CN116673347A - Gap-controllable white copper metal material calendering equipment - Google Patents

Abstract

The invention relates to the technical field of white copper metal material processing equipment, in particular to gap-controllable white copper metal material calendaring equipment, which comprises a frame, wherein one side of the frame is provided with a transmission system, the surface of the transmission system is provided with two rollers which are arranged in the frame, the surface of the roller above the transmission system is provided with a connecting frame fixedly connected with the frame, and the top of the connecting frame is fixedly connected with a roller spacing adjusting system fixedly connected with the frame; through setting up inclination detection device, this inclination detection device can detect unusual at the very first time of roller slope to stop device's operation, with the reduction of roller under the state of slope copper-nickel alloy metal material, this not only reduced the circumstances that follow-up reduction finished product thickness is different, reduced the disability rate of reduction finished product, this also can save the apparatus that is used for detecting reduction finished product planarization simultaneously, reduced copper-nickel alloy metal material's reduction cost.

Description

Gap-controllable white copper metal material calendering equipment

Technical Field

The invention relates to the technical field of white copper metal material processing equipment, in particular to gap-controllable white copper metal material calendaring equipment.

Background

White copper is a copper-based alloy with nickel as a main additive element, is silvery white and has metallic luster, so the name of white copper. Currently, a calender is used for changing the thickness and shape of a cupronickel metal material. At present, a common calender consists of a roller, a frame, a roller spacing adjusting system, a transmission system and the like. The existing metal calender has a certain defect on a calendering device after gap adjustment, and the thickness of the calendered metal is different due to the fact that the upper roller and the lower roller are possibly not parallel during metal pressing.

At present, chinese patent discloses a non-ferrous metal calendaring device with adjustable gap (publication No. CN 216027090U), which is characterized in that a fixed column is arranged to vertically slide in an auxiliary frame, a second scale mark is used for assisting in observing whether the heights of two sides are uniform, then the top of the fixed column is fixed through a bolt rod and a fixed bolt, so that the calendaring gap is stable and cannot incline,

the abrasion of the bearings is unavoidable in the running process of the upper roller and the lower roller, and under the action of external force of the installation and processing positions, the abrasion degree of the bearings at the two ends of the rollers is different, which can cause the problem, and the device ensures that the upper roller is in a leveling state by leveling a fixing frame for installing the upper roller, so that the upper roller and the lower roller can only be ensured to be parallel to each other on a theoretical layer, the upper roller and the lower roller can not be ensured to be parallel in the actual production and use, and the situation that the thickness of the product after the rolling is different still exists.

Disclosure of Invention

The invention aims to solve the problems and provide the gap-controllable white copper metal material rolling equipment, which solves the problems that the upper roller and the lower roller of the existing gap-controllable white copper metal material rolling equipment are difficult to keep parallel and the thickness of the rolled product is easy to be different.

The invention realizes the aim through the following technical scheme that the gap-controllable white copper metal material calendaring device comprises a frame, wherein one side of the frame is provided with a transmission system, the surface of the transmission system is provided with two rollers which are arranged in the frame, the surface of the roller above the transmission system is provided with a connecting frame fixedly connected with the frame, the top of the connecting frame is fixedly connected with a roller spacing adjusting system fixedly connected with the frame, the surface of the connecting frame is provided with a detection system fixedly connected with the frame, and the two rollers are arranged on the inner side of the detection system; wherein, the surface of the roller is provided with two ring grooves; the detection system comprises an inclination detection device fixedly connected to the surface of the connecting frame, four offset detection devices are slidably connected to the surface of the inclination detection device, the other end of each offset detection device is fixedly connected with a connecting device which is slidably connected to the inner wall of the annular groove, the other end of each connecting device is fixedly connected with the connecting frame, and the other end of each connecting device is fixedly connected with the frame.

Preferably, the inclination detection device comprises a light shield and two sliding rails, the light shield is fixedly connected to the surface of the connecting frame, two L-shaped connecting strips are connected to the inside of the light shield in a sliding mode, two ends of each L-shaped connecting strip penetrate through the outside of the light shield, grating holes are formed in the surface of each L-shaped connecting strip, two opposite ends of each L-shaped connecting strip are fixedly connected with a laser emitter and a laser receiver respectively, the output end of each laser emitter, the receiving end of each laser receiver and two grating holes are all located on the same straight line, a controller which is fixedly connected with the light shield is electrically connected between each laser emitter and each laser receiver, one end of each L-shaped connecting strip is fixedly connected with a transmission shaft, two sliding rails are connected to the adjacent two offset detection devices in a sliding mode, two connecting plates are hinged between the sliding frames at the largest relative distance, one ends of each transmission shaft penetrate through all the connecting plates and are connected with the adjacent connecting plates in a rotating mode, two rolling shapes are the closest X-shaped rolling shapes, the rolling shapes can be detected through the inclined rolling device, and the rolling thickness of the rolling device can be reduced, and the rolling thickness of a finished product can be prevented from being detected by the rolling device can be reduced, and the rolling thickness of the rolling device can be reduced.

Preferably, the inner wall fixedly connected with connecting rod of slide rail, adjacent two equal sliding connection of sliding frame is in the surface of connecting rod, two helicla flute has been seted up on the surface of connecting rod, two the spiral direction of helicla flute is opposite, the inner wall sliding connection of helicla flute has the slider with sliding frame fixed connection, this not only can ensure that the inside sliding frame of same slide rail keeps opposite directions or the state of opposite directions motion, and simultaneously when two slide rails do not change the interval, two sliding frames also can be through connecting rod, helicla flute and slider mutual restriction to prevent that the sliding frame from driving the condition of connecting plate horizontal migration, reduced the resistance that the transmission shaft goes up and down.

Preferably, one end fixedly connected with T shape slide bar of slide rail, the equal sliding connection in other both ends of T shape slide bar with adjacent offset detection device fixed connection's guide frame, this can ensure that offset detection device is when being driven the slope by the roller and goes up and down, and offset detection device accessible guide frame drives the vertical lift of T shape slide bar, and then has ensured the probability that two grating holes can successfully misplace to this holistic precision of skew detection device has been improved.

Preferably, the surface fixedly connected with two connecting blocks of L type connecting strip, two the connecting block sets up respectively in the upper and lower both sides of lens hood, fixedly connected with rubber bellows between connecting block and the lens hood, the surface of L type connecting strip is located to the rubber bellows cover, and this can prevent external dust, impurity such as steam from getting into the inside of lens hood along the gap of L type connecting strip and lens hood, has reduced the influence to laser conduction.

Preferably, the deflection detection device comprises an installation box fixedly connected to the surface of the connection device, an installation cavity in annular distribution is formed in the installation box, a pressure sensor is fixedly connected to the vertical inner wall of the installation cavity away from the center point of the installation box, a spring is arranged on the vertical inner wall of the installation cavity away from the center point of the installation box, the spring is always in a compressed state, a guide block is arranged at the other end of the spring, the other end of the guide block penetrates through the installation cavity and extends to the inside of the installation box, a guide hole is formed in the other end of the installation box, a disc in contact with the other end of the guide block is slidingly connected to the inner wall of the installation box, the diameter of disc is greater than the internal diameter of guide hole, the one end fixedly connected with connecting seat of disc, the other end of connecting seat runs through the guide hole and extends to the outside of mounting box, guide frame fixed connection is in the other end of connecting seat, through setting up skew detection device, when a certain roller skew, roller is driving the in-process of skew through connecting device, connecting device supports the partial guide block through mounting box and installation chamber for this guide block triggers pressure sensor, and the controller is the data of record again and pauses the device, further reduced the condition that follow-up calendering finished product thickness is different, has enlarged the whole detection range to the roller abnormal conditions of this detecting system.

Preferably, the protection groove is offered to the one end of guide block, the other end of spring runs through to the inside of protection groove and with the inner wall contact of protection groove, this can avoid the spring to be compressed excessively, has reduced the probability that the spring damaged.

Preferably, the connecting device comprises two semicircular plates which are all in sliding connection with the inner walls of the annular grooves and are adjacent to each other, the two semicircular plates jointly form a whole circle, two ends of each semicircular plate are fixedly connected with threaded sleeves, one of the semicircular plates is provided with a first bolt in threaded connection with the inner wall of each threaded sleeve, the rod part of each first bolt sequentially penetrates through the adjacent threaded sleeves and is in threaded connection with the adjacent threaded sleeves, an installation groove is formed in the inner side of each semicircular plate, a second bolt is inserted into the inner wall of each installation groove, the rod part of each second bolt penetrates through the outer part of each installation groove, one of the rod parts of each second bolt is in threaded connection with the adjacent installation box, each semicircular plate is fixedly connected with the corresponding installation box through the corresponding second bolt, and by means of the arrangement of the connecting device, workers can install the annular grooves in the corresponding specifications only by selecting semicircular plates matched with the annular grooves, the connecting device can be installed in the annular grooves according to the corresponding specifications, the whole detection system can be used, the detection system can be applied to the detection system without the application range of the corresponding detection system, and the detection system can be further expanded according to the detection system.

Preferably, the balls which are uniformly distributed are embedded and installed in the semicircular plate, and the surfaces of the balls penetrate through the semicircular plate and are in sliding connection with the adjacent annular grooves, so that friction force between the semicircular plate and the annular grooves can be reduced, and resistance when the roller rotates is further reduced.

Preferably, the other pole portion fixedly connected with spliced pole of second bolt, the other end sliding connection of spliced pole has the telescopic link, is in the roller top the telescopic link fixed connection is in the inboard of link, is in the roller below the telescopic link fixed connection is in the inboard of frame, this can provide a tractive force for two semicircle boards that make up into whole circle to it is rotatory with the roller to avoid semicircle board follow, in order to ensure that whole detecting system can normal operating.

The beneficial effects of the invention are as follows:

1. by arranging the inclination detection device, the inclination detection device can detect abnormality at the first time of inclination of the roller, and the operation of the device is stopped to prevent the roller from rolling the white copper metal material in an inclined state, so that the situation that the thicknesses of the subsequent rolled finished products are different is reduced, the rejection rate of the rolled finished products is reduced, and meanwhile, an instrument for detecting the flatness of the rolled finished products can be omitted, and the rolling cost of the white copper metal material is reduced;

2. by arranging the offset detection device, when one roller is offset, the roller is driven to offset by the connection device, and the connection device presses part of the guide block through the mounting box and the mounting cavity, so that the guide block triggers the pressure sensor, the controller records data again and pauses the device, the situation that the thickness of the follow-up rolled finished products is different is further reduced, and the detection range of the detection system for the abnormal situation of the roller is enlarged;

3. through setting up connecting device, adopt detachable design, the staff only need select with annular assorted semicircle board just can install in the inside of the annular of corresponding specification for connecting device can install in the annular of different specifications, this holistic application scope that can enlarge this detecting system need not the staff and designs corresponding detecting system according to the specification of roller, and then has enlarged this detecting system's application scope.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic diagram of the connection of a roller to a detection system according to the present invention;

FIG. 3 is a schematic cross-sectional view of a detection system of the present invention;

FIG. 4 is a schematic diagram of the arrangement of the L-shaped connecting bars, the grating holes, the laser transmitters and the laser receivers in the invention;

FIG. 5 is a schematic view of a detection system according to the present invention;

FIG. 6 is a schematic cross-sectional view of a portion of the detection system of the present invention;

FIG. 7 is an enlarged view of A in FIG. 6;

FIG. 8 is a schematic view of an explosion of the detection system of the present invention partially cut away;

FIG. 9 is a schematic diagram of the connection of the tilt sensing apparatus and the connection apparatus to the offset sensing apparatus according to the present invention;

FIG. 10 is a schematic cross-sectional view of an offset detection apparatus according to the present invention;

fig. 11 is an exploded view of the connecting device of the present invention.

In the figure: 1. a frame; 2. a transmission system; 3. a roller; 301. a ring groove; 4. a connecting frame; 5. a roll gap adjusting system; 6. a detection system; 7. inclination detection means; 701. a light shield; 702. an L-shaped connecting strip; 703. a grating hole; 704. a laser emitter; 705. a laser receiver; 706. a controller; 707. a transmission shaft; 708. a slide rail; 709. a sliding frame; 710. a connecting plate; 711. a connecting rod; 712. a spiral groove; 713. a slide block; 714. a T-shaped slide bar; 715. a guide frame; 716. a connecting block; 717. a rubber bellows; 8. an offset detection device; 801. a mounting box; 802. a mounting cavity; 803. a pressure sensor; 804. a spring; 805. a guide block; 806. a guide hole; 807. a disc; 808. a connecting seat; 809. a protection groove; 9. a connecting device; 901. a semicircular plate; 902. a thread sleeve; 903. a first bolt; 904. a mounting groove; 905. a second bolt; 906. a ball; 907. a connecting column; 908. a telescopic rod.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The specific implementation method comprises the following steps: as shown in fig. 1-11, a gap-controllable white copper metal material calendaring device comprises a frame 1, wherein a transmission system 2 is arranged on one side of the frame 1, two rollers 3 which are arranged in the frame 1 are arranged on the surface of the transmission system 2, a connecting frame 4 fixedly connected with the frame 1 is arranged on the surface of the upper roller 3, a roller spacing adjusting system 5 fixedly connected with the frame 1 is fixedly connected to the top of the connecting frame 4, a detection system 6 fixedly connected with the frame 1 is arranged on the surface of the connecting frame 4, and the two rollers 3 are arranged on the inner side of the detection system 6; wherein, the surface of the roller 3 is provided with two ring grooves 301; wherein, detecting system 6 includes the slope detection device 7 of fixed connection in link 4 surface, and the surface sliding connection of slope detection device 7 has four skew detection device 8, and the other end fixedly connected with of skew detection device 8 is connected with connecting device 9 in annular 301 inner wall, and the other end and the link 4 fixed connection of top connecting device 9, the other end and the frame 1 fixed connection of below connecting device 9.

As shown in fig. 2-9, the tilt detection device 7 includes a light shield 701 and two slide rails 708, the light shield 701 is fixedly connected to the surface of the connection frame 4, two L-shaped connection bars 702 are slidably connected inside the light shield 701, two ends of the L-shaped connection bars 702 penetrate through the light shield 701, grating holes 703 are formed in the surface of the L-shaped connection bars 702, opposite ends of the two L-shaped connection bars 702 are respectively fixedly connected with a laser transmitter 704 and a laser receiver 705, an output end of the laser transmitter 704, a receiving end of the laser receiver 705 and the two grating holes 703 are all located on the same straight line, a controller 706 is electrically connected between the laser transmitter 704 and the laser receiver 705 and is fixedly connected with the light shield 701, one end of the L-shaped connection bars 702 is fixedly connected with a transmission shaft 707, the two slide rails 708 are respectively slidably connected between two adjacent offset detection devices 8, two slide frames 709 are slidably connected to the inner wall of the slide rails 708, two slide frames 709 are hinged between the two slide frames 709 at the farthest distance, one end of the transmission shaft penetrates through all the connection plates 710 and is rotatably connected with the laser receiver 705, the two connection plates 710 are rotatably connected with the adjacent connection plates, and the two fork frames 710 are not in the same distance from the nearest two slide frames through the two slide frames, and the two fork frames 710 are in the current well-known technology, and the two fork frames are not in the well known structure, and the space is a well-known structure, and the space is formed by the two fork frames, and the two space is formed by the two space frames, and the space is formed by the frame, and the space between the space is easily; the inner wall of the sliding rail 708 is fixedly connected with a connecting rod 711, two adjacent sliding frames 709 are all connected to the surface of the connecting rod 711 in a sliding manner, two spiral grooves 712 are formed in the surface of the connecting rod 711, the spiral directions of the two spiral grooves 712 are opposite, the inner wall of the spiral groove 712 is connected with a sliding block 713 which is fixedly connected with the sliding frame 709 in a sliding manner { in the process that the sliding rail 708 drives the two sliding frames 709 to lift, the connecting plate 710 drives the two sliding frames 709 with the farthest relative distance to move in the opposite direction or in the opposite direction, the sliding frame 709 drives the sliding block 713 connected with the sliding frame to move, the connecting rod 713 drives the connecting rod 711 to rotate through the spiral groove 712 connected with the sliding frame, and the connecting rod 711 drives the other spiral groove 712 to rotate; one end of the sliding rail 708 is fixedly connected with a T-shaped sliding rod 714, and the other two ends of the T-shaped sliding rod 714 are both in sliding connection with a guide frame 715 fixedly connected with the adjacent offset detection device 8; the surface of the L-shaped connecting strip 702 is fixedly connected with two connecting blocks 716, the two connecting blocks 716 are respectively arranged on the upper side and the lower side of the light shield 701, a rubber corrugated pipe 717 is fixedly connected between the connecting blocks 716 and the light shield 701, and the rubber corrugated pipe 717 is sleeved on the surface of the L-shaped connecting strip 702.

As shown in fig. 8-10, the deflection detecting device 8 comprises a mounting box 801 fixedly connected to the surface of the connecting device 9, a mounting cavity 802 which is annularly distributed is formed in the mounting box 801, a pressure sensor 803 is fixedly connected to the vertical inner wall of the mounting cavity 802 far away from the center point of the mounting box 801, a spring 804 is arranged on the vertical inner wall of the mounting cavity 802 far away from the center point of the mounting box 801, the spring 804 is always in a compressed state, a guide block 805 is arranged at the other end of the spring 804, the other end of the guide block 805 penetrates through the mounting cavity 802 and extends into the mounting box 801, a guide hole 806 is formed at the other end of the mounting box 801, a disc 807 which is contacted with the other end of the guide block 805 is slidingly connected to the inner wall of the mounting box 801, the diameter of the disc 807 is larger than the inner diameter of the guide hole 806, a connecting seat 808 is fixedly connected to one end of the disc 807, the other end of the connecting seat 808 penetrates through the guide hole and extends to the outside of the mounting box 801, the guide frame 715 is fixedly connected to the other end of the connecting seat 808 { when one roller 3 is deflected, the roller 3 drives the semicircular plate 901 to deflect through the annular groove 301, the semicircular plate 901 drives the mounting box 801 to deflect through the second bolt 905, the mounting box 801 drives the guide block 805 to move through the mounting cavity 802, at the moment, part of the guide block 805 is blocked by the circular disc 807 when moving in the direction close to the center point of the mounting box 801, the guide block 805 slides in the corresponding mounting cavity 802 and gradually approaches the pressure sensor 803 after being blocked, when the guide block 805 contacts with the pressure sensor 803, the pressure sensor 803 senses a pressure signal and transmits the pressure signal to the controller 706, and the controller 706 records the data and controls the stop transmission system 2 according to a preset program, so that surrounding workers can check and recall the roller 3 in time; a protection groove 809 is provided at one end of the guide block 805, and the other end of the spring 804 penetrates into the protection groove 809 and contacts the inner wall of the protection groove 809.

As shown in fig. 3, fig. 5, fig. 6, fig. 8, fig. 9 and fig. 11, the connecting device 9 comprises two semicircular plates 901 which are all connected to the inner wall of the adjacent ring groove 301 in a sliding manner, the two semicircular plates 901 form a whole circle together, both ends of each semicircular plate 901 are fixedly connected with threaded sleeves 902, the inner wall of one threaded sleeve 902 is in threaded connection with a first bolt 903, the rod part of the first bolt 903 sequentially penetrates through the adjacent threaded sleeve 902 and the adjacent other threaded sleeve 902 and is in threaded connection with the adjacent other threaded sleeve 902, the inner side of the semicircular plate 901 is provided with a mounting groove 904, the inner wall of the mounting groove 904 is inserted with a second bolt 905, the rod part of the second bolt 905 penetrates to the outer part of the mounting groove 904, the rod part of one second bolt 905 is in threaded connection with the adjacent mounting box 801, the semicircular plate 901 is fixedly connected with the adjacent mounting box 801 through the second bolt 905 { when a worker performs mounting work, the worker takes out eight semicircular plates 901 matched with the annular groove 301, fixedly connects four semicircular plates 901 to one end of a connecting column 907 far away from a telescopic rod 908 through a second bolt 905, fixedly connects the other four semicircular plates 901 to one end of a mounting box 801 far away from a sliding rail 708 through the second bolt 905, penetrates the semicircular plates 901 into the corresponding annular groove 301 and is attached to the interior of the annular groove 301, at the moment, two adjacent semicircular plates 901 form a whole circle together, the worker is in threaded connection with two threaded sleeves 902 at the end parts of the two semicircular plates 901 through a first bolt 903, the two semicircular plates 901 are firmly locked together, at the moment, the semicircular plates 901 limit the sliding rail 708 together with the sliding frame 709, the connecting plate 710 and a transmission shaft 707 between the two rollers 3 through an offset detection device 8, and with the drive shaft 707 at the center point between the two rollers 3; the inner part of the semicircular plate 901 is embedded with evenly distributed balls 906, and the surfaces of the balls 906 penetrate through the semicircular plate 901 and are connected with the adjacent annular grooves 301 in a sliding manner; the other second bolt 905 has a connecting post 907 fixedly connected to the rod portion, the other end of the connecting post 907 is slidably connected with a telescopic rod 908, the telescopic rod 908 above the roller 3 is fixedly connected to the inner side of the connecting frame 4, the telescopic rod 908 below the roller 3 is fixedly connected to the inner side of the frame 1 { when the roller 3 is operating normally, since the semicircular plate 901 is slidably connected to the inner side of the ring groove 301, and the telescopic rod 908 prevents the semicircular plate 901 from rotating along with the ring groove 301 through the connecting post 907, so as to ensure that the whole detection system 6 can operate normally }.

When the invention is used, when one roller 3 tilts, the roller 3 drives the semicircular plate 901 to tilt through the annular groove 301, the semicircular plate 901 is lifted through the offset detection device 8 connected with the semicircular plate 901 through the second bolt 905, the offset detection device 8 drives the guide frame 715 to lift, the guide frame 715 drives the T-shaped slide rod 714 to vertically lift, the T-shaped slide rod 714 drives the slide rail 708 connected with the T-shaped slide rod 714 to lift, the slide rail 708 simultaneously drives the two slide frames 709 in the inner part of the T-shaped slide rod to vertically lift, at the moment, the distance between the two slide frames 709 at the farthest distance changes, at the moment, the two slide frames 709 at the farthest distance are mutually close to or far away from each other under the connection limit of the connecting plate 710, the connecting plate 710 rotates upwards or downwards in the process of the two slide frames 709 at the farthest distance, all the connecting plates 710 cooperate to drive the transmission shaft 707 to move upwards or downwards, the transmission shaft 707 drives the L-shaped connecting bar 702 to move upwards or downwards, the L-shaped connecting bar 702 drives the grating holes 703 and the laser transmitter or the laser receiver 705 connected with the L-shaped slide bar 714 to move upwards or downwards, at the moment, the two grating holes 703 are staggered, at the moment, the transmitting ends of the laser transmitter 704 are close to or the laser receiver 705 to the distance from each other, the two grating holes are controlled by the laser transmitter 704 is controlled by the preset laser receiver holes, the laser receiver 705 is stopped, and the laser receiver 2 can stop the work and the work control program is controlled by a user to stop and can stop the work of the laser receiver system 2 according to the work after the receiving program is recorded by the laser receiver 706. This can detect the abnormality at the first time that roller 3 is inclined to stop the operation of device, this not only reduced the condition that follow-up calendering finished product thickness is different, reduced the disability rate of calendering finished product, this simultaneously also can save the planarization apparatus of calendering finished product, reduced the calendering cost of cupronickel metal material.

It should be noted that, in the above description, the transmission system 2, the roll gap adjustment system 5, the laser transmitter 704, the laser receiver 705, the controller 706 and the controller 706 are relatively mature devices in the prior art, the specific model may be selected according to actual needs, meanwhile, the transmission system 2, the roll gap adjustment system 5, the laser transmitter 704, the laser receiver 705, the controller 706 and the controller 706 may be powered by a built-in power supply, and may also be powered by a commercial power supply, and a specific power supply mode is optionally selected, which is not described herein.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (10)

1. The utility model provides a clearance controllable formula cupronickel metal material calendering equipment, includes frame (1), its characterized in that: one side of the frame (1) is provided with a transmission system (2), two rollers (3) which are arranged inside the frame (1) are arranged on the surface of the transmission system (2), a connecting frame (4) which is fixedly connected with the frame (1) is arranged on the surface of the roller (3) above, a roller spacing adjusting system (5) which is fixedly connected with the frame (1) is fixedly connected to the top of the connecting frame (4), a detection system (6) which is fixedly connected with the frame (1) is arranged on the surface of the connecting frame (4), and the two rollers (3) are arranged on the inner side of the detection system (6);

wherein two ring grooves (301) are formed in the surface of the roller (3);

the detection system (6) comprises an inclination detection device (7) fixedly connected to the surface of the connecting frame (4), four offset detection devices (8) are slidably connected to the surface of the inclination detection device (7), the other end of each offset detection device (8) is fixedly connected with a connecting device (9) slidably connected to the inner wall of the annular groove (301), the other end of each connecting device (9) is fixedly connected with the connecting frame (4), and the other end of each connecting device (9) is fixedly connected with the frame (1).

2. A gap-controllable white copper metal material rolling apparatus as claimed in claim 1, wherein: the tilt detection device (7) comprises a light shield (701) and two slide rails (708), the light shield (701) is fixedly connected to the surface of a connecting frame (4), two L-shaped connecting strips (702) are connected to the inside of the light shield (701) in a sliding manner, two ends of each L-shaped connecting strip (702) penetrate through the outside of the light shield (701), grating holes (703) are formed in the surface of each L-shaped connecting strip (702), a laser emitter (704) and a laser receiver (705) are respectively and fixedly connected to opposite ends of each L-shaped connecting strip (702), the output end of each laser emitter (704), the receiving end of each laser receiver (705) and two grating holes (703) are all positioned on the same straight line, a controller (706) fixedly connected with the light shield (701) is electrically connected between each laser emitter (704) and each laser receiver (705), one end of each L-shaped connecting strip (702) is fixedly connected with a transmission shaft (708), two slide rails (708) are respectively and slidingly connected to two slide frames (709) are connected to two slide frames (709) between two adjacent detection devices (8), one end of the transmission shaft (707) penetrates through all the connecting plates (710) and is in rotary connection with the adjacent connecting plates (710), and the shape of the two connecting plates (710) closest to the connecting plates is X-shaped.

3. A gap-controllable white copper metal material rolling apparatus as claimed in claim 2, wherein: the inner wall fixedly connected with connecting rod (711) of slide rail (708), two adjacent sliding frame (709) all sliding connection in the surface of connecting rod (711), two helicla flute (712) have been seted up on the surface of connecting rod (711), two the spiral direction of helicla flute (712) is opposite, the inner wall sliding connection of helicla flute (712) have slider (713) with sliding frame (709) fixed connection.

4. A gap-controllable white copper metal material rolling apparatus as claimed in claim 2, wherein: one end of the sliding rail (708) is fixedly connected with a T-shaped sliding rod (714), and the other two ends of the T-shaped sliding rod (714) are both connected with guide frames (715) fixedly connected with the adjacent offset detection devices (8) in a sliding manner.

5. A gap-controllable white copper metal material rolling apparatus as claimed in claim 2, wherein: the surface fixing of L type connecting strip (702) is connected with two connecting blocks (716), two connecting blocks (716) set up respectively in the upper and lower both sides of lens hood (701), fixedly connected with rubber bellows (717) between connecting block (716) and lens hood (701), the surface of L type connecting strip (702) is located to rubber bellows (717) cover.

6. A gap-controllable white copper metal material rolling apparatus as claimed in claim 4, wherein: the utility model provides a skew detection device (8) including fixed connection in installation box (801) on connecting device (9) surface, installation cavity (802) that are annular distribution have been seted up to the inside of installation box (801), vertical inner wall fixedly connected with pressure sensor (803) of installation cavity (802) keep away from installation box (801) central point, the vertical inner wall that installation cavity (802) kept away from installation box (801) central point is provided with spring (804), spring (804) are in compressed state all the time, the other end of spring (804) is provided with guide block (805), the inside that installation cavity (802) and extension to installation box (801) were run through to the other end of guide block (805), guide hole (806) have been seted up to the other end of installation box (801), the inner wall sliding connection of installation box (801) has disc (807) with guide block (805) other end contact, the diameter of disc (807) is greater than the internal diameter of guide hole (806), one end fixedly connected with connecting seat (808) of disc (807), other end connecting seat (808) and run through installation box (808) and extend to outside guide seat (808) outside that is connected to guide box (801).

7. A gap-controllable white copper metal material rolling apparatus as claimed in claim 6, wherein: a protection groove (809) is formed in one end of the guide block (805), and the other end of the spring (804) penetrates into the protection groove (809) and is in contact with the inner wall of the protection groove (809).

8. A gap-controllable white copper metal material rolling apparatus as claimed in claim 6, wherein: the connecting device (9) comprises two semicircular plates (901) which are all in sliding connection with the inner walls of the annular grooves (301) and are adjacent to each other, the two semicircular plates (901) jointly form a whole circle, two ends of each semicircular plate (901) are fixedly connected with threaded sleeves (902), one of the threaded sleeves (902) is in threaded connection with a first bolt (903) on the inner wall of each threaded sleeve, the rod of each first bolt (903) sequentially penetrates through the adjacent threaded sleeve (902) and the adjacent other threaded sleeve (902) and is in threaded connection with the adjacent other threaded sleeve (902), a mounting groove (904) is formed in the inner side of each semicircular plate (901), a second bolt (905) is inserted into the inner wall of each mounting groove, the rod of each second bolt (905) penetrates through the outer portion of each mounting groove (904), and one of the rod of each second bolt (905) is in threaded connection with the adjacent mounting box (801), and each semicircular plate (901) is fixedly connected with the adjacent mounting box (801) through the corresponding second bolt (905).

9. A gap-controllable white copper metal material rolling apparatus as claimed in claim 8, wherein: the inside of semicircle board (901) imbeds installs evenly distributed ball (906), the surface of ball (906) runs through semicircle board (901) and with adjacent annular (301) sliding connection.

10. A gap-controllable white copper metal material rolling apparatus as claimed in claim 8, wherein: the other rod part of the second bolt (905) is fixedly connected with a connecting column (907), the other end of the connecting column (907) is slidably connected with a telescopic rod (908), the telescopic rod (908) above the roller (3) is fixedly connected with the inner side of the connecting frame (4), and the telescopic rod (908) below the roller (3) is fixedly connected with the inner side of the frame (1).