CN112060608A - Aluminium alloy section heat-insulating synthesizer - Google Patents

Abstract

The invention discloses an aluminum alloy section heat-insulating synthesizer, which comprises an equipment main body and rolling equipment, wherein a rolling front piece is arranged on the equipment main body and comprises a plurality of fixed seats, a sliding rod is connected between a pair of fixed seats, a sliding plate is connected on the sliding rod in a sliding manner, and a pair of rolling cylinders is connected on the sliding plate; the rolling cylinder comprises a rotating shaft, the rotating shaft is rotatably connected with the sliding plate, the outer side of the rotating shaft is rotatably connected with an elastic part, metal particles are arranged in the elastic part, a variable rolling mechanism is arranged on the inner side of the elastic part, a control box is installed on the equipment main body, and the control box is electrically connected with rolling equipment. According to the invention, the variable rolling mechanism is additionally arranged on the rolling equipment of the adiabatic synthesizer, so that the rolling equipment can be suitable for different bridge-cut aluminum shapes, the application range of the rolling equipment is greatly improved, the arc or polygonal bridge-cut aluminum is prevented from being extruded, deformed and damaged, the rolling effect is greatly improved, and the integral rolling speed is improved.

Description

Aluminium alloy section heat-insulating synthesizer

Technical Field

The invention belongs to the technical field of aluminum alloy production and processing, and particularly relates to an aluminum alloy profile adiabatic synthesizer.

Background

The aluminum alloy is an alloy which takes aluminum as a base and is added with a certain amount of other alloying elements, has the characteristics of low density, good mechanical property, good processing property, no toxicity, easy recovery, excellent conductivity, heat transfer property, corrosion resistance and the like, and is widely used in the fields of marine industry, chemical industry, aerospace, metal packaging, transportation and the like.

Among them, the bridge cutoff aluminum is mainly used in the field of doors and windows, which is an improved type developed for improving the thermal insulation performance of doors and windows on the basis of aluminum alloy. The bridge-cut-off aluminum is also called heat-insulating bridge-cut-off aluminum profile, heat-insulating aluminum alloy profile, bridge-cut-off aluminum alloy, cold and hot bridge-cut-off profile and bridge-cut-off aluminum plastic composite profile. It has more excellent performance than common aluminum alloy section. The production process technology of the bridge-cut aluminum adopts a rolling embedded type and a three-step method, namely, tooth punching, strip threading and rolling, and the production process comprises the following steps: operating platform on the section bar, sticking protective film, slotting, strip penetrating, rolling, filling polyurethane foam in the heat insulation cavity and packaging.

The heat-insulating synthesizer is used in the production process of the bridge-cut aluminum, and mainly comprises the steps of penetrating an aluminum alloy into a toothed bridge-cut aluminum tooth path with formed teeth through a strip penetrating device, and then rolling the bridge-cut aluminum and a polyvinyl chloride rigid plastic adhesive tape together through a rolling device. However, the rolling equipment of the heat-insulated synthesizer is mainly suitable for square bridge-cut-off aluminum, and when a user needs to roll some arc-shaped bridge-cut-off aluminum or polygonal bridge-cut-off aluminum, the bridge-cut-off aluminum is easily deformed and damaged due to different bearing pressures of the bridge-cut-off aluminum, so that the subsequent processing production of the bridge-cut-off aluminum is influenced, and the processing rate of the user is reduced.

Therefore, in order to solve the above technical problems, it is necessary to provide an aluminum alloy profile adiabatic synthesizer.

Disclosure of Invention

The invention aims to provide an aluminum alloy section heat-insulation synthesizer, which aims to solve the problem that the heat-insulation synthesizer is not suitable for arc or polygonal bridge-cut aluminum, so that the bridge-cut aluminum is easy to deform and damage and subsequent processing production is influenced.

In order to achieve the above object, an embodiment of the present invention provides the following technical solutions:

the aluminum alloy profile heat-insulating synthesizer comprises an equipment main body and rolling equipment, wherein a rolling front piece is installed on the equipment main body and comprises a plurality of fixed seats, a sliding rod is connected between a pair of the fixed seats, a sliding plate is connected onto the sliding rod in a sliding manner, and a pair of rolling cylinders is connected onto the sliding plate;

the rolling cylinder comprises a rotating shaft, the rotating shaft is rotatably connected with the sliding plate, the outer side of the rotating shaft is rotatably connected with an elastic piece, metal particles are arranged in the elastic piece, and a variable rolling mechanism is arranged on the inner side of the elastic piece.

Further, install the control box in the equipment main part, control box and roll-in equipment electric connection, the person of facilitating the use controls roll-in equipment through the control box, carries out the roll-in to bridge cut-off aluminium through roll-in equipment.

Further, install the guide in the equipment main part, the guide is located the one side that the piece kept away from the roll-in equipment before the roll-in, guides through the guide, is convenient for guide bridge cut-off aluminium to go into the roll-in piece and carry out preliminary roll-in before the roll-in, rolls in equipment again.

Furthermore, the quantity of fixing base is four, fixing base and equipment main part fixed connection are convenient for improve the roll-in effect to the bridge cut-off aluminium for the roll-in is more abundant, avoids adhesive tape and bridge cut-off aluminium bonding inadequately.

Furthermore, a locking screw is arranged between the sliding rod and the sliding plate, the locking screw penetrates through the sliding plate and is connected with the sliding rod, sliding of the sliding plate is convenient to fix through the locking screw, and the sliding phenomenon of the sliding plate in the rolling process of bridge cutoff aluminum is avoided.

Furthermore, the variable rolling mechanism comprises non-Newtonian fluid, the non-Newtonian fluid is utilized to generate certain hardness when being extruded, meanwhile, the flowability of the non-Newtonian fluid is utilized to enable the elastic part to be suitable for the bridge-cut-off aluminum with different shapes, the bridge-cut-off aluminum with different shapes is rolled, magnetic powder is arranged on one side, close to the rotating shaft, of the non-Newtonian fluid, the magnetism of the magnetic powder is utilized, when the bridge-cut-off aluminum is rolled by the elastic part, the elastic part is extruded, the distance between the magnetic powder and the elastic part is shortened, metal particles in the elastic part can be attracted by the magnetic powder, the magnetic force of the magnetic powder on the metal particles can extrude the magnetic conductive elastic plate, the magnetic conductive elastic plate has larger acting force on the non-Newtonian fluid, the extrusion force on the bridge-cut-off aluminum is increased, the rolling effect is greatly improved, and the magnetic conductive elastic, used for isolating the non-Newtonian fluid and the magnetic powder.

Further, the magnet is arranged on the inner side of the magnetic powder, and the magnet can enable the surface of the magnetic powder to be magnetic and is used for attracting metal particles in the elastic piece.

Furthermore, the magnetic conduction elastic plate is made of a leakage-proof elastic material, so that the condition that non-Newtonian fluid or magnetic powder leaks is avoided.

Furthermore, one side of the magnetic powder, which is far away from the magnetic conductive elastic plate, is provided with an air cavity, the elastic piece is provided with an air faucet, and the air faucet is connected with a plug.

Further, the air cock link up the elastic component and is linked together with the air cavity, and user's accessible air cock carries out the gas injection to the air cavity for the air cavity can expand, thereby strengthens the extrusion to the magnetic, thereby further increase is to the extrusion of elastic component, makes the elastic component more abundant to the extrusion of bridge cut-off aluminium.

Compared with the prior art, the invention has the following advantages:

according to the invention, the variable rolling mechanism is additionally arranged on the rolling equipment of the adiabatic synthesizer, so that the rolling equipment can be suitable for different bridge-cut aluminum shapes, the application range of the rolling equipment is greatly improved, the arc or polygonal bridge-cut aluminum is prevented from being extruded, deformed and damaged, the rolling effect is greatly improved, and the integral rolling speed is improved.

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, it is obvious that the drawings in the following description are only some embodiments described in the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a perspective view of an aluminum alloy profile adiabatic synthesizer in an embodiment of the present invention;

FIG. 2 is a side view of an aluminum alloy profile adiabatic synthesizer in accordance with an embodiment of the present invention;

FIG. 3 is a perspective view of a roll front piece in one embodiment of the present invention;

FIG. 4 is a partial cross-sectional view of a rolled front piece in accordance with an embodiment of the present invention;

FIG. 5 is a schematic diagram of the structure at A in FIG. 4 according to an embodiment of the present invention;

FIG. 6 is a cross-sectional view of a metal particle in accordance with an embodiment of the present invention;

FIG. 7 is a top cross-sectional view of a roller tube in accordance with one embodiment of the present invention;

FIG. 8 is another angular partial cross-sectional view of a roller tube in accordance with an embodiment of the present invention;

fig. 9 is a schematic structural diagram of a portion B in fig. 8 according to an embodiment of the present invention.

In the figure: 1. the device comprises a device body, 101, a control box, 102, a guide piece, 2, a rolling device, 3, a rolling front piece, 301, a fixed seat, 302, a sliding rod, 303, a sliding plate, 304, a rolling cylinder, 305, a rotating shaft, 306, an elastic piece, 307, non-Newtonian fluid, 308, magnetic powder, 3008, a magnet, 309, a magnetic conductive elastic plate, 310, an air cavity, 311, an air nozzle, 312, a plug, 4, an electromagnetic generating cavity, 401, an iron core, 402, a coil, 403, a power supply, 404, a first lead, 405, a chip, 406 and a second lead.

Detailed Description

The present invention will be described in detail below with reference to embodiments shown in the drawings. The embodiments are not intended to limit the present invention, and structural, methodological, or functional changes made by those skilled in the art according to the embodiments are included in the scope of the present invention.

The invention discloses an aluminum alloy section heat-insulation synthesizer, which comprises an equipment main body 1, rolling equipment 2 and a rolling front piece 3 which are arranged on the equipment main body 1, and an electromagnetic generating cavity 4, and is shown in figures 1-9.

Referring to fig. 1-2, install control box 101 on the equipment main part 1, control box 101 and roll-in equipment 2 electric connection, the person of facilitating the use controls roll-in equipment 2 through control box 101, roll-in equipment 2 is to bridge cut-off aluminium and roll-in, install guide 102 on the equipment main part 1, guide 102 locates the one side that rolling-in front piece 3 kept away from roll-in equipment 2, guide through guide 102, be convenient for guide bridge cut-off aluminium go into to roll-in front piece 3 and carry out preliminary roll-in, roll-in equipment 2 again.

Referring to fig. 1-5, a rolling front piece 3 is installed on an apparatus main body 1, the rolling front piece 3 is used for rolling bridge-cut-off aluminum with different shapes to ensure that colloid is clamped with the bridge-cut-off aluminum, the rolling front piece 3 comprises a plurality of fixed seats 301, the number of the fixed seats 301 is four, the fixed seats 301 are fixedly connected with the apparatus main body 1, a rolling barrel 304 is convenient to install, thereby improving the rolling effect on the bridge-cut-off aluminum, so that rolling is more sufficient, and the adhesive tape is prevented from being insufficiently adhered with the bridge-cut-off aluminum, a sliding rod 302 is connected between a pair of fixed seats 301, so that a sliding plate 303 can conveniently slide on the sliding rod 302, thereby adjusting the distance between a pair of sliding plates 303 to adapt to the bridge-cut-off aluminum with different sizes, a sliding plate 303 is slidably connected on the sliding rod 302, a locking screw is arranged between the sliding rod, through the locking screw, the sliding of the sliding plate 303 is convenient to fix, the sliding phenomenon of the sliding plate 303 in the rolling process of the bridge-cut aluminum is avoided, the sliding plate 303 is connected with a pair of rolling cylinders 304 for rolling the bridge-cut aluminum, each rolling cylinder 304 comprises a rotating shaft 305, the rotating shafts 305 are rotatably connected with the sliding plate 303 and can rotate along with the movement of the bridge-cut aluminum, so that the rolling effect of the rolling cylinders 304 on the bridge-cut aluminum can be mentioned, the outer side of the rotating shafts 305 is rotatably connected with elastic members 306, the elastic members 306 can be rubber or air bags, preferably, the elastic members 306 are made of air bags, so that metal particles can be conveniently installed, meanwhile, when the elastic members 306 contact the bridge-cut aluminum, the shape change can be carried out to adapt to the bridge-cut aluminum in different shapes, the elastic members 306 can be fully contacted with the bridge-cut aluminum, so that the extrusion effect of the elastic members 306 on the bridge-cut aluminum can be mentioned, make bridge cut-off aluminium and adhesive tape laminating more abundant, be equipped with the metal particle in the elastic component 306, the magnetic 308 of being convenient for attracts, utilizes magnetic 308 to attract the metal particle to can promote magnetic conduction elastic plate 309 extrusion non-Newton fluid 307, non-Newton fluid 307 has the same effort to elastic component 306, thereby can make the dynamics that elastic component 306 extrudes bridge cut-off aluminium bigger, improved the effect of roll-in by a wide margin.

Referring to fig. 4-5, a variable rolling mechanism is disposed inside the elastic member 306 for adapting to the bridge-cut aluminum with different shapes and improving the extrusion effect of the bridge-cut aluminum, the variable rolling mechanism includes a non-newtonian fluid 307, the non-newtonian fluid 307 can be adapted to the bridge-cut aluminum with different shapes by using the liquid flow rebound property of the non-newtonian fluid 307, when the non-newtonian fluid 307 is extruded, a certain reaction force can be generated, and simultaneously by using the fluidity of the non-newtonian fluid 307, the non-newtonian fluid 307 can be adapted to the bridge-cut aluminum with different shapes along with the elastic member 306, the bridge-cut aluminum with different shapes is rolled, a magnetic powder 308 is disposed on a side of the non-newtonian fluid 307 close to the rotating shaft 305, and by using the magnetism of the magnetic powder 308, when the bridge-cut aluminum is rolled by the elastic member 306, the elastic member 306 is extruded, so that the distance between, magnetic powder 308 can extrude magnetic conduction elastic plate 309 to the magnetic force of metal particle, and magnetic conduction elastic plate 309 can extrude non-Newtonian fluid 307 for non-Newtonian fluid 307 has bigger effort to elastic component 306, thereby increases the extrusion force to bridge cut-off aluminium, improves the effect of roll-in by a wide margin, is connected with magnetic conduction elastic plate 309 between magnetic powder 308 and the non-Newtonian fluid 307 for cut-off non-Newtonian fluid 307 and magnetic powder 308, avoids taking place the problem of seepage.

Referring to fig. 6, a magnet 3008 is provided inside the magnetic powder 308, and the magnet 3008 can make the surface of the magnetic powder 308 magnetic to attract the metal particles in the elastic member 306.

Specifically, magnetic conduction elastic plate 309 is the leak protection elastic material, avoid non-Newtonian fluid 307 or the condition that magnetic powder 308 takes place the seepage, one side that magnetic conduction elastic plate 309 was kept away from to magnetic powder 308 is equipped with air cavity 310, install air cock 311 on the elastic component 306, be connected with end cap 312 on the air cock 311, air cock 311 link up elastic component 306 and air cavity 310 and be linked together, user's accessible air cock 311 carries out the gas injection to air cavity 310, make the elastic component 306 inner chamber can expand, thereby further strengthen the extrusion to magnetic powder 308, further increase the extrusion of non-Newtonian fluid 307, thereby can increase the extrusion of non-Newtonian fluid 307 to elastic component 306, make elastic component 306 more abundant to the extrusion of bridge cut-off aluminium, realize the perfect laminating of elastic component 306 and bridge cut-off aluminium, the adhesive force of bridge cut-off aluminium and adhesive tape has been improved greatly, avoid appearing the.

Referring to fig. 7-9, an electromagnetic generating chamber 4 is formed between the elastic member 306 and the magnetic conductive elastic plate 309, the electromagnetic generating chamber 4 is used for storing a part of non-newtonian fluid 307, so that the iron core 401 is energized to generate strong magnetism, a thin film is arranged between the electromagnetic generating chamber 4 and the non-newtonian fluid 307, the thin film is provided with pores, when the elastic member 306 extrudes the aluminum bridge-cut, the non-newtonian fluid 307 extrudes the thin film, the thin film deforms to a certain degree, so that the diameter of the pores on the thin film is increased, the non-newtonian fluid 307 can flow into the electromagnetic generating chamber 4 through the pores, the problem that the non-newtonian fluid 307 is broken due to excessive pressure is avoided, the electromagnetic generating chamber 4 is spaced from the non-newtonian fluid 307, preferably, the number of the electromagnetic generating chambers 4 is six in the present invention, and is used for providing buffer for the non-newtonian fluid 307, the iron, the outer side of the iron core 401 is provided with a coil 402, the coil 402 can generate strong magnetism when being electrified, the strong magnetism can attract the magnetic powder 308, the strength of the magnetic powder 308 to non-Newtonian fluid 307 is further increased, so as to improve the whole roller pressure, a power supply 403 is arranged in the rotating shaft 305, the maximum voltage of the power supply 403 is 24V, the voltage is safe for human body, the risk of electric shock of a user is avoided, the power supply 403 is electrically connected with the control box 101, the user can conveniently control whether the power supply 403 is electrified or not through the control box 101, when the user needs to use the power supply 403, the power supply 403 is controlled to be turned on through the control box 101, a first lead 404 is connected between the power supply 403 and the coil 402, a chip 405 is arranged in the electromagnetism generating cavity 4, a second lead 406 is connected between the chip 405 and the power supply 403, in a normal state, the coil 402 is not in contact with the chip 405, and the coil 402, in the time, utilize the electric conductivity of non-Newtonian fluid 307, can be so that coil 402, power 403, first wire 404, chip 405 and second wire 406 are in closed circuit, thereby can make iron core 401 produce strong magnetism, strong magnetism can attract magnetic powder 308, make magnetic powder 308 strengthen to the extrusion force degree of elastic component 306, thereby can further increase the roll-in effect of elastic component 306 to bridge-cut-off aluminium, avoid the adhesive tape and the coming off of bridge-cut-off aluminium, first wire 404 and second wire 406 all link up magnetic powder 308, magnetic conduction elastic plate 309, air cavity 310 sets up.

According to the technical scheme, the invention has the following beneficial effects:

according to the invention, the variable rolling mechanism is additionally arranged on the rolling equipment of the adiabatic synthesizer, so that the rolling equipment can be suitable for different bridge-cut aluminum shapes, the application range of the rolling equipment is greatly improved, the arc or polygonal bridge-cut aluminum is prevented from being extruded, deformed and damaged, the rolling effect is greatly improved, and the integral rolling speed is improved.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (10)

1. The aluminum alloy section heat-insulating synthesizer comprises an equipment main body (1) and rolling equipment (2), and is characterized in that a rolling front piece (3) is mounted on the equipment main body (1), the rolling front piece (3) comprises a plurality of fixed seats (301), a slide rod (302) is connected between a pair of the fixed seats (301), a slide plate (303) is connected onto the slide rod (302) in a sliding manner, and a pair of pressing cylinders (304) is connected onto the slide plate (303);

the rolling cylinder (304) comprises a rotating shaft (305), the rotating shaft (305) is rotatably connected with the sliding plate (303), an elastic part (306) is rotatably connected to the outer side of the rotating shaft (305), metal particles are arranged in the elastic part (306), and a variable rolling mechanism is arranged on the inner side of the elastic part (306).

2. The machine for the heat-insulation synthesis of aluminum alloy profiles according to claim 1, characterized in that the equipment body (1) is provided with a control box (101), and the control box (101) is electrically connected with the rolling equipment (2).

3. Aluminium alloy profile thermoinsulating synthesizer according to claim 1 characterized in that on said equipment body (1) is mounted a guide (102), said guide (102) being provided on the side of the rolling front piece (3) away from the rolling equipment (2).

4. The aluminum alloy profile heat-insulation synthesizer as recited in claim 1, characterized in that the number of the fixed seats (301) is four, and the fixed seats (301) are fixedly connected with the equipment main body (1).

5. The aluminum alloy profile adiabatic synthesizer of claim 1, wherein a locking screw is arranged between the sliding bar (302) and the sliding bar (303), and the locking screw penetrates through the sliding bar (303) to be connected with the sliding bar (302).

6. The machine for the adiabatic synthesis of aluminum alloy profiles according to claim 1, wherein the variable rolling mechanism comprises a non-Newtonian fluid (307), a magnetic powder (308) is arranged on one side of the non-Newtonian fluid (307) close to the rotating shaft (305), and a magnetic conductive elastic plate (309) is connected between the magnetic powder (308) and the non-Newtonian fluid (307).

7. The machine for hot break synthesis of aluminum alloy profiles according to claim 6, characterized in that inside of the magnetic powder (308) is provided with a magnet (3008).

8. The machine for the heat-insulation synthesis of aluminum alloy profiles according to claim 6, characterized in that the magnetic-conductive elastic plate (309) is made of leakproof elastic material.

9. The machine for the heat-insulation synthesis of aluminum alloy profiles according to claim 6, characterized in that the magnetic powder (308) is provided with an air cavity (310) at the side far away from the magnetic conductive elastic plate (309), the elastic member (306) is provided with an air tap (311), and the air tap (311) is connected with a plug (312).

10. Aluminium alloy profile adiabatic synthesiser as claimed in claim 1, characterized in that air tap (311) is linked to air cavity (310) through resilient member (306).

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