CN210138965U - Forming system of aluminum-manganese alloy layer of integrated wall - Google Patents

Abstract

The utility model belongs to the technical field of integrated wall, especially, relate to forming system on aluminium manganese alloy layer of integrated wall, include edging mortise area (a) to the aluminium manganese alloy coiled material in proper order to and these two districts of preheating zone (b), be equipped with tongue-and-groove edging machine in edging mortise area (a), tongue-and-groove edging machine is including being located the gyro wheel friction drive structure on the aluminium manganese alloy coiled material upper surface, and is located aluminium manganese alloy coiled material both sides and setting are in the cam mortise structure of gyro wheel friction drive structure rear end. The utility model has the advantages of the shaping system is seted up to the tongue-and-groove effectively, and friction drive is rational in infrastructure effective, and the nimble adjustable of friction drive power size, and the regulative mode is simple and convenient to and can be applicable to the tongue-and-groove resistance of different intensity, and final shaping is effectual.

Description

Forming system of aluminum-manganese alloy layer of integrated wall

Technical Field

The utility model belongs to the technical field of integrated wall, especially, relate to the shaping system on aluminium manganese alloy layer of integrated wall.

Background

The integrated wall surface is an integrated whole house decoration solution provided aiming at the defects of house decoration pollution, complicated working procedures and the like. The aluminum-manganese alloy is used as a basic layer, and a composite layer structure is added on the basic layer, so that the wallpaper is the replacement product of wallpaper and paint, and has the most distinctive characteristics of strong stereoscopic impression and a concave-convex surface. On the other hand, the forming system of the aluminum-manganese alloy layer in the existing integrated wall surface process mainly comprises two steps of operations of forming mortises on two sides and driving by friction, but most friction driving structures in the forming system have the problem that pressure of a pressing wheel is fixed and cannot be adjusted, and finally, the phenomenon that static friction driving force is insufficient, driving is slipped, or static friction force is too large, so that the aluminum-manganese alloy coiled material is embossed with harmful appearance is caused, and therefore a friction driving structure with flexibly adjustable driving pressure for the forming system of the aluminum-manganese alloy layer is urgently needed in the market.

The patent publication No. CN108115813A, Chinese patent application No. 2018.06.05 discloses a production process of an A-level fireproof integrated wall decoration plate, which comprises the following steps: A. preparing corresponding gypsum and plant fiber, and pouring into a stirrer for uniformly stirring; B. processing and extruding the raw materials into a specification plate through a shaping die at a high temperature, cooling the specification plate, and then polishing and dedusting the front surface and the back surface of the integrated plate by using a polisher; C. coating waterproof paint on the integrated board by adopting a machine bubble spraying technology, and performing waterproof treatment; D. carrying out high-temperature off-line film coating on the glue by a machine hot melting technology; E. and locking type grooving is carried out on two sides of the plate by using a grooving machine.

However, the production process in the invention patent has the problem of great difficulty in overall operation.

Chinese utility model patent with patent publication No. CN204914298U and publication No. 2015.12.30 discloses a drive device for a roller of an open mill, which comprises a frame, wherein a front roller and a rear roller are arranged on the frame, and the drive device is characterized in that the front roller is driven by a front drive hydraulic motor or a front drive motor through a front roller speed reducer, and the rear roller is driven by a rear drive hydraulic motor or a rear drive motor through a rear roller speed reducer; the front roller speed reducer is installed on the rack through a supporting sliding mechanism, and the rear roller speed reducer is installed on the rack through a rear roller support.

But the roller drive device in the utility model patent has the single nonadjustable problem of friction drive intensity.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a molding system of aluminium manganese alloy layer of integrated wall, it can pass through the step mode of preheating again behind the manganese aluminium alloy both sides edging mortising slot, guarantees that the mortising slot sets up validity and the convenient follow-up advantage of carrying out the foaming operation, on the other hand to set up mounting bracket, mounting panel, electro-magnet attraction unit, roll drive unit and resistance adjustment unit's mode on the carriage, the effect of the effective drive coiled material of gyro wheel friction drive structure when reaching the shaping. The utility model has the advantages of the shaping system is seted up to the tongue-and-groove effectively, and friction drive is rational in infrastructure effective, and the nimble adjustable of friction drive power size, and the regulative mode is simple and convenient to and can be applicable to the tongue-and-groove resistance of different intensity, and final shaping is effectual.

The utility model provides a technical scheme that above-mentioned problem adopted is: the forming system of the aluminum-manganese alloy layer of the integrated wall surface sequentially comprises an edge rolling mortise area (a) of an aluminum-manganese alloy coiled material and two preheating areas (b), wherein a mortise edging machine is arranged in the edge rolling mortise area (a), the mortise edging machine comprises a roller friction driving structure positioned on the upper surface of the aluminum-manganese alloy coiled material and two mounting frames arranged on two sides of the aluminum-manganese alloy coiled material and arranged at the rear end of the roller friction driving structure, the roller friction driving structure comprises two mounting frames arranged on two sides of a conveying frame, two ends of the mounting frames are respectively sleeved and arranged on the mounting frames, the mounting frames are arranged on the mounting frames and the mounting frames, a lifting mode is used for adjusting the electromagnet attraction unit of the height of the mounting plates through magnetic attraction, the roller friction driving structure is arranged on the lower surfaces of the mounting plates and is used for improving the rolling driving unit of power for the cam mortise structure through a static friction driving mode, and the resistance adjusting unit is arranged on the rolling driving unit and is used for adjusting the static friction driving force of the rolling driving unit on the aluminum-manganese alloy coiled material by adjusting the resistance and further adjusting the magnetic force mode of the electromagnet attracting unit.

The further preferred technical scheme is as follows: the mounting frame comprises a frame body plate, a mounting opening arranged on the frame body plate and a mounting column vertically arranged on the mounting opening; the mounting plates comprise plate bodies and mounting rings which are arranged at two ends of the plate bodies and used for sleeving and mounting on the mounting columns; the electromagnet attraction unit comprises a permanent magnet ring arranged on the annular upper surface of the mounting ring, an annular electromagnet arranged on the inner top surface of the mounting port and sleeved with the mounting column, and a battery for adjustment arranged on the upper surface of the plate body and used for providing direct current for the annular electromagnet, wherein the battery for adjustment, the annular electromagnet and the resistance adjustment unit are connected in series, and the mounting column is sleeved with a buffer spring for upwards jacking the mounting ring.

The further preferred technical scheme is as follows: the rolling drive unit is including setting up U type mounting bracket on the plate body lower surface cup joints the setting and is in be used for on the middle part crossbeam of U type mounting bracket and be in carry out stiction driven pinch roller on the aluminium manganese alloy coiled material, set up and be used for rotary drive on the side spliced pole of U type mounting bracket the gear motor of pinch roller, and set up and be in be used for on the side spliced pole to gear motor provides for direct current drive with the battery.

The further preferred technical scheme is as follows: the rolling driving unit further comprises two connecting gears arranged at the side edge of the pinch roller and a fixed gear which is arranged on one side of the U-shaped mounting frame, is different from the side where the speed reducing motor is arranged, and is meshed with the connecting gears.

The further preferred technical scheme is as follows: the resistance adjusting unit comprises an installation beam arranged on the side connecting column provided with the speed reducing motor, a thermistor which is sleeved on the installation beam and used for adjusting the current and the magnetic field on the annular electromagnet in a distance adjusting mode between the speed reducing motor and the speed reducing motor, a position adjusting part which is arranged on the installation beam and used for controlling the distance between the thermistor and the speed reducing motor in a size adjusting mode through elastic jacking and magnetic repulsion, and a sliding rheostat which is arranged on the side connecting column, connected with the driving battery through a lead and used for adjusting the current of the electromagnetic electromagnet in the position adjusting part.

The further preferred technical scheme is as follows: the mounting cross beam is arranged on the side connecting column in a bonding mode with the side face, the long axial direction of the speed reducing motor is parallel to the long axial direction of the speed reducing motor, and the thermistor is arranged on the lower surface, close to the speed reducing motor, of the position adjusting portion in a bonding mode.

The further preferred technical scheme is as follows: position control portion is in including cup jointing the setting installation crossbeam is last and be used for setting thermistor's slip ring sets up the limiting plate of installation crossbeam end position department cup joints the setting installation crossbeam is last and be used for jack-up on the limiting plate the jack-up spring of slip ring cup joints the setting and is in just bonding the setting on the installation crossbeam the last second electro-magnet of side spliced pole to and the bonding setting is in the slip ring is close to on the annular side of second electro-magnet and be used for with form the second permanent magnet ring in repulsion magnetic field between the second electro-magnet.

The further preferred technical scheme is as follows: the thermistor is a positive temperature coefficient thermistor.

The further preferred technical scheme is as follows: the driving battery and the sliding rheostat and the speed reducing motor are respectively arranged on two side surfaces of the side connecting column.

A forming method of a forming system of an aluminum-manganese alloy layer integrated with a wall surface sequentially comprises the following steps:

s1, extruding the two sides of the aluminum-manganese alloy coiled material onto the wheel mortise structure, and manually pulling the aluminum-manganese alloy coiled material to the position below the rolling driving unit;

s2, the roller friction driving structure is opened by electrifying, the static friction driving force is adjusted according to the resistance of the wheel mortise structure, stable driving is guaranteed, and the aluminum-manganese alloy coiled material is less in impression;

and S3, heating the alloy coiled material with the mortises through an infrared heating device, and finishing the forming operation.

The utility model discloses a step mode of preheating again behind the manganese-aluminum alloy both sides edging mortising slot guarantees that the mortise sets up validity and the convenient follow-up advantage of carrying out the foaming operation, on the other hand to set up mounting bracket, mounting panel, electro-magnet attraction unit, roll drive unit and resistance adjusting unit's mode on the carriage, the effect of the effective drive coiled material of gyro wheel friction drive structure when reaching the shaping. The utility model has the advantages of the shaping system is seted up to the tongue-and-groove effectively, and friction drive is rational in infrastructure effective, and the nimble adjustable of friction drive power size, and the regulative mode is simple and convenient to and can be applicable to the tongue-and-groove resistance of different intensity, and final shaping is effectual.

Drawings

Fig. 1 is a schematic view of the steps of the molding system of the present invention.

Fig. 2 is the position schematic diagram of the friction driving structure of the middle roller and the cam mortise structure of the present invention.

Fig. 3 is a schematic position diagram of the rolling driving unit according to the present invention.

Fig. 4 is a position structure diagram of the electromagnet attraction unit of the present invention.

Fig. 5 is a schematic diagram of a position structure of the rolling driving unit according to the present invention.

Fig. 6 is a schematic diagram of a position structure of the middle resistance adjusting unit according to the present invention.

Detailed Description

The following description is only for the preferred embodiment of the present invention, and is not intended to limit the scope of the present invention.

Example (b): as shown in fig. 1, 2, 3, 4, 5 and fig. 6, the forming system of the aluminum-manganese alloy layer of the integrated wall sequentially includes two steps of edging and mortising a of the aluminum-manganese alloy coiled material and preheating b, the step of edging and mortising a is completed by a mortising edging machine, the mortising edging machine includes a roller friction driving structure located on the upper surface of the aluminum-manganese alloy coiled material, and is located the two sides of the aluminum-manganese alloy coiled material are arranged at the cam mortising structure at the rear end of the roller friction driving structure, and the forming system is characterized in that: the gyro wheel friction drive structure is including setting up two mounting brackets 1 of both sides position department on carriage 11, and the setting is cup jointed respectively at both ends mounting panel 2 on the mounting bracket 1 sets up mounting bracket 1 with on mounting panel 2 and through magnetic force attraction lifting means in order to be used for adjusting the electro-magnet of mounting panel 2 height attracts unit 3, sets up on 2 lower surfaces of mounting panel and through the stiction drive mode in order to be used for cam mortise structure improves the roll drive unit 4 of power, and sets up on the roll drive unit 4 and through adjusting resistance and then adjust 3 magnetic force modes of electro-magnet attraction unit are in order to be used for adjusting roll drive unit 4 is in resistance adjustment unit 5 of stiction drive power size on the aluminium manganese alloy coiled material.

In this embodiment, after the aluminum-manganese alloy coiled material is bent upwards at two sides and is provided with the connecting mortises, preheating operation is performed, and then a foaming material is added to form the covering film, namely the covering film is an integrated wall panel, wherein the cam mortising structure is a physical extrusion structure for forming the mortises, and the roller friction driving structure is used for pulling the aluminum-manganese alloy coiled material on the cam mortising structure, pulling out the coiled material after the mortising has been provided, and certainly, the coiled material needs to be manually inserted and pulled down when just starting to be formed at the roller friction driving structure.

Wherein the rolling driving unit 4 is a static friction driving force application part, the electromagnet attraction unit 3 is used for adjusting the height of the mounting plate 2, namely the height of the rolling driving unit 4, for example, when the resistance of the cam mortise structure is large, the electromagnet attraction unit 3 reduces the height of the rolling driving unit 4, the rolling driving unit 4 is pressed on the aluminum-manganese alloy coiled material with a large pressure, the static friction force is large at the moment, the driving is effective, certain coining can be generated certainly, which is a part of the sacrifice made by friction driving, and when the resistance of the cam mortise structure is small, the rolling driving unit 4 is partially lifted up, the static friction driving force is relatively reduced, at the moment, the aluminum-manganese alloy coiled material can also be normally friction-driven, and the coining is small, the two situations depend on the structures required by the connecting mortises on the two sides of the integrated wall surface, if the structure is only a single groove-tenon, the resistance is naturally small.

On the other hand, the force of the electromagnet attraction unit 3 attracting and lifting the rolling drive unit 4 upward is generated by the electromagnetic effect, and the smaller the current is, the smaller the magnetic force is, so the resistance adjustment unit 5 can effectively and finally feed back to the height adjustment effect of the rolling drive unit 4 by the resistance adjustment manner.

The mounting frame 1 comprises a frame body plate 101, a mounting opening 102 arranged on the frame body plate 101, and a mounting column 103 vertically arranged on the mounting opening 102; the mounting plate 2 comprises a plate body 201 and mounting rings 202 which are arranged at two ends of the plate body 201 and used for being sleeved on the mounting columns 103; the electromagnet attraction unit 3 comprises a permanent magnet ring 301 arranged on the annular upper surface of the mounting ring 202, an annular electromagnet 302 arranged on the inner top surface of the mounting opening 102 and sleeved with the mounting column 103, and a regulation battery 303 arranged on the upper surface of the plate body 201 and used for providing direct current for the annular electromagnet 302, wherein the regulation battery 303, the annular electromagnet 302 and the resistance regulation unit 5 are connected in series, and a buffer spring 6 used for jacking up the mounting ring 202 is sleeved on the mounting column 103.

In this embodiment, the elastic support height of the buffer spring 6 is adjusted, so that when the annular electromagnet 302 does not attract the permanent magnet ring 301, and the plate body 201 is located at the lowest position, the rolling driving unit 4 is driven by friction with a maximum static friction force, and the resistance at the cam mortise structure is reduced, and when the friction force is not required to be large, the annular electromagnet 302 is electrified and magnetized to lift the rolling driving unit 4.

The adjusting battery 303 is used for supplying power to the annular electromagnet 302 in the prior art, attracting the permanent magnet ring 301 upwards in an electromagnetic manner, and finally lifting the rolling driving unit 4 to reduce the static friction driving force, so that the two aspects of sufficient driving and reduced stamping are achieved, wherein the annular electromagnet 302 has the characteristic that the current is in direct proportion to the size of the magnetic field for attraction.

The rolling driving unit 4 is including setting up U type mounting bracket 401 on the plate body 201 lower surface, cup joints the setting and is in on the middle part crossbeam of U type mounting bracket 401 and be used for on the aluminium manganese alloy coiled material carry out stiction driven pinch roller 402, set up and be in on the side spliced pole of U type mounting bracket 401 and be used for rotary drive pinch roller 402's gear motor 403, and set up and be in on the side spliced pole and be used for to gear motor 403 provides direct current's battery 404 for the drive. The rolling drive unit 4 further includes two connecting gears 405 disposed at the side positions of the pinch rollers 402, and a fixed gear 406 disposed at a side of the U-shaped mount 401 other than the side where the reduction motor 403 is disposed and engaged with the connecting gears 405.

In this embodiment, the pressing wheel 402 is a rubber wheel with a large friction coefficient, the reduction motor 403 drives the pressing wheel 402 to rotate through the connecting gear 405, and the fixed gear 406 is used for ensuring the rotating effectiveness of the pressing wheel 402 on the other side, so as to prevent the pressing wheel 402 from generating a slight centrifugal rotation.

The resistance adjusting unit 5 includes an installation beam 501 disposed on the side connection column provided with the decelerating motor 403, a thermistor 502 sleeved on the installation beam 501 and used for adjusting the current and the magnetic field of the annular electromagnet 302 by adjusting the distance between the decelerating motor 403 which generates heat, a position adjusting part 503 disposed on the installation beam 501 and used for controlling the distance between the thermistor 502 and the decelerating motor 403 by adjusting the size of both elastic jacking and magnetic repulsion, and a sliding rheostat 504 disposed on the side connection column and connected with the driving battery 404 through a lead and used for adjusting the magnitude of the current of the electromagnet in the position adjusting part 503. The mounting beam 501 is parallel to the long axial direction of the speed reducing motor 403 with the side surface being bonded and arranged on the side connecting column, and the thermistor 502 is bonded and arranged on the lower surface of the position adjusting part 503 close to the speed reducing motor 403. The thermistor 502 is a positive temperature coefficient thermistor. The driving battery 404, the sliding resistor 504, and the reduction motor 403 are respectively disposed on both side surfaces of the side connection post.

In this embodiment, when the pressing wheel 402 requires a large driving force, the height of the plate 201 needs to be partially adjusted downward, the attraction force of the annular electromagnet 302 to the permanent magnet ring 301 needs to be reduced, the current on the annular electromagnet 302 needs to be reduced, and finally, the resistance of the resistance adjusting unit 5 may be increased, or vice versa.

When the thermistor 502 with the ptc characteristic is close to a heat source, i.e., the geared motor 403, the ambient temperature increases, the resistance value increases, and finally the purpose of increasing the stiction driving force of the pinch roller 402 is achieved, so that the position adjusting portion 503 only needs to adjust the thermistor 502 to be close to the geared motor 403, and otherwise, the thermistor is far from the geared motor 403.

The position adjusting portion 503 comprises a sliding ring 503a sleeved on the mounting beam 501 and used for setting the thermistor 502, a limiting plate 503b arranged at the end position of the mounting beam 501, a jacking spring 503c sleeved on the mounting beam 501 and used for jacking the sliding ring 503a on the limiting plate 503b, a second electromagnet 503d sleeved on the mounting beam 501 and bonded on the side connecting column, and a second permanent magnet ring 503e bonded on the annular side surface of the sliding ring 503a close to the second electromagnet 503d and used for forming a repulsive magnetic field between the second electromagnet 503 d.

In this embodiment, the jacking spring 503c always provides a pushing elastic force to the sliding ring 503a, the second electromagnet 503d forms a repulsive magnetic force with the second permanent magnet ring 503e through the sliding rheostat 504 and the driving battery 404, and also provides a pushing repulsive force to the sliding ring 503a, and the magnitude of the two forces is the key of adjusting the position of the sliding ring 503a, so as to finally make the heat transfer distance between the thermistor 502 and the decelerating motor 403 flexibly adjustable, and ensure that the magnitude of the attractive magnetic force on the ring electromagnet 302 flexibly adjustable, for example, after the resistance value of the access circuit is reduced by the sliding rheostat 504, the current on the second electromagnet 503d increases and the repulsive magnetic force increases, the jacking spring 503c is further compressed, and the sliding ring 503a carries the thermistor 502 away from the decelerating motor 403 which generates heat, the temperature of the environment where the thermistor 502 is located is reduced, the resistance is reduced, the current and the attractive magnetic force of the annular electromagnet 302 are increased, the plate body 201 is lifted upwards by a partial distance, the pressure and the static friction force of the pressing wheel 402 are reduced, and the method is finally suitable for the condition that the resistance at the cam mortise structure is small, and when the mortise structure at the cam mortise structure is complex and the resistance is large, the resistance of the slide rheostat 504 is increased through a series of conversion.

In this embodiment, the purpose of adjusting the stiction driving force of the pressing wheel 402 is finally achieved by a sliding resistance adjusting manner of the sliding rheostat 504, so as to avoid a simple height mechanical adjusting manner in reality, ensure that the stiction driving force of the pressing wheel 402 has the advantages of being flexible and effective in adjustment, simple and convenient, and avoid directly moving and adjusting the pressing wheel 402 with a heavy weight.

A forming method of a forming system of an aluminum-manganese alloy layer integrated with a wall surface sequentially comprises the following steps:

s1, extruding the two sides of the aluminum-manganese alloy coiled material onto the wheel mortise structure, and manually pulling the aluminum-manganese alloy coiled material to the position below the rolling driving unit 4;

s2, the roller friction driving structure is opened by electrifying, the static friction driving force is adjusted according to the resistance of the wheel mortise structure, stable driving is guaranteed, and the aluminum-manganese alloy coiled material is less in impression;

and S3, heating the alloy coiled material with the mortises through an infrared heating device, and finishing the forming operation.

In this embodiment, the aluminum-manganese alloy coiled material is firstly inserted into the cam mortise structure, then pulled to the position below the rolling driving unit 4, then pressed by the pressing wheel 402 to be driven by friction, and finally the pressing wheel 402 is opened to perform the operation of automatically opening the mortises at two sides in the rolling and pulling process, so as to ensure the effectiveness of the forming system.

On the other hand, the heating operation is used for ensuring that the problem of incomplete foaming is not easy to occur when the subsequent foaming material is added, and the purpose of heating is to provide a proper temperature environment for the foaming operation.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the above embodiments, and various modifications can be made without departing from the spirit of the present invention within the knowledge of those skilled in the art. These are non-inventive modifications, which are intended to be protected by patent laws within the scope of the appended claims.

Claims (9)

1. The forming system of the aluminium manganese alloy layer of integrated wall includes edging mortise groove district (a) to the aluminium manganese alloy coiled material in proper order to and these two districts of preheating zone (b), be equipped with the mortise edger in edging mortise groove district (a), the mortise edger is including being located the gyro wheel friction drive structure on the aluminium manganese alloy coiled material upper surface, and is located aluminium manganese alloy coiled material both sides just set up the cam mortise groove structure of gyro wheel friction drive structure rear end, its characterized in that: the roller friction driving structure comprises two mounting frames (1) arranged at positions on two sides of a conveying frame (11), mounting plates (2) arranged on the mounting frames (1) are respectively sleeved at two ends of the roller friction driving structure, electromagnet attraction units (3) which are arranged on the mounting frames (1) and the mounting plates (2) and attract lifting modes through magnetic force to adjust the height of the mounting plates (2), rolling driving units (4) which are arranged on the lower surfaces of the mounting plates (2) and are used for improving power for the cam mortise structure through a static friction driving mode, and the resistance adjusting unit (5) is arranged on the rolling driving unit (4) and is used for adjusting the static friction driving force of the rolling driving unit (4) on the aluminum-manganese alloy coiled material by adjusting the resistance and further adjusting the magnetic force mode of the electromagnet attracting unit (3).

2. The forming system of the aluminum-manganese alloy layer of the integrated wall surface of claim 1, wherein: the mounting frame (1) comprises a frame body plate (101), a mounting opening (102) arranged on the frame body plate (101), and a mounting column (103) vertically arranged on the mounting opening (102); the mounting plate (2) comprises a plate body (201) and mounting rings (202) which are arranged at two ends of the plate body (201) and used for sleeving and mounting on the mounting columns (103); the electromagnet attraction unit (3) comprises a permanent magnet ring (301) arranged on the annular upper surface of the mounting ring (202), an annular electromagnet (302) arranged on the inner top surface of the mounting opening (102) and sleeved with the mounting column (103), and a battery (303) for adjusting the plate body (201) on the upper surface and used for providing direct current for the annular electromagnet (302), wherein the battery (303) for adjusting and the annular electromagnet (302) and the resistance adjusting unit (5) are connected in series, and a buffer spring (6) used for upwards jacking the mounting ring (202) is sleeved on the mounting column (103).

3. The forming system of the aluminum-manganese alloy layer of the integrated wall surface of claim 2, wherein: roll drive unit (4) including setting up U type mounting bracket (401) on plate body (201) lower surface, cup joint the setting and be in on the middle part crossbeam of U type mounting bracket (401) and be used for carrying out stiction driven pinch roller (402) on the aluminium manganese alloy coiled material, set up and be in be used for rotary drive on the side spliced pole of U type mounting bracket (401) gear motor (403) of pinch roller (402), and set up and be in on the side spliced pole and be used for to gear motor (403) provide for the drive of direct current battery (404).

4. The forming system of the aluminum-manganese alloy layer of the integrated wall surface of claim 3, wherein: the rolling driving unit (4) further comprises two connecting gears (405) arranged at the side positions of the pinch rollers (402), and a fixed gear (406) which is arranged on one side of the U-shaped mounting frame (401) different from the side where the speed reducing motor (403) is arranged and meshed with the connecting gears (405).

5. The forming system of the aluminum-manganese alloy layer of the integrated wall surface of claim 3, wherein: the resistance adjusting unit (5) comprises an installation beam (501) arranged on the side connecting column provided with the speed reducing motor (403), a thermistor (502) which is sleeved on the installation beam (501) and used for adjusting the current and the magnetic field of the annular electromagnet (302) in a distance adjusting mode with the speed reducing motor (403) generating heat, a position adjusting part (503) which is arranged on the installation beam (501) and used for controlling the distance between the thermistor (502) and the speed reducing motor (403) in a size adjusting mode of elastic jacking and magnetic repulsion, and a sliding rheostat (504) which is arranged on the side connecting column, connected with the driving battery (404) through a lead and used for adjusting the current of the electromagnetic inside the position adjusting part (503).

6. The forming system of the aluminum-manganese alloy layer of the integrated wall surface of claim 5, wherein: the mounting cross beam (501) is parallel to the long axial direction of the speed reducing motor (403) which is arranged on the side connecting column in a bonding mode, and the thermistor (502) is arranged on the lower surface, close to the speed reducing motor (403), of the position adjusting portion (503) in a bonding mode.

7. The forming system of the aluminum-manganese alloy layer of the integrated wall surface of claim 5, wherein: position control portion (503) is including cup jointing the setting and is in be used for setting on installation crossbeam (501) slip ring (503 a) of thermistor (502), the setting is in limiting plate (503 b) of installation crossbeam (501) end position department, cup joint the setting and be in be used for on installation crossbeam (501) and be used for jack-up on limiting plate (503 b) the jack-up spring (503 c) of slip ring (503 a) cup joint the setting and be in on installation crossbeam (501) and the setting of bonding are in second electro-magnet (503 d) on the side connection post, and the setting of bonding is in slip ring (503 a) is close to on the annular side of second electro-magnet (503 d) and be used for with form the second permanent magnet ring (503 e) of repelling magnetic field between second electro-magnet (503 d).

8. The forming system of the aluminum-manganese alloy layer of the integrated wall surface of claim 5, wherein: the thermistor (502) is a positive temperature coefficient thermistor.

9. The forming system of the aluminum-manganese alloy layer of the integrated wall surface of claim 5, wherein: the driving battery (404) and the sliding rheostat (504) and the speed reducing motor (403) are respectively arranged on two side surfaces of the side connecting column.

Images