CN114273880A

CN114273880A - Thermal-insulated bridge cut-off aluminum alloy strip penetrating machine

Info

Publication number: CN114273880A
Application number: CN202111531210.XA
Authority: CN
Inventors: 罗铭强; 黄和銮; 马得胜; 李美玉; 聂德键; 易鹏
Original assignee: Guangdong Xingfa Aluminium Jiangxi Co ltd
Current assignee: Guangdong Xingfa Aluminium Jiangxi Co ltd
Priority date: 2021-12-15
Filing date: 2021-12-15
Publication date: 2022-04-05
Anticipated expiration: 2041-12-15
Also published as: CN114273880B

Abstract

The invention discloses a heat-insulation bridge-cutoff aluminum alloy threading machine which comprises a bottom plate and a threading unit; the front end of the upper side of the bottom plate is provided with a workbench, the rear end of the upper side of the bottom plate is provided with a conveyor belt, and the middle part of the upper side of the bottom plate is provided with a fixing unit; wear a unit and include spout one, the slider, the bracing piece, the axis of rotation, the processing running roller, square sand grip, square groove and power component, the cooperation relative rotation between two processing running rollers that correspond about the same end, the right-hand member of two axis of rotation of left end is provided with a square sand grip respectively, the cooperation relative rotation effect between two processing running rollers down realizes the driven effect to the aluminum alloy, drive two sliders along left right direction relative slip about the inside of spout one between both ends under power component's effect, two processing running rollers that correspond about both ends about the relative slip drives through two sliders are along left right direction relative slip, thereby realize the driven effect to the aluminum alloy of different specifications.

Description

Thermal-insulated bridge cut-off aluminum alloy strip penetrating machine

Technical Field

The invention relates to the technical field of aluminum alloy threading machines, in particular to a heat-insulation bridge-cutoff aluminum alloy threading machine.

Background

The aluminum alloy is metal, the heat conduction is relatively fast, when the indoor and outdoor temperature difference is very much, the aluminum alloy can become a bridge for transferring heat, the heat insulation performance is not good, therefore, the traditional aluminum alloy section is gradually used in the home decoration market, along with the rapid development of heat insulation doors, windows and curtain walls, the aluminum alloy heat insulation section is widely applied, the strip penetrating type heat insulation section is a mainstream product, the existing heat insulation bridge-cut aluminum alloy usually adopts manual strip penetrating or mechanical strip penetrating, the manual strip penetrating efficiency is low, labor and time are wasted, the labor intensity is high, the mechanical strip penetrating efficiency is improved compared with the manual strip penetrating efficiency, but the strip penetrating adopts fixed-length heat insulation strips or wire rods, the heat insulation strips are required to be manually cut when the strip penetrating is finished, the working efficiency of workers is reduced, and the cutting openings of the heat insulation strips are not neat.

Application number is CN208681419U provides a thermal-insulated bridge cut-off aluminum alloy threading machine among the prior art, including the frame and pass through the control box of bolt fastening in frame one side, be provided with cutting device in the frame, the welding of frame top has the workstation, just cutting device is located the workstation below, the workstation has the portal frame through the bolt fastening, be provided with the threading device on the portal frame, be provided with spacing strutting arrangement on the workstation, this spacing strutting arrangement is located the below of portal frame, cut groove has still been seted up on the workstation.

In the prior art, although the strip penetrating machine for the heat-insulation bridge-cutoff aluminum alloy has the good effect of penetrating the aluminum alloy, the strip penetrating machine can only penetrate the aluminum alloy with the same specification due to the fixed structure of the strip penetrating machine, and only can replace another strip penetrating machine for the aluminum alloys with different specifications, so that the working efficiency is influenced.

Disclosure of Invention

The invention aims to overcome the technical problem of the prior art, and provides a heat-insulation bridge-cut-off aluminum alloy threading machine, which realizes the transmission effect on aluminum alloy under the matching relative rotation effect between two processing rollers, drives two sliding blocks to relatively slide along the left and right directions between the left and right ends in a sliding chute I under the effect of a power assembly, and drives the two processing rollers corresponding to the left and right ends up and down to relatively slide along the left and right directions through the relative sliding of the two sliding blocks, so that the transmission effect on aluminum alloys with different specifications is realized, and the problems in the background technology can be effectively solved.

In order to achieve the purpose, the invention provides the following technical scheme: a heat-insulating bridge-cutoff aluminum alloy threading machine comprises a bottom plate and a threading unit.

A bottom plate: a workbench is arranged at the front end of the upper side of the bottom plate, a conveyor belt is arranged at the rear end of the upper side of the bottom plate, and a fixing unit is arranged in the middle of the upper side of the bottom plate;

a threading unit: comprises a first sliding groove, sliding blocks, supporting rods, rotating shafts, processing rollers, square raised lines, square grooves and a power assembly, wherein the first sliding groove is formed in the middle of the upper side of a bottom plate along the left-right direction, the left end and the right end of the inside of the first sliding groove are respectively connected with one sliding block in a sliding manner, the upper ends of the two sliding blocks are respectively provided with one supporting rod, the inner sides of the two supporting rods are respectively connected with two rotating shafts in a rotating manner, the end side surfaces of the four rotating shafts are respectively and fixedly connected with one processing roller, the two processing rollers which correspond to the upper end and the lower end of the four rotating shafts up and down are matched and relatively rotated, the right end of the two rotating shafts at the left end is respectively provided with one square raised line, the outer sides of the square raised lines which correspond to the left and right are connected with the inner side surfaces of the square grooves in a sliding manner, the power assembly is arranged on the right side of the supporting rod at the right end, the left end of the power assembly is fixedly connected with the right end of the rotating shaft at the right end.

Fix the one end of nylon strip under the fixed action of fixed unit, sliding connection's between the outside of the square sand grip that corresponds about and the inside side of square groove under the effect, form an axle between two axis of rotation that correspond about making, under the cooperation relative rotation effect between two processing running rollers that correspond about with the end, realize the driven effect to the aluminum alloy, drive two sliders along left right direction relative slip about the inside of spout one between both ends under power component's effect, two processing running rollers that correspond about both ends about the relative slip drives through two sliders are along left right direction relative slip, thereby realize the driven effect to the aluminum alloy of different specifications.

Further, power component includes loose axle one, screw thread one and disc one, the both ends side rotates between the inside left and right sides of spout one respectively about the loose axle one, threaded connection between the middle part through a screw thread one and a slider respectively is connected to both ends side about the loose axle one, disc one sets up the left end at the loose axle one.

The first disc is rotated under the action of external force, the first movable shaft is driven to move through the rotation of the first disc, the side faces of the left end and the right end of the first movable shaft are respectively connected with the middle of one sliding block through a first thread, and the two sliding blocks are driven to relatively slide between the left end and the right end of the inside of the first sliding groove along the left-right direction through the movement of the first movable shaft.

Further, power component still includes gear and support frame one, support frame one sets up the right side at the right-hand member bracing piece, the gear is provided with two, and two gears set up the right-hand member side at two axis of rotation of right-hand member respectively, and the meshing is connected between two gears.

Under the meshing connection effect between two gears, the rotation of one gear drives the rotation of the other gear, and the relative rotation between the two gears drives the matching relative rotation between the two processing rollers which are up-down corresponding.

Further, power component still includes arc fixed block and motor, the motor passes through arc fixed block fixed connection on the right side of support frame one, fixed connection between the output shaft of motor and the right-hand member of a axis of rotation of right-hand member, the input of motor is connected through the output electricity of external control switch and external power source.

The output shaft of the motor is driven to rotate under the action of an external power supply, the rotation of the output shaft of the motor drives the rotation of a rotating shaft, and the rotation of a rotating shaft drives the rotation of a gear.

Further, fixed unit includes support frame two, electric telescopic handle and fixed block, the upside of bottom plate is provided with a support frame two along left right direction, support frame two sets up the rear side at the bracing piece, the inside upside of support frame two is provided with an electric telescopic handle, the fixed block is provided with two, and a fixed block setting is at the upside of bottom plate, and another fixed block setting is at electric telescopic handle's lower extreme, and the cooperation is connected between the inboard of two fixed blocks.

Under the supporting action of the second supporting frame, the electric telescopic rod drives the fixing block to slide up and down, and under the matching and connecting action between the inner sides of the two fixing blocks, the fixing action on one end of the nylon strip is realized.

Further, fixed unit still includes the arc draw-in groove, two have been seted up to the arc draw-in groove, and two arc draw-in grooves are seted up in the inboard of two fixed blocks along the fore-and-aft direction respectively, and under the effect of arc draw-in groove, the cooperation between the inboard of making two fixed blocks and the one end of nylon strip is connected more stably.

Further, the positioning unit comprises a first round hole, a positioning rod and a second round hole, the first round hole is uniformly formed in the left end of the first round disc along the circumferential direction, the positioning rod is slidably connected inside the first round hole, the second round hole is formed in the left side of the bottom plate, and the left end side face of the positioning rod is connected with the inside side face of the second round hole in a matched mode.

The positioning rod slides under the action of the first round hole, and the position of the first disc is fixed under the action of matching clamping between the left end side face of the positioning rod and the inner side face of the second round hole.

Furthermore, the positioning unit further comprises a cylindrical block, the cylindrical block is arranged at the left end of the positioning rod, the cylindrical block is located at the left end of the first disc, and the positioning rod can slide in the first circular hole more easily under the action of the cylindrical block.

Further, the adjusting unit comprises a second sliding groove and an adjusting block, the second sliding groove is arranged in the middle of the upper side of the workbench in the left-right direction, and two ends of the second sliding groove are respectively connected with the adjusting block in a sliding mode.

Under the action of external force, the two adjusting blocks slide relatively in the second sliding groove, and the position of the aluminum alloy is adjusted through the relative sliding of the two adjusting blocks.

Furthermore, the adjusting unit further comprises a second movable shaft, a second thread and a second disc, the side faces of the left end and the right end of the second movable shaft are respectively connected with the left side and the right side of the inner part of the second sliding groove in a rotating mode, the side faces of the left end and the right end of the second movable shaft are respectively connected with an adjusting block through the second thread in the opposite direction in a threaded mode, and the second disc is arranged at the left end of the second movable shaft.

The second disc is driven to rotate under the action of external force, the second movable shaft is driven to move through the rotation of the second disc, and the two adjusting blocks are driven to slide relatively between the inner parts of the second sliding grooves through the movement of the second movable shaft under the action of threaded connection between the second movable shaft and one adjusting block through threads in opposite directions on the side faces of the left end and the right end of the second movable shaft respectively.

Compared with the prior art, the invention has the beneficial effects that: this thermal-insulated bridge cut-off aluminum alloy threading machine has following benefit:

1. the heat-insulation bridge-cutoff aluminum alloy threading machine is provided with an adjusting unit, the second movable shaft is driven to move through the rotation of the second disc, the two adjusting blocks are driven to slide relatively between the inner parts of the second sliding groove through the movement of the second movable shaft under the effect of threaded connection between the second movable shaft and the adjusting block through the second screw thread with the opposite direction on the side faces of the left end and the right end of the second movable shaft respectively, and the position of aluminum alloy is adjusted through the relative sliding of the two adjusting blocks.

2. This thermal-insulated bridge cut-off aluminum alloy threading machine is provided with fixed unit, slides from top to bottom through electric telescopic handle drive a fixed block, under the cooperation linkage between the inboard of two fixed blocks, realizes making the cooperation between the inboard of two fixed blocks and the one end of nylon strip be connected more stably under the effect of arc draw-in groove to the fixed action of the one end of nylon strip.

3. The heat-insulation broken bridge aluminum alloy threading machine is provided with a threading unit, the first movable shaft is driven to move through the rotation of the first disc, the side faces of the left end and the right end of the first movable shaft are respectively connected with the middle of one sliding block through threads, and the two sliding blocks are driven to relatively slide along the left direction and the right direction between the left end and the right end of the inside of the first sliding groove through the movement of the first movable shaft.

4. Realize the driven effect to the aluminum alloy under the relative rotation effect of cooperation between two processing running rollers, drive two sliders along left right direction relative slip between the both ends about the inside of spout one under power component's effect, two processing running rollers that correspond about both ends are driven through the relative slip of two sliders along left right direction relative slip to the realization is to the driven effect of the aluminum alloy of different specifications.

Drawings

FIG. 1 is a schematic view of the structure of the present invention.

Fig. 2 is a schematic rear view of the present invention.

FIG. 3 is an enlarged view of a portion A of FIG. 2 according to the present invention.

In the figure: the device comprises a base plate 1, a workbench 2, a conveyor belt 3, a strip penetrating unit 4, a sliding groove I41, a sliding block 42, a supporting rod 43, a rotating shaft 44, a processing roller 45, a square convex strip 46, a square groove 47, a movable shaft I48, a thread I49, a disc I410, a gear 411, a support frame I412, an arc-shaped fixed block 413, a motor 414, a positioning unit 5, a round hole I51, a positioning rod 52, a round hole II 53, a cylindrical block 54, a fixing unit 6, a support frame II 61, an electric telescopic rod 62, a fixed block 63, an arc-shaped clamping groove 64, an adjusting unit 7, a sliding groove II 71, an adjusting block 72, a movable shaft II 73, a thread II 74 and a disc II 75.

Detailed Description

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

Referring to fig. 1-3, the present embodiment provides a technical solution: a heat-insulating bridge-cutoff aluminum alloy threading machine comprises a bottom plate 1 and a threading unit 4.

Bottom plate 1: the front end of the upper side is provided with a workbench 2, the rear end of the upper side of the bottom plate 1 is provided with a conveyor belt 3, and the middle part of the upper side of the bottom plate 1 is provided with a fixing unit 6;

fixed unit 6 includes support frame two 61, electric telescopic handle 62 and fixed block 63, the upside of bottom plate 1 is provided with a support frame two 61 along the left and right directions, support frame two 61 sets up the rear side at bracing piece 43, the inside upside of support frame two 61 is provided with an electric telescopic handle 62, fixed block 63 is provided with two, a fixed block 63 sets up the upside at bottom plate 1, another fixed block 63 sets up the lower extreme at electric telescopic handle 62, the cooperation is connected between the inboard of two fixed blocks 63.

Under the supporting action of the second supporting frame 61, the electric telescopic rod 62 drives the fixing block 63 to slide up and down, and under the matching and connecting action between the inner sides of the two fixing blocks 63, the fixing action on one end of the nylon strip is realized.

The fixing unit 6 further comprises two arc-shaped clamping grooves 64, the two arc-shaped clamping grooves 64 are formed in the inner sides of the two fixing blocks 63 respectively in the front-back direction, and under the action of the arc-shaped clamping grooves 64, the inner sides of the two fixing blocks 63 are connected with one ends of the nylon strips in a matched mode more stably.

The threading unit 4: comprises a first sliding groove 41, a first sliding block 42, a supporting rod 43, rotating shafts 44, processing rollers 45, square convex strips 46, square grooves 47 and a power assembly, wherein the first sliding groove 41 is formed in the middle of the upper side of the bottom plate 1 along the left-right direction, the left end and the right end of the inside of the first sliding groove 41 are respectively connected with the sliding block 42 in a sliding manner, the upper ends of the two sliding blocks 42 are respectively provided with the supporting rod 43, the inner sides of the two supporting rods 43 are respectively connected with the two rotating shafts 44 in a rotating manner, the end side surfaces of the four rotating shafts 44 are respectively fixedly connected with the processing rollers 45, the two processing rollers 45 corresponding to the upper end and the lower end of the same end are matched and relatively rotated, the right ends of the two rotating shafts 44 at the left end are respectively provided with the square convex strips 46, the left ends of the two rotating shafts 44 at the right end are respectively provided with the square grooves 47, the outer sides of the square convex strips 46 corresponding to the left side and the outer sides of the square concave grooves 47 are connected in a sliding manner, the power assembly is arranged on the right side of the right end support rod 43, and the left end of the power assembly is fixedly connected with the right end of the rotating shaft 44 on the right end.

Fix the one end of nylon strip under fixed unit 6's fixed action, sliding connection's effect between the outside of the square sand grip 46 that corresponds about and the inside side of square groove 47, form an axle between two axis of rotation 44 that correspond about making, under the cooperation relative rotation effect between two processing running rollers 45 that correspond about through the same end, realize the driven effect to the aluminum alloy, drive two sliders 42 along left and right directions relative slip between the both ends about the inside of spout 41 under power component's effect, the relative slip drives processing running roller 45 along left and right directions relative slip about the both ends through the relative slip of two sliders 42, thereby realize the driven effect to the aluminum alloy of different specifications.

The power assembly comprises a first movable shaft 48, a first screw thread 49 and a first disc 410, the side faces of the left end and the right end of the first movable shaft 48 are respectively in rotating connection with the left side and the right side of the inside of the first sliding groove 41, the side faces of the left end and the right end of the first movable shaft 48 are respectively in threaded connection with the middle of a sliding block 42 through the first screw thread 49, and the first disc 410 is arranged at the left end of the first movable shaft 48.

The first disc 410 is rotated under the action of external force, the first disc 410 is rotated to drive the first movable shaft 48 to move, the side faces of the left end and the right end of the first movable shaft 48 are respectively connected with the middle of one sliding block 42 through threads 49, and the two sliding blocks 42 are driven to relatively slide between the left end and the right end of the inner portion of the first sliding groove 41 along the left-right direction through the movement of the first movable shaft 48.

The power assembly further comprises a gear 411 and a first support frame 412, the first support frame 412 is arranged on the right side of the right end support rod 43, the number of the gear 411 is two, the two gears 411 are respectively arranged on the right end side faces of the two rotating shafts 44 on the right end, and the two gears 411 are connected in a meshed mode.

Under the meshing connection effect between the two gears 411, the rotation of one gear 411 drives the rotation of the other gear 411, and the relative rotation between the two gears 411 drives the matching relative rotation between the two processing rollers 45 which are up and down corresponding.

The power assembly further comprises an arc-shaped fixing block 413 and a motor 414, the motor 414 is fixedly connected to the right side of the first support frame 412 through the arc-shaped fixing block 413, an output shaft of the motor 414 is fixedly connected with the right end of a rotating shaft 44 at the right end, and an input end of the motor 414 is electrically connected with an output end of an external power supply through an external control switch.

The output shaft of the motor 414 is driven to rotate by the external power source, the rotation of the output shaft of the motor 414 drives the rotation of a rotating shaft 44, and the rotation of a rotating shaft 44 drives the rotation of a gear 411.

The positioning unit 5 comprises a first circular hole 51, a positioning rod 52 and a second circular hole 53, the first circular hole 51 is uniformly formed in the left end of the first circular disc 410 along the circumferential direction, the positioning rod 52 is slidably connected inside the first circular hole 51, the second circular hole 53 is formed in the left side of the bottom plate 1, and the left end side face of the positioning rod 52 is in matched clamping connection with the inside side face of the second circular hole 53.

The positioning rod 52 slides under the action of the first round hole 51, and the position of the first disc 410 is fixed under the action of matching clamping between the left end side face of the positioning rod 52 and the inner side face of the second round hole 53.

The positioning unit 5 further comprises a cylindrical block 54, the cylindrical block 54 is arranged at the left end of the positioning rod 52, the cylindrical block 54 is arranged at the left end of the first disc 410, and the positioning rod 52 can slide in the circular hole 51 more easily under the action of the cylindrical block 54.

The adjusting unit 7 comprises a second sliding groove 71 and an adjusting block 72, the second sliding groove 71 is arranged in the middle of the upper side of the workbench 2 in the left-right direction, and the left end and the right end of the inner part of the second sliding groove 71 are respectively connected with the adjusting block 72 in a sliding manner.

Under the action of external force, the two adjusting blocks 72 relatively slide in the second sliding groove 71, and the position of the aluminum alloy is adjusted through the relative sliding of the two adjusting blocks 72.

The adjusting unit 7 further comprises a second movable shaft 73, a second thread 74 and a second disc 75, the side surfaces of the left end and the right end of the second movable shaft 73 are respectively in rotating connection with the left side and the right side of the inside of the second sliding chute 71, the side surfaces of the left end and the right end of the second movable shaft 73 are respectively in threaded connection with an adjusting block 72 through the second thread 74 in the opposite direction, and the second disc 75 is arranged at the left end of the second movable shaft 73.

The second disc 75 is driven to rotate under the action of external force, the second movable shaft 73 is driven to move through the rotation of the second disc 75, and the two adjusting blocks 72 are driven to relatively slide between the inner parts of the second sliding grooves 71 through the movement of the second movable shaft 73 under the action of threaded connection between the left end side and the right end side of the second movable shaft 73 and one adjusting block 72 through the second screw threads 74 in opposite directions.

The working principle of the heat-insulation bridge-cutoff aluminum alloy strip penetrating machine provided by the invention is as follows:

under the supporting action of the second supporting frame 61, the electric telescopic rod 62 drives the one fixing block 63 to slide up and down, under the matching connection action between the inner sides of the two fixing blocks 63, the fixing action on one end of the nylon strip is realized, under the action of the arc-shaped clamping groove 64, the matching connection between the inner sides of the two fixing blocks 63 and one end of the nylon strip is more stable, under the action of the sliding connection between the outer sides of the square convex strips 46 corresponding to the left and the right and the inner side surfaces of the square groove 47, a shaft is formed between the two rotating shafts 44 corresponding to the left and the right, the output shaft of the motor 414 is driven to rotate under the action of an external power supply, the rotating shaft 44 is driven to rotate by the rotation of the output shaft of the motor 414, the rotation of the gear 411 is driven to rotate by the rotation of the one rotating shaft 44, under the meshing connection action between the two gears 411, the rotation of the other gear 411 is driven by the rotation of the one gear 411, the two processing rollers 45 corresponding up and down are driven to rotate relatively by the relative rotation between the two gears 411, the aluminum alloy is driven to rotate under the action of the matched relative rotation between the two processing rollers 45 corresponding up and down at the same end, the first disc 410 is rotated under the action of external force, the first movable shaft 48 is driven to move by the rotation of the first disc 410, the two sliders 42 are driven to slide relatively between the left end and the right end of the inner part of the first chute 41 along the left-right direction by the movement of the first movable shaft 48 under the action of threaded connection between the left end and the right end of the first movable shaft 48 and the middle part of the slider 42 through the first thread 49, the processing rollers 45 at the left end and the right end are driven to slide relatively along the left-right direction by the relative sliding of the two sliders 42, so that the transmission effect on the aluminum alloys with different specifications is realized, and the positioning rod 52 realizes the sliding effect under the action of the first circular hole 51, the positioning rod 52 can slide in the first round hole 51 more easily under the action of the cylindrical block 54, the first disc 410 is fixed under the action of the matching clamping between the left end side face of the positioning rod 52 and the inner side face of the second round hole 53, the second disc 75 is driven to rotate under the action of external force, the second disc 75 rotates to drive the second movable shaft 73 to move, the left end side face and the right end side face of the second movable shaft 73 are respectively connected with one adjusting block 72 through threads in the second screw thread 74 in opposite directions, the two adjusting blocks 72 are driven to slide relatively between the inner portions of the second sliding grooves 71 through the movement of the second movable shaft 73, and the position of the aluminum alloy is adjusted through the relative sliding of the two adjusting blocks 72.

It should be noted that the motor 414 disclosed in the above embodiments is a fractional start motor, and the control switch set is used to control the operation of the motor 414 in a conventional manner.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. The utility model provides a strip machine is worn to thermal-insulated bridge cut-off aluminum alloy which characterized in that: comprises a bottom plate (1) and a strip penetrating unit (4);

base plate (1): a workbench (2) is arranged at the front end of the upper side of the bottom plate (1), a conveyor belt (3) is arranged at the rear end of the upper side of the bottom plate (1), and a fixing unit (6) is arranged in the middle of the upper side of the bottom plate (1);

threading unit (4): comprises a first sliding groove (41), a first sliding block (42), a first supporting rod (43), rotating shafts (44), processing rollers (45), square convex strips (46), square grooves (47) and a power assembly, wherein the first sliding groove (41) is formed in the middle of the upper side of the bottom plate (1) along the left-right direction, the first sliding block (42) is respectively connected to the left end and the right end of the first sliding groove (41) in a sliding manner, the supporting rods (43) are respectively arranged at the upper ends of the two sliding blocks (42), the two rotating shafts (44) are respectively and rotatably connected to the inner sides of the two supporting rods (43), the processing rollers (45) are respectively and fixedly connected to the end side surfaces of the four rotating shafts (44), the two processing rollers (45) which vertically correspond to each other at the same end are matched and relatively rotated, the square convex strips (46) are respectively arranged at the right ends of the two rotating shafts (44) at the left end, the square grooves (47) are respectively formed at the left end of the two rotating shafts (44) at the right end, sliding connection between the outside of the square protruding strip (46) that corresponds about and the inside side of square groove (47), power component sets up the right side at right-hand member bracing piece (43), fixed connection between the left end of power component and the right-hand member of the axis of rotation (44) of right-hand member.

2. The heat-insulating bridge-cut-off aluminum alloy threading machine according to claim 1, characterized in that: the power assembly comprises a first movable shaft (48), a first thread (49) and a first disc (410), the side faces of the left end and the right end of the first movable shaft (48) are respectively connected with the left side and the right side of the inner part of the first sliding groove (41) in a rotating mode, the side faces of the left end and the right end of the first movable shaft (48) are respectively connected with the middle of a first thread (49) and a sliding block (42) in a threaded mode, and the first disc (410) is arranged at the left end of the first movable shaft (48).

3. The heat-insulating bridge-cut-off aluminum alloy threading machine according to claim 1, characterized in that: the power assembly further comprises a gear (411) and a first support frame (412), the first support frame (412) is arranged on the right side of the right end support rod (43), the two gears (411) are arranged on the right end side faces of the two rotating shafts (44) on the right end, and the two gears (411) are meshed and connected.

4. The heat-insulating bridge-cut-off aluminum alloy threading machine according to claim 3, characterized in that: the power component further comprises an arc fixing block (413) and a motor (414), the motor (414) is fixedly connected to the right side of the first support frame (412) through the arc fixing block (413), an output shaft of the motor (414) is fixedly connected with the right end of a rotating shaft (44) at the right end, and the input end of the motor (414) is electrically connected with the output end of an external power supply through an external control switch.

5. The heat-insulating bridge-cut-off aluminum alloy threading machine according to claim 1, characterized in that: fixed unit (6) include support frame two (61), electric telescopic handle (62) and fixed block (63), the upside of bottom plate (1) is provided with a support frame two (61) along the left and right directions, support frame two (61) set up the rear side at bracing piece (43), the inside upside of support frame two (61) is provided with an electric telescopic handle (62), fixed block (63) are provided with two, and a fixed block (63) set up the upside at bottom plate (1), and another fixed block (63) set up the lower extreme at electric telescopic handle (62), and the cooperation is connected between the inboard of two fixed blocks (63).

6. The heat-insulating bridge-cut-off aluminum alloy threading machine according to claim 5, characterized in that: the fixing unit (6) further comprises two arc-shaped clamping grooves (64), and the two arc-shaped clamping grooves (64) are respectively arranged on the inner sides of the two fixing blocks (63) in the front-back direction.

7. The heat-insulating bridge-cut-off aluminum alloy threading machine according to claim 1, characterized in that: positioning unit (5) include round hole one (51), locating lever (52) and round hole two (53), round hole one (51) has evenly been seted up along the circumferencial direction to the left end of disc one (410), the inside sliding connection of round hole one (51) has locating lever (52), round hole two (53) have been seted up in the left side of bottom plate (1), the cooperation joint between the left end side of locating lever (52) and the inside side of round hole two (53).

8. The heat-insulating bridge-cut-off aluminum alloy threading machine according to claim 7, characterized in that: the positioning unit (5) further comprises a cylindrical block (54), the cylindrical block (54) is arranged at the left end of the positioning rod (52), and the cylindrical block (54) is located at the left end of the first disc (410).

9. The heat-insulating bridge-cut-off aluminum alloy threading machine according to claim 1, characterized in that: adjusting element (7) include spout two (71) and regulating block (72), the upside middle part in workstation (2) is seted up along the left right direction in spout two (71), both ends difference sliding connection has a regulating block (72) about the inside of spout two (71).

10. The heat-insulating bridge-cut-off aluminum alloy threading machine according to claim 9, characterized in that: adjusting element (7) still include loose axle two (73), screw thread two (74) and disc two (75), the both ends side rotates between the inside left and right sides of the two (71) of left and right sides respectively and spout of loose axle two (73) and is connected, threaded connection between the both ends side is through screw thread two (74) and an adjusting block (72) that an opposite direction respectively about loose axle two (73), disc two (75) set up the left end at loose axle two (73).