, and the bottoms of the supporting frames at the two ends of the compression roller are symmetrically fixed on the outer circular surface of the second shaft lever;

the manufacturing and processing technology of the high-temperature-resistant aluminum foil telescopic air duct specifically comprises the following steps:

s1, mounting aluminum foil cloth: winding the aluminum foil cloth on the outer circular surface of the roller;

s2, placing aluminum foil cloth: the roller is driven to rotate by the servo motor, and the drooping top end of the aluminum foil cloth is placed in the semicircular groove of the lower cladding;

s3, placing an expansion framework: placing a telescopic framework in the semi-arc groove of the lower cladding in which the aluminum foil cloth is placed in the step S2, and horizontally placing the telescopic framework in the semi-arc groove of the lower cladding to press the aluminum foil cloth placed in the semi-arc groove below the telescopic framework;

s4, wrapping the outer wall of the telescopic skeleton: wrapping the outer wall of the telescopic framework placed in the semi-circular arc groove of the lower cladding in the step S3 with aluminum foil cloth, buckling the upper cladding with the lower cladding, wrapping the aluminum foil cloth along the outer wall of the telescopic framework through the semi-circular arc groove of the upper cladding and the semi-circular arc groove of the lower cladding, and cutting off the aluminum foil cloth outside the upper cladding and the lower cladding after wrapping;

s5, wrapping the inner wall of the telescopic skeleton: and D, performing inner wall wrapping on the telescopic framework of which the outer wall is wrapped with the aluminum foil cloth in the step S4, extending the left end of the second shaft rod into an inner hole of the telescopic framework, and rolling along the inner wall of the telescopic framework through a compression roller on the outer wall of the second shaft rod to wrap the aluminum foil cloth on the inner wall of the telescopic framework.

2. The manufacturing and processing technology of the high-temperature-resistant aluminum foil telescopic air duct according to claim 1, characterized in that: the support frame includes slide opening, slide bar, spring, articulated seat, and the slide opening is seted up in the top middle part of support frame, and articulated seat is installed on the top of each support frame, and articulated seat articulates in the both ends of compressing roller, and the bottom of articulated seat is provided with the slide bar, and the slide bar bottom is embedded in the slide opening of support frame through sliding fit, and the spring mounting is on the outer disc of slide bar of support frame and articulated seat.

3. The manufacturing and processing technology of the high-temperature-resistant aluminum foil telescopic air duct according to claim 1, characterized in that: the compressing roller comprises a abdicating groove, a poking piece and supporting arc pieces, the poking pieces of a plurality of upwarping are arranged on the outer circular surface of the compressing roller at equal intervals, each piece of upwarping poking piece is of a semi-circular arc structure, the poking piece is equal in length to the two ends of the compressing roller, each piece of abdicating groove is formed in the root of each poking piece, the supporting arc pieces fixed in an inclined mode are arranged in the middle of the bottom end of each poking piece, and the bottom end of each supporting arc piece is in sliding contact with the bottom surface of each abdicating groove.

4. The manufacturing and processing technology of the high-temperature-resistant aluminum foil telescopic air duct according to claim 1, characterized in that: a stepped opening is formed in one side of the lower cladding semi-circular groove, a clamping block is installed in the stepped opening of the lower cladding in a sliding fit mode, and the clamping block is spliced and attached through a tension spring.

5. The manufacturing and processing technology of the high-temperature-resistant aluminum foil telescopic air duct according to claim 4, characterized in that: and a cutting edge is arranged at the top end of the semi-arc groove of the lower cladding close to the step opening.

6. The manufacturing and processing technology of the high-temperature-resistant aluminum foil telescopic air duct according to claim 1, characterized in that: the height of the second shaft lever is positioned in the middle of the circular hole formed by splicing the upper cladding and the lower cladding.

7. The manufacturing and processing technology of the high-temperature-resistant aluminum foil telescopic air duct according to claim 2, characterized in that: and an aluminum foil cloth is wound on the outer circular surface of the left end of the second shaft lever and is positioned in the middle of the supporting frames at the two ends.

Technical Field

The invention relates to the technical field of high-temperature-resistant equipment processing, in particular to a manufacturing and processing technology of a high-temperature-resistant aluminum foil telescopic air duct.

Background

The telescopic aluminum foil wind pipe is a Mylar aluminum foil pipeline with the flow rate of 28M/S, is coated with Mylar reinforced aluminum foil, is internally supported by spiral steel wires, Mylar, and is adhered to the upper layer and the lower layer of the steel wires to reinforce the adhesive force and the tensile force, is a hose, has high telescopic bending property, is easy to construct, is used for dust absorption and air exhaust in general, and is used for air extraction and exhaust in bathroom rooms, and has flame retardant performance.

Currently, patent number CN201820974789.4 discloses a flexible tuber pipe machine forming device of aluminium foil, including the frame, be provided with aluminium foil area guide roll and steel wire leading wheel in the frame, still be provided with winding mechanism in the frame, winding mechanism includes the fender dish, the fender dish has actuating mechanism through the hub connection, be provided with the winding body on the fender dish, the outward flange line of winding body is regular polygon shape, still is provided with the indentation wheel in the frame, the indentation wheel is located the winding body and keeps away from fender dish one side outward, the utility model discloses can make the flexible tuber pipe overall structure of aluminium foil after the indentation better and even, no wastrel produces, the later stage compression of being convenient for.

The forming device of the aluminum foil telescopic duct machine disclosed by the patent has some defects in actual production, manufacturing and processing, and the specific defects are as follows:

when the aluminum foil telescopic air pipe is manufactured and processed, the aluminum foil wraps the steel wires easily and is not tight, so that the aluminum foil wraps the outer walls of the steel wires loosely, the aluminum foil wraps the telescopic framework easily and slides, and the use performance of the aluminum foil telescopic air pipe is influenced.

Disclosure of Invention

Aiming at the problems in the prior art, the invention aims to provide a manufacturing and processing technology of a high-temperature-resistant aluminum foil telescopic air pipe, which solves the technical problems that when an aluminum foil telescopic air pipe is manufactured and processed, when an aluminum foil wraps steel wires, the aluminum foil is easy to wrap and not compact, the aluminum foil wraps the outer walls of the steel wires and is not compact, the aluminum foil is easy to wrap on a telescopic framework to slide, and the use performance of the aluminum foil telescopic air pipe is influenced.

The technical problem to be solved by the invention is realized by adopting the following technical scheme: a high-temperature-resistant aluminum foil telescopic air duct manufacturing and processing technology is applied to the manufacturing and processing of telescopic air ducts, and is used for wrapping a telescopic framework in the telescopic air ducts with aluminum foil cloth, the manufacturing and processing technology of the high-temperature-resistant aluminum foil telescopic air duct is completed by matching a high-temperature-resistant aluminum foil telescopic air duct manufacturing and processing device which comprises a base, a supporting plate which is upright at the top end of the base is arranged at the top end of the base, a shaft lever sleeve with a cylindrical structure is arranged on the left side of the top end of the supporting plate, a through shaft hole is formed in the axial position of the shaft lever sleeve, a shaft lever is arranged in the shaft hole of the shaft lever sleeve in a sliding fit mode, a coupler is arranged at the top end of the shaft lever arranged in the shaft hole, a servo motor is fixedly arranged on the right side of the, a cylindrical roller is arranged at the left end of the shaft lever, and a plurality of circles of aluminum foil cloth are wound on the outer circumferential surface of the roller;

the top end of the base is provided with a square block-shaped lower cladding base, the top end of the lower cladding base is fixedly provided with a tile-shaped lower cladding, the top end of the lower cladding is provided with a semi-arc groove with an upward opening, the bottom end of the lower cladding is fixed on the lower cladding base, the top end of the lower cladding base is hinged with a tile-shaped upper cladding, the top end of the upper cladding is provided with a semi-arc groove, the semi-arc groove of the upper cladding and the semi-arc groove of the lower cladding are spliced into a through round hole, and the semi-arc groove of the lower cladding is arranged at the sagging position of the top end of the aluminum;

the outer wall of the upper cladding is provided with a hinged support, the top end of the base of the lower cladding behind the lower cladding is hinged with a hydraulic rod, and the top end of the hydraulic rod is hinged and fixed on the hinged support;

the top end of the base is provided with a support rib plate standing upright at the top end of the base, the middle part of the support rib plate is provided with a square block-shaped sliding hole, a square rod-shaped sliding block is embedded in the sliding hole of the support rib plate in a sliding fit mode, the bottom end of the sliding block is provided with a rack, the side wall of the support rib plate close to the rack is fixedly provided with a third servo motor, an output shaft extends out of the third servo motor, the top end of the output shaft of the third servo motor is fixedly provided with a driving gear, and the driving gear is connected with a rack meshing strip at the bottom end of the sliding block;

the middle part of the sliding block is provided with a through shaft hole, a second shaft lever is arranged in the middle shaft hole of the sliding block through a bearing, the right end of the second shaft lever extends out of the right end of the sliding block, a second gear is arranged at the top end of the second shaft lever extending out of the right end of the sliding block, a second servo motor is fixedly arranged at the right end of the sliding block, the second servo motor is fixedly arranged on the sliding block through a motor fixing frame, a first gear is arranged at the top end of an output shaft of the second servo motor, and the first gear is meshed with the second gear;

a compression roller with a cylindrical structure is arranged on the outer wall of the left end of the second shaft lever, two ends of the compression roller are symmetrically hinged to the supporting frames, and the bottoms of the supporting frames at the two ends of the compression roller are symmetrically fixed on the outer circular surface of the second shaft lever;

the manufacturing and processing technology of the high-temperature-resistant aluminum foil telescopic air duct specifically comprises the following steps:

s1, mounting aluminum foil cloth: winding the aluminum foil cloth on the outer circular surface of the roller;

s2, placing aluminum foil cloth: the roller is driven to rotate by the servo motor, and the drooping top end of the aluminum foil cloth is placed in the semicircular groove of the lower cladding;

s3, placing an expansion framework: placing a telescopic framework in the semi-arc groove of the lower cladding in which the aluminum foil cloth is placed in the step S2, and horizontally placing the telescopic framework in the semi-arc groove of the lower cladding to press the aluminum foil cloth placed in the semi-arc groove below the telescopic framework;

s4, wrapping the outer wall of the telescopic skeleton: wrapping the outer wall of the telescopic framework placed in the semi-circular arc groove of the lower cladding in the step S3 with aluminum foil cloth, buckling the upper cladding with the lower cladding, wrapping the aluminum foil cloth along the outer wall of the telescopic framework through the semi-circular arc groove of the upper cladding and the semi-circular arc groove of the lower cladding, and cutting off the aluminum foil cloth outside the upper cladding and the lower cladding after wrapping;

s5, wrapping the inner wall of the telescopic skeleton: and D, performing inner wall wrapping on the telescopic framework of which the outer wall is wrapped with the aluminum foil cloth in the step S4, extending the left end of the second shaft rod into an inner hole of the telescopic framework, and rolling along the inner wall of the telescopic framework through a compression roller on the outer wall of the second shaft rod to wrap the aluminum foil cloth on the inner wall of the telescopic framework.

According to a preferable technical scheme, the support frame comprises sliding holes, sliding rods, springs and hinge seats, the sliding holes are formed in the middle of the top end of the support frame, the hinge seats are mounted at the top end of each support frame and are hinged to two ends of the pressing roller, the sliding rods are arranged at the bottom ends of the hinge seats, the bottom ends of the sliding rods are embedded into the sliding holes of the support frame in a sliding fit mode, and the springs are mounted on the outer circular surfaces of the sliding rods of the support frame and the hinge seats.

As a preferred technical scheme of the invention, the compression roller comprises a abdicating groove, a poking sheet and a supporting arc sheet, wherein a plurality of tilted poking sheets are arranged on the outer circumferential surface of the compression roller at equal intervals, each tilted poking sheet is of a semi-circular arc structure, the poking sheets are as long as the two ends of the compression roller, the abdicating groove is formed in the root of each poking sheet, the supporting arc sheet is obliquely fixed and arranged in the middle of the bottom end of each poking sheet, and the bottom end of the supporting arc sheet is in sliding contact with the bottom surface of the abdicating groove.

As a preferred technical scheme of the invention, one side of the semicircular groove of the lower cladding is provided with a stepped opening, a clamping block is arranged in the stepped opening of the lower cladding in a sliding fit mode, and the clamping block is spliced and attached through a tension spring.

As a preferable technical scheme of the invention, a cutting edge is arranged at the top end of the semi-arc groove of the lower cladding close to the position of the stepped port.

As a preferable technical scheme of the invention, the height of the second shaft lever is positioned in the middle of the circular hole for splicing the upper cladding and the lower cladding.

As a preferable technical scheme of the invention, the outer circle surface of the left end of the second shaft lever is wound with aluminum foil cloth, and the aluminum foil cloth is positioned in the middle of the supporting frames at the two ends.

Compared with the prior art, the invention at least comprises the following beneficial effects:

the manufacturing and processing device for the high-temperature-resistant aluminum foil telescopic air duct comprises a roller arranged on a supporting plate at the top end of a base, wherein a plurality of circles of aluminum foil cloth are wound on the outer circumferential surface of the roller and are driven by a servo motor to be wound and put down, a lower semi-arc-groove-shaped jacket is arranged at the sagging position of the top end of the aluminum foil cloth, so that the aluminum foil cloth falls into the semi-arc groove of the lower jacket when the aluminum foil cloth is rewound, the telescopic framework is conveniently placed in the semi-arc groove of the lower jacket by manpower, the aluminum foil cloth is wrapped on the outer wall of the telescopic framework, the wrapping tightness of the aluminum foil cloth on the telescopic framework is improved, the upper jacket and the lower jacket are buckled, the semi-arc groove of the upper jacket and the semi-arc groove of the lower jacket are spliced into a through circular hole to tightly hold the telescopic framework, the aluminum foil cloth placed in the semi-arc groove of the lower jacket, the wrapping tightness of the telescopic framework is improved.

Secondly, the invention is provided with a supporting ribbed plate standing on the top end of the base, a square rod-shaped sliding block is arranged in a sliding hole at the top end of the supporting ribbed plate in a sliding fit mode, a second shaft rod is arranged in a shaft hole of the sliding block through a bearing, so that the second shaft rod extends into an inner ring of a telescopic framework to rotate, the left end of the second shaft rod extending into the inner ring of the telescopic framework is provided with a pressing roller, the axial length of the pressing roller is greater than that of the telescopic framework, an aluminum foil cloth is arranged at the left end of the second shaft rod, the top end of the aluminum foil cloth is wound on the inner wall of the telescopic bone clamp through the pressing roller in a laminating mode to adhere the aluminum foil cloth on the inner wall of the telescopic framework, the sliding block is driven by a second servo motor to move at a constant speed, so that the top end of the aluminum foil cloth is wound on the inner wall of the telescopic bone, the wrapping tightness of the aluminum foil cloth on the inner wall of the telescopic framework is improved, the aluminum foil cloth bonded on the inner wall of the telescopic framework is attached to the aluminum foil cloth wrapped on the outer wall of the telescopic framework, the winding tightness of the aluminum foil cloth is improved, the wrapping of the two layers of aluminum foil cloth further effectively improves the tightness of the surface of the aluminum foil telescopic air pipe, the problem that the middle of the pipeline is not wrapped tightly and air leakage occurs is avoided, and the practicability of the telescopic air pipe is improved.

Third, a stepped opening is formed in one side of the semicircular groove of the lower cladding, a clamping block is installed in the stepped opening of the lower cladding in a sliding fit mode, the clamping block is spliced and attached through a tension spring, the clamping block can slide on the right side of the stepped opening and clamp and fix the top end of the aluminum foil cloth, when the upper cladding and the lower cladding are buckled, upward sliding of the bottom end of the aluminum foil cloth is avoided, the outer wall of the telescopic framework is not tightly wrapped, a cutting edge is arranged at the top end of the semicircular groove of the lower cladding close to the stepped opening, after the upper cladding and the lower cladding are buckled, mechanical automatic cutting is conducted through the cutting edge after the outer wall of the telescopic framework is tightly wrapped, and the corners of the aluminum foil cloth wrapped on the outer wall of the telescopic framework are smooth. The attractiveness of the package is improved.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a process flow diagram of the manufacturing process of the high temperature resistant aluminum foil telescopic air duct of the present invention;

FIG. 2 is a front view of the manufacturing and processing device for the high temperature resistant aluminum foil telescopic air duct of the present invention;

FIG. 3 is a left side view of the upper cladding of the present invention open at the top end of the lower cladding;

FIG. 4 is a left side view of the present invention with the upper and lower enclosures snapped together;

FIG. 5 is a schematic view of the second shaft of the present invention extending into the telescoping mast;

FIG. 6 is a schematic structural view of the present invention in which the pinch roller wraps the aluminum foil cloth on the inner wall of the telescopic frame;

FIG. 7 is a schematic structural view of a pressure roller of the present invention;

FIG. 8 is an enlarged view of the structure in the direction A of FIG. 3;

FIG. 9 is an enlarged view of a portion of the structure shown in FIG. 4 in the direction B according to the present invention;

in the figure: 1. the device comprises a base, 2, a supporting plate, 3, a servo motor, 4, a shaft rod sleeve, 5, a coupler, 6, a shaft rod, 7, a roller, 8, aluminum foil cloth, 9, an upper shell, 10, a lower shell, 101, a blade, 102, a clamping block, 103, a tension spring, 11, a second shaft rod, 12, a supporting rib plate, 13, a first gear, 14, a motor fixing frame, 15, a second servo motor, 16, a second gear, 17, a sliding block, 18, a rack, 19, a driving gear, 20, a hydraulic rod, 21, a hinged support, 22, a lower shell base, 23, a supporting frame, 2301, a sliding hole, 2302, a sliding rod, 2303, a spring, 2304, a hinged support, 24, a pressing roller, 2401, a abdicating groove, 2402, a shifting sheet, 2403 and a supporting arc sheet.

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways as defined and covered by the claims.

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further explained below by combining the specific drawings.

It will be understood that when an element is referred to as being "secured to" another element, it can be on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and similar expressions are used herein for illustrative purposes only and do not represent the only embodiments.

Please refer to fig. 1-9, which are schematic diagrams of the overall structure of a manufacturing process of a high temperature resistant aluminum foil telescopic air duct;

a high temperature resistant aluminum foil telescopic air duct manufacturing and processing technology is applied to the manufacturing and processing of a telescopic air duct, a telescopic framework in the telescopic air duct is wrapped by aluminum foil cloth, the manufacturing and processing technology of the high temperature resistant aluminum foil telescopic air duct is completed by adopting a high temperature resistant aluminum foil telescopic air duct manufacturing and processing device in a matching way, the high temperature resistant aluminum foil telescopic air duct manufacturing and processing device comprises a base 1, the base 1 is horizontally fixed on the ground, a supporting plate 2 which is upright on the top end of the base 1 is arranged on the top end of the base 1, a shaft lever sleeve 4 with a cylindrical structure is arranged on the left side of the top end of the supporting plate 2, a through shaft hole is formed in the axis position of the shaft lever sleeve 4, a shaft lever 6 is arranged in the shaft hole in a sliding matching way, a coupler 5 is arranged on the top end of the shaft lever 6 arranged in the, the top end of an output shaft of the servo motor 3 extends into a shaft hole of the shaft lever sleeve 4, the top end of the output shaft of the servo motor 3 is fixedly connected with a shaft lever 6 through a coupler 5, a cylindrical roller 7 is arranged at the left end of the shaft lever 6, and a plurality of circles of aluminum foil cloth 8 are wound on the outer circular surface of the roller 7;

the top end of the base 1 is provided with a square block-shaped lower cladding base 22, the top end of the lower cladding base 22 is fixedly provided with a tile-shaped lower cladding 10, the top end of the lower cladding 10 is provided with a semi-arc groove with an upward opening, the bottom end of the lower cladding 10 is fixed on the lower cladding base 22, the top end of the lower cladding base 22 is hinged with a tile-shaped upper cladding 9, the top end of the upper cladding 9 is provided with a semi-arc groove, the semi-arc groove of the upper cladding 9 and the semi-arc groove of the lower cladding 10 are spliced into a through round hole, and the semi-arc groove of the lower cladding 10 is arranged at the sagging position;

wherein, the manufacturing and processing device of the high temperature resistant aluminum foil telescopic air duct comprises a roller 7 arranged on a supporting plate 2 at the top end of a base 1, a plurality of circles of aluminum foil cloth 8 are wound on the outer circle surface of the roller 7, the aluminum foil cloth 8 is wound and put down by being driven by a servo motor 3, a lower casing 10 in the shape of a semi-arc groove is arranged at the drooping position of the top end of the aluminum foil cloth 8, when the aluminum foil cloth 8 is rewound, the aluminum foil cloth 8 falls into the semi-arc groove of the lower casing 10, so that when the telescopic framework is manually placed in the semi-arc groove of the lower casing 10, the aluminum foil cloth 8 is wrapped on the outer wall of the telescopic framework, the wrapping tightness of the aluminum foil cloth 8 on the telescopic framework is improved, the upper casing 9 is buckled with the lower casing 10, the semi-arc groove of the upper casing 9 is spliced with the semi-arc groove of the lower casing 10 into a through round hole to tightly hold the telescopic framework, so, the outer circle surface of the telescopic framework is tightly wrapped, and the wrapping tightness of the telescopic framework is improved.

The outer wall of the upper cladding 9 is provided with a hinged support 21, the top end of a lower cladding base 22 positioned behind the lower cladding 10 is hinged with a hydraulic rod 20, and the top end of the hydraulic rod 20 is hinged and fixed on the hinged support 21; the upper cladding 9 is pushed by the hydraulic rod 20 to be buckled conveniently, and the operation simplicity is improved.

The top end of the base 1 is provided with a supporting rib plate 12 standing on the top end of the base 1, the middle part of the supporting rib plate 12 is provided with a square block-shaped sliding hole, a square rod-shaped sliding block 17 is embedded in the sliding hole of the supporting rib plate 12 in a sliding fit mode, the bottom end of the sliding block 17 is provided with a rack 18, the side wall of the supporting rib plate 2 close to the position of the rack 18 is fixedly provided with a third servo motor, an output shaft extends out of the third servo motor, the top end of the output shaft of the third servo motor is fixedly provided with a driving gear 19, and the driving gear 19 is connected with the rack 18 at;

a through shaft hole is formed in the middle of the sliding block 17, a second shaft rod 11 is mounted in the shaft hole in the middle of the sliding block 17 through a bearing, the right end of the second shaft rod 11 extends out to the right end of the sliding block 17, a second gear 16 is mounted at the top end of the second shaft rod 11 extending out of the right end of the sliding block 17, a second servo motor 15 is fixedly mounted at the right end of the sliding block 17, the second servo motor 15 is fixedly mounted on the sliding block 17 through a motor fixing frame 14, an output shaft extends out of the second servo motor 15, a first gear 13 is mounted at the top end of the output shaft of the second servo motor 15, and the first gear 13 is;

wherein, through the rotation of third servo motor drive gear 19, drive slider 17 and axially slide in the slide opening of support rib plate 12, make the axial constant velocity motion of second shaft lever 11 that stretches into in the telescopic frame, drive second gear 16 through No. two servo motor 15 and rotate, drive the constant velocity rotation of second shaft lever 11 that stretches into in the telescopic frame, through the constant velocity motion of the axial constant velocity motion of second shaft lever 11 cooperation second shaft lever 11, make compressing roller 24 with the spiral winding of aluminium foil along the inner wall of telescopic frame, improve the winding tightness of aluminium foil.

The left end of a second shaft lever 11 extends into an inner ring of the telescopic framework, the height of the second shaft lever 11 is positioned in the middle of a circular hole formed by splicing an upper cladding 9 and a lower cladding 10, an aluminum foil cloth 8 is wound on the outer circular surface of the left end of the second shaft lever 11, the aluminum foil cloth 8 is positioned in the middle of support frames 23 at two ends, a pressing roller 24 with a cylindrical structure is arranged on the outer wall of the left end of the second shaft lever 11, the axial length of the pressing roller 24 is greater than that of the telescopic framework, two ends of the pressing roller 24 are symmetrically hinged on the support frames 23, and the bottoms of the support frames 23 at two ends of the pressing roller 24 are symmetrically fixed on the; the bottom of the support frame 23 at the two ends of the pressing roller 24 is positioned on the outer wall of the second shaft lever 11 and is wound with the aluminum foil cloth 8, and the top end of the aluminum foil cloth 8 is wound on the inner wall of the telescopic framework by the pressing roller 24 through pulling the top end of the aluminum foil cloth 8.

Wherein, the invention is provided with a supporting ribbed plate 12 standing on the top of the base 1, a square rod shaped slide block 17 is arranged in a slide hole 2301 on the top of the supporting ribbed plate 12 in a sliding fit mode, a second shaft lever 11 is arranged in a shaft hole of the slide block 17 through a bearing, so that the second shaft lever 11 extends into an inner ring of a telescopic skeleton to be rotated, a pressing roller 24 is arranged at the left end of the second shaft lever 11 extending into the inner ring of the telescopic skeleton, the axial length of the pressing roller 24 is larger than that of the telescopic skeleton, an aluminum foil cloth 8 is arranged at the left end of the second shaft lever 11, the top end of the aluminum foil cloth 8 rotates on the inner wall of the telescopic skeleton through the pressing roller 24, so that the aluminum foil cloth 8 is bonded on the inner wall of the telescopic skeleton, the slide block 17 is driven by a second servo motor 15 to move at a constant speed, so that the top end of the aluminum foil cloth, make 8 layers of aluminium foil cloth of winding on flexible skeleton inner wall fold and press, improve the parcel of aluminium foil cloth 8 on flexible skeleton inner wall tight, bond aluminium foil cloth 8 on flexible skeleton inner wall and the laminating of the aluminium foil cloth 8 of parcel on flexible skeleton outer wall, improve the winding fastening nature of aluminium foil cloth 8, through the parcel of two-layer aluminium foil cloth 8, further effectively improve the leakproofness on this aluminium foil flexible tuber pipe surface, avoid the pipeline middle part not to wrap up tightly and leak out, improve the practicality of this flexible tuber pipe.

The manufacturing and processing technology of the high-temperature-resistant aluminum foil telescopic air duct specifically comprises the following steps:

s1, mounting aluminum foil cloth: winding the aluminum foil cloth on the outer circular surface of the roller 7;

s2, placing aluminum foil cloth: the roller 7 is driven to rotate by the servo motor 3, and the drooping top end of the aluminum foil cloth 8 is placed in the semicircular groove of the lower cladding 10;

s3, placing an expansion framework: placing a telescopic skeleton in the semi-circular groove of the lower cladding 10 in which the aluminum foil cloth 8 is placed in the step S2, and horizontally placing the telescopic skeleton in the semi-circular groove of the lower cladding 10 to enable the aluminum foil cloth placed in the semi-circular groove to be pressed below the telescopic skeleton;

s4, wrapping the outer wall of the telescopic skeleton: wrapping the outer wall of the telescopic framework placed in the semi-circular groove of the lower cladding 10 in the step S3 with aluminum foil cloth, buckling the upper cladding 9 and the lower cladding 10, wrapping the aluminum foil cloth 8 along the outer wall of the telescopic framework through the semi-circular groove of the upper cladding 9 and the semi-circular groove of the lower cladding 10, and cutting off the aluminum foil cloth outside the upper cladding 9 and the lower cladding 10 after wrapping;

s5, wrapping the inner wall of the telescopic skeleton: and (4) carrying out inner wall wrapping on the telescopic framework of which the outer wall is wrapped with the aluminum foil cloth 8 in the step S4, extending into an inner hole of the telescopic framework through the left end of the second shaft rod 11, rolling along the inner wall of the telescopic framework through the compression roller 24 on the outer wall of the second shaft rod 11, wrapping the aluminum foil cloth 8 on the inner wall of the telescopic framework, opening the upper wrapping shell 9 after completion, taking out the telescopic framework of which the inner wall and the outer wall are all wrapped with the aluminum foil cloth 8, and finishing the manufacturing and processing of the aluminum foil telescopic air pipe.

The support frame 23 comprises slide holes 2301, slide rods 2302, springs 2303 and hinged seats 2304, the slide holes 2301 are opened in the middle of the top end of the support frame 23, the hinged seats 2304 are installed at the top end of each support frame 23, the hinged seats 2304 are hinged at two ends of the pressing roller 24, the slide rods 2302 are arranged at the bottom ends of the hinged seats 2304, the bottom ends of the slide rods 2302 are embedded in the slide holes 2301 of the support frame 23 in a sliding fit mode, and the springs 2303 are installed on the outer circular surfaces of the slide rods 2302 of the support frame 2303 and the hinged seats 2304.

The pressing roller 24 comprises a abdicating groove 2401, poking pieces 2402 and supporting arc pieces 2403, the poking pieces 2402 of a plurality of tilting are arranged on the outer circular surface of the pressing roller 24 at equal intervals, each tilted poking piece 2402 is of a semi-circular arc structure, the poking pieces 2402 are equal in length to the two ends of the pressing roller 24, the abdicating groove 2401 is formed in the root of each poking piece 2402, the supporting arc pieces 2403 fixed in an inclined mode are arranged in the middle of the bottom end of each poking piece 2402, and the bottom ends of the supporting arc pieces 2403 are in sliding contact with the bottom surface of the abdicating groove 2401.

Wherein, the support frame 23 of the invention is elastically stretched by the spring 2303, so that the support frame 23 is automatically adjusted on the inner wall of the telescopic framework according to the inner diameter of the telescopic framework, the pressing roller 24 is in close contact with the inner wall of the telescopic framework, a plurality of tilted poking sheets 2402 are arranged on the outer circular surface of the pressing roller 24 at equal intervals, each tilted poking sheet 2402 is in a semi-circular arc structure, the bottom end of the poking sheet 2402 is supported by the supporting arc sheet 2403, the two ends of each tilted poking sheet 2402 are equal in length to the two ends of the pressing roller 24, when the top end of the aluminum foil cloth 8 extends into the inner ring of the telescopic framework, the aluminum foil cloth 8 arranged on the second shaft rod 11 is pulled out in advance and fixed on the tilted poking sheet 2402 of the pressing wheel, when the pressing wheel is in contact with the inner wall of the telescopic framework, the tilted poking sheets 2402 have certain resilience, so that when the aluminum foil cloth 8 is attached to the inner wall of the, through the elastic pressing of plectrum 2402, it is inseparabler to laminate aluminium foil cloth 8 with the inner wall of flexible skeleton, and it is inseparabler to be favorable to the pinch roller to laminate aluminium foil cloth 8 when following the inner wall spiral winding of flexible skeleton.

The bottom end of the supporting arc 2403 is slidably connected with the bottom surface of the abdicating groove 2401, so that the bottom end of the supporting arc 2403 can slide on the bottom surface of the abdicating groove 2406, the supporting arc 2403 has a certain tension by the arc bending of the supporting arc 2403, and the pulling piece 2402 has a certain elastic force by the tension of the supporting arc 2403.

One side of the semicircular groove of the lower cladding 10 is provided with a stepped opening, a clamping block 102 is installed in the stepped opening of the lower cladding 10 in a sliding fit mode, the clamping block 102 is spliced and attached through a tension spring 103, and a cutting edge 101 is arranged at the top end of the semicircular groove of the lower cladding 10 close to the position of the stepped opening.

According to the invention, a stepped opening is formed in one side of the semicircular groove of the lower cladding 10, the clamping block 102 is installed in the stepped opening of the lower cladding 10 in a sliding fit mode, the clamping block 102 is spliced and attached through the tension spring 103, so that the clamping block 102 can slide on the right side of the stepped opening and clamp and fix the top end of the aluminum foil cloth 8, when the upper cladding 9 is buckled with the lower cladding 10, the upward sliding of the bottom end of the aluminum foil cloth 8 is avoided, the outer wall of the telescopic framework is not tightly wrapped, the top end of the semicircular groove of the lower cladding 10 close to the stepped opening is provided with the cutting edge 101, after the upper cladding 9 is buckled with the lower cladding 10, the outer wall of the telescopic framework is tightly wrapped, mechanical automatic cutting is carried out through the cutting edge 101, and the corners of the aluminum foil cloth 8 wrapped on the outer wall of the telescopic. The attractiveness of the package is improved.

Wherein, because the aluminium foil cloth 8 can be cut off and a part of the aluminium foil cloth 8 is added when the clamping block 102 clamps the bottom end of the aluminium foil cloth 8, the part of the aluminium foil cloth 8 added adds the space occupied by the clamping block 102, so that the aluminium foil cloth 8 is tightly wrapped.

The working principle is as follows: when the manufacturing and processing device of the high-temperature resistant aluminum foil telescopic air duct is matched, firstly, aluminum foil cloth is wound on the outer circular surface of the roller 7; the roller 7 is driven to rotate by the servo motor 3, and the drooping top end of the aluminum foil cloth 8 is placed in the semicircular groove of the lower cladding 10; secondly, placing a telescopic framework in the semi-circular groove of the lower cladding 10 with the aluminum foil cloth 8, and horizontally placing the telescopic framework in the semi-circular groove of the lower cladding 10 to enable the telescopic framework to be coaxial with the semi-circular groove of the lower cladding 10; then, wrapping the outer wall of the telescopic framework placed in the semi-circular arc groove of the lower cladding 10 with aluminum foil cloth, buckling the upper cladding 9 with the lower cladding 10, wrapping the aluminum foil cloth 8 along the outer wall of the telescopic framework through the semi-circular arc groove of the upper cladding 9 and the semi-circular arc groove of the lower cladding 10, and cutting off the aluminum foil cloth outside the upper cladding 9 and the lower cladding 10 after wrapping; finally, the telescopic framework with the outer wall wrapped by the aluminum foil cloth 8 is wrapped by the inner wall, the left end of the second shaft rod 11 extends into an inner hole of the telescopic framework, and the pressing roller 24 on the outer wall of the second shaft rod 11 rolls along the inner wall of the telescopic framework to wrap the aluminum foil cloth 8 on the inner wall of the telescopic framework.

In addition, the working process of winding the inner wall and the outer wall of the telescopic framework is as follows:

the manufacturing and processing device of the high-temperature resistant aluminum foil telescopic air duct comprises a roller 7 arranged on a supporting plate 2 at the top end of a base 1, a plurality of circles of aluminum foil cloth 8 are wound on the outer circumferential surface of the roller 7, the aluminum foil cloth 8 is driven by a servo motor 3 to be wound and put down, a lower semi-arc groove-shaped jacket 10 is arranged at the top end of the aluminum foil cloth 8, when the aluminum foil cloth 8 is rewound, the aluminum foil cloth 8 falls into the semi-arc groove of the lower jacket 10, the bottom end of the aluminum foil cloth 8 is clamped and fixed by a clamping block 102, when the telescopic framework is manually placed in the semi-arc groove of the lower jacket 10, the aluminum foil cloth 8 is wrapped on the outer wall of the telescopic framework, the aluminum foil wrapping tightness of the aluminum foil cloth 8 on the telescopic framework is improved, the telescopic framework is tightly wrapped by the upper jacket 9 and the lower jacket 10, the semi-arc groove of the upper jacket 9 and the semi-arc groove of the lower jacket 10 are spliced into a through round hole to tightly hold, a stepped opening is formed in one side of the semicircular groove of the lower cladding 10, a cutting edge 101 is arranged at the top end of the semicircular groove of the lower cladding 10 close to the position of the stepped opening, so that after the upper cladding 9 and the lower cladding 10 are buckled, the outer wall of the telescopic framework is wrapped tightly and then is mechanically and automatically cut through the cutting edge 101, and the corners of the aluminum foil cloth 8 wrapped on the outer wall of the telescopic framework are smooth.

The left end of the second shaft lever 11 extends into the inner ring of the telescopic framework to rotate, the left end of the second shaft lever 11 extending into the inner ring of the telescopic framework is provided with a pressing roller 24, the shaft length of the pressing roller 24 is greater than that of the telescopic framework, a third servo motor drives a gear 19 to rotate, a sliding block 17 is driven to axially slide in a sliding hole of a support rib plate 12, so that the second shaft lever 11 extending into the telescopic framework axially moves at a constant speed, a second gear 16 is driven to rotate through a second servo motor 15, the second shaft lever 11 extending into the telescopic framework is driven to rotate at a constant speed, the second shaft lever 11 axially moves at a constant speed to be matched with the constant speed rotation of the second shaft lever 11, the aluminum foil cloth 8 is arranged at the left end of the second shaft lever 11, the top end of the aluminum foil cloth 8 is rotationally wound on the inner wall of the telescopic bone clamp through the pressing roller 24, the pressing roller 24 elastically stretches through a support frame 23, so that the support, the automatic adjustment is carried out according to the inner diameter of the telescopic framework, so that the compression roller 24 is in close contact with the inner wall of the telescopic framework.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are given by way of illustration of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.