CN111452481A

CN111452481A - Aluminum substrate foil plate pressing device

Info

Publication number: CN111452481A
Application number: CN202010346897.9A
Authority: CN
Inventors: 陈庆祝
Original assignee: 陈庆祝
Current assignee: SHANXI DINGLONG SMART BUILDING TECHNOLOGY CO.,LTD.
Priority date: 2020-04-28
Filing date: 2020-04-28
Publication date: 2020-07-28
Anticipated expiration: 2040-04-28
Also published as: CN111452481B

Abstract

The invention relates to the field of aluminum substrate production and processing, in particular to an aluminum substrate foil plate pressing device which comprises a positioning table, a feeding assembly for feeding an aluminum substrate, a transmission assembly for feeding a copper foil, a pressing assembly, a discharging transmission belt and four first photoelectric sensors for positioning and pressing the aluminum substrate and the copper foil, wherein the positioning table is arranged between the feeding assembly and the transmission assembly, the feeding direction of the feeding assembly is vertical to the feeding direction of the transmission assembly, the pressing assembly is arranged at the side of the transmission assembly, the four first photoelectric sensors are arranged on the pressing assembly, the positioning table and the transmission assembly are also respectively provided with four second photoelectric sensors corresponding to each first photoelectric sensor, and the feeding assembly comprises a feeding transmission belt. And the production efficiency of the aluminum substrate is improved.

Description

Aluminum substrate foil plate pressing device

Technical Field

The invention relates to the field of aluminum substrate production and processing, in particular to an aluminum substrate foil plate pressing device.

Background

The aluminum substrate is a metal-based copper-clad plate with a good heat dissipation function, a common single-sided plate is composed of three layers, namely a circuit layer (copper foil), an insulating layer and a metal base layer, and is commonly used in L ED lighting products, wherein the front side and the back side are provided, a white side is welded with L ED pins, the other side is in aluminum natural color, the aluminum natural color is generally coated with heat conduction slurry and then is contacted with a heat conduction part, the high-heat-conductivity aluminum substrate is an aluminum substrate with high-end heat conductivity coefficient in the aluminum substrate industry, meanwhile, the product project of the high-heat-conductivity aluminum substrate covers the whole industry of lighting products, such as commercial lighting and indoor lighting, the application range is increasingly large.

The basic technological process includes gluing and stoving one large roll of copper foil, cutting the copper foil into square, cutting the thin aluminum plate into square, pressing the copper foil and the thin aluminum plate together with the glue on the copper foil, cutting and trimming to obtain the aluminum base plate.

Most the structure of the production facility of present high heat conduction aluminium base board is complicated, and manufacturing cost is higher, and shearing, the efficiency is lower in the production and processing technology of pressfitting, often unable pinpoint, the pressfitting of traditional aluminium base board and copper foil is mostly through the direct pressfitting of punching press, can not carry out accurate pressfitting to aluminium base board and copper foil through pinpointing, often can lead to the laminating not accurate like this, however the laminating between aluminium base board and the copper foil that the light path location can be accurate is more perfect, therefore, need design the equipment through the accurate pressfitting of light path location between aluminium base board and the copper foil.

Disclosure of Invention

The technical problem to be solved by the invention is to provide a pressing device for aluminum substrates and foil plates, and the technical scheme solves the problem of inaccurate fitting between the aluminum substrates and the copper foil.

In order to solve the technical problems, the invention provides the following technical scheme:

provides an aluminum substrate foil plate pressing device, which comprises a positioning table, a feeding assembly for feeding an aluminum substrate, a transmission assembly for feeding a copper foil, a pressing assembly, a discharging transmission belt and four first photoelectric sensors for positioning and pressing the aluminum substrate and the copper foil, wherein the positioning table is arranged between the feeding assembly and the transmission assembly, the feeding direction of the feeding assembly is perpendicular to the feeding direction of the transmission assembly, the pressing assembly is arranged beside the transmission assembly, the four first photoelectric sensors are all arranged on the pressing assembly, the discharging transmission belt is arranged on one side, away from the pressing assembly, of the transmission assembly, the positioning table and the transmission assembly are respectively provided with four second photoelectric sensors corresponding to each first photoelectric sensor, the feeding assembly comprises a feeding transmission belt, the feeding transmission belts are arranged on one support in a horizontal state, and the feeding transmission belts are driven by a transmission motor.

As an aluminium base board foil board compression fittings's an preferred scheme, the top of support is equipped with two limiting plates that are used for spacing aluminium base board material loading along the length direction of material loading transmission band, two limiting plates all set up in the top of support through a support frame symmetry, one side that the one end of support is located the location platform still is equipped with a baffle that is used for keeping out aluminium base board removal, and the outside of baffle still is equipped with an inductor that is used for responding to aluminium base board contact baffle, the opposite side of support principle location platform still is equipped with one through a fixed ring is fixed and pushes away the material cylinder, it still is equipped with a push pedal that is used for promoting aluminium base board towards the output of location platform to push away.

As an aluminium base board foil sheet compression fittings's an preferred scheme, the top of location platform is equipped with a draw-in groove that is used for aluminium base board location, the draw-in groove is the opening form towards one side of push pedal, and the open end both sides of draw-in groove still can the pivoted respectively be equipped with an open-close board, every open-close board still all is equipped with a rectangular plate that is used for keeping out the rotation range to the outside, and the bottom of every open-close board all is driven through a rotating electrical machines, every second photoelectric sensor on the location platform still fixes respectively and sets up in four corners at location bench top, and the equal setting towards of transmission end of every second photoelectric sensor on the location platform.

As a preferred scheme of an aluminum substrate foil plate pressing device, the conveying assembly includes a conveying frame, a discharging roller and a receiving roller, a plurality of rollers are disposed on the conveying frame along a length direction, the discharging roller is rotatably disposed on a side of the conveying frame away from the positioning table, the receiving roller is rotatably disposed on a side of the conveying frame close to the positioning table, a limiting roller for limiting is further disposed between the discharging roller and the receiving roller on one side of the discharging roller, the receiving roller is driven by a winding motor, an output end of the winding motor is matched with one end of the receiving roller through a transmission belt and a transmission wheel, and a limiting assembly for preventing conveying from fluctuating is further disposed on the conveying frame between the limiting roller and the receiving roller on one side of the limiting roller.

As an optimized scheme of an aluminum substrate foil plate pressing device, the limiting assembly comprises two pressing mechanisms which are the same in structure and used for pressing copper foils, the two pressing mechanisms are symmetrically arranged at the upper end and the lower end of each copper foil along the height direction of the transmission frame, each pressing mechanism consists of a pressing cylinder and two lifting blocks, the two pressing cylinders are symmetrically arranged at the upper end and the lower end of each copper foil in a horizontal state, each two lifting blocks are fixed at the two ends of the corresponding pressing cylinder respectively, the two sides of each lifting block are provided with sleeving plates respectively, each sleeving plate is sleeved on a round rod respectively, a first spring is sleeved on the round rod between each lifting block and the transmission frame respectively, and the middle of each round rod is provided with a baffle disc respectively.

As an aluminium base board foil plate compression fittings's an preferred scheme, transmission frame between spacing subassembly and the receipts feed roller is located the below of copper foil and still is equipped with a buffer gear, and four second photoelectric sensor on the transmission subassembly all set up on the transmission frame of buffer gear top, interval between per two second photoelectric sensor is the same, buffer gear comprises a buffer board, the bottom of buffer board is vertical all around to be equipped with four pegs graft poles downwards, the buffer board still sets up in a casing, and still be equipped with a hollow post of pegging graft with corresponding peg graft pole around the inboard top of casing respectively, it is equipped with a second spring still all to fix the cover on four peg graft poles between the bottom of buffer board and the inboard top of casing.

As an optimal scheme of an aluminum substrate foil plate pressing device, the pressing assembly comprises a Y-direction moving mechanism, a Z-direction moving mechanism, a telescopic mechanism and a pressing cylinder, the Y-direction moving mechanism is arranged at the top of a high frame body, the Z-direction moving mechanism is arranged on the Y-direction moving mechanism, the telescopic mechanism is arranged on the Z-direction moving mechanism, the pressing cylinder is arranged at one end of the telescopic mechanism, the Y-direction moving mechanism is composed of a first sliding groove and a first sliding block, the first sliding groove is arranged at the top of the high frame body in a horizontal state along the length direction of a transmission frame, a first screw rod is arranged in the first sliding groove along the length direction, the first sliding block is sleeved on the first screw rod, and the first screw rod is further driven by a first driving motor.

As an aluminium base board foil board compression fittings's an preferred scheme, Z is to moving mechanism by a second spout, a second slider and a major axis cylinder are constituteed, the outside end of first slider is equipped with an installation department that is used for installing the second spout, the second spout is vertical state and is fixed in on the first slider, the second slider slides and sets up in the second spout, the major axis cylinder is vertical state and sets up in the top of second spout, and one side fixed connection of second spout and second slider is passed to the output of major axis cylinder, the outside end of second slider still is equipped with a mounting panel that is used for installing telescopic machanism.

As an aluminium base board foil board compression fittings's an preferred scheme, telescopic machanism comprises a rectangle box and a arm, the rectangle box is the horizontal state and is fixed in one side of mounting panel, the arm activity sets up in the rectangle box, and still the symmetry is articulated to be equipped with two electronic gas poles between the top of rectangle box to the outside and the second spout top, the top and the both sides of rectangle box are equipped with a second screw rod and two guide bars along length direction respectively, and the top of arm and both sides end all locate on second screw rod and two guide bars through a cup joint ring cover, the second screw rod still drives through a second driving motor, still through belt and band pulley cooperation between the output of second driving motor and the one end of second screw rod, the outside of arm still is equipped with a folded plate that is used for installing the air cylinder that pushes down.

As an aluminium base board foil board compression fittings's an preferred scheme, it is fixed in the top of folded plate to push down the cylinder and be vertical state, it stretches out downwards to push down the output shaft of cylinder to pass the folded plate, and the output of pushing down the cylinder still is equipped with a clamp plate, the top both sides of clamp plate still all vertically upwards pass the folded plate and be equipped with two stabilizer bars, the bottom of clamp plate still evenly distributed all around is equipped with four sucking discs that are used for absorbing aluminium base board, the bottom of folded plate still is equipped with a square board, the corner all around of square board still all is equipped with a collar that is used for installing every first photoelectric sensor, every first photoelectric sensor's output all sets up downwards in corresponding collar, and four first photoelectric sensors respectively with relative setting between four second photoelectric sensors on fixed position platform and the transmission assembly.

Compared with the prior art, the invention has the beneficial effects that:

an operator firstly places a plurality of aluminum substrates on a feeding conveying belt, a transmission motor drives the feeding conveying belt to transmit, the aluminum substrates are transmitted through the feeding conveying belt, then the aluminum substrates come to a positioning table, a copper foil is transmitted through a transmission assembly, after the pressing assembly comes above the aluminum substrates of the positioning table, four E L130 first photoelectric sensors on the pressing assembly correspond to four E L130 second photoelectric sensors on the positioning table, the pressing assembly then accurately grabs the aluminum substrates on the positioning table, the pressing assembly then drives the aluminum substrates to drive the copper foil to be above, then the four E L130 first photoelectric sensors on the pressing assembly correspond to the four E L130 second photoelectric sensors on the transmission assembly to be accurately positioned, the pressing assembly presses the aluminum substrates to the copper foil, the copper foil is pressed onto the aluminum substrates, and finally the aluminum substrates are conveyed out through a discharging conveying belt after processing is completed.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic perspective view of the feeding assembly;

FIG. 3 is a schematic perspective view of a positioning table;

FIG. 4 is a front view of the positioning table;

FIG. 5 is a perspective view of the transmission assembly;

FIG. 6 is a schematic perspective view of a position-limiting assembly;

FIG. 7 is a perspective view of the buffering mechanism;

FIG. 8 is a front view of the cushioning mechanism;

FIG. 9 is a perspective view of the pressing assembly;

figure 10 is a front view of the compression assembly.

The reference numbers in the figures are: the device comprises a positioning table 1, an aluminum substrate 2, a copper foil 3, a discharge conveyor belt 4, a first photoelectric sensor 5, a second photoelectric sensor 6, a feeding conveyor belt 7, a support 8, a transmission motor 9, a limit plate 10, a baffle 11, a sensor 12, a material pushing cylinder 13, a push plate 14, a clamping groove 15, an opening plate 16, a rectangular plate 17, a rotating motor 18, a transmission frame 19, a material discharging roller 20, a material receiving roller 21, a roller 22, a limit roller 23, a winding motor 24, a transmission belt 25, a pressing cylinder 26, a lifting block 27, a sleeving plate 28, a round rod 29, a first spring 30, a baffle disc 31, a buffer plate 32, a plugging rod 33, a shell 34, a hollow column 35, a second spring 36, a pressing cylinder 37, an elevated frame body 38, a first chute 39, a first slide block 40, a first screw 41, a first driving motor 42, a second chute 43, a second slide block 44, a long shaft cylinder 45, a mounting part 46, a mounting plate 47, a rectangular box 48, a, The device comprises a mechanical arm 49, an electric air rod 50, a second screw 51, a guide rod 52, a socket ring 53, a second driving motor 54, a belt 55, a folded plate 56, a pressing plate 57, a stabilizing rod 58, a suction cup 59, a square plate 60 and a mounting ring 61.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Referring to fig. 1 to 10, an aluminum substrate foil plate laminating device includes a positioning table 1, a feeding assembly for feeding an aluminum substrate 2, a transmission assembly for feeding a copper foil 3, a laminating assembly, a discharging transmission belt 4, and four first photoelectric sensors 5 for positioning and laminating between the aluminum substrate 2 and the copper foil 3, the positioning table 1 is disposed between the feeding assembly and the transmission assembly, a feeding direction of the feeding assembly is perpendicular to a feeding direction of the transmission assembly, the laminating assembly is disposed beside the transmission assembly, the four first photoelectric sensors 5 are disposed on the laminating assembly, the discharging transmission belt 4 is disposed on a side of the transmission assembly away from the laminating assembly, the positioning table 1 and the transmission assembly are further provided with four second photoelectric sensors 6 corresponding to each first photoelectric sensor 5, the feeding assembly includes a feeding transmission belt 7, the feeding transmission belt 7 is disposed on a support 8 in a horizontal state, the feeding transmission belt 7 is driven by a transmission motor 9, an operator first places a plurality of the feeding belts 2 on the feeding transmission belt 7, the feeding belt 7 drives the feeding belt 7 to pass through the feeding transmission belt 7, the feeding assembly, the feeding belt 7, the feeding assembly passes through the feeding assembly, the feeding assembly is positioned by the photoelectric sensors, the feeding assembly is accurately, the photoelectric sensors, the feeding assembly is carried out, the photoelectric sensors, the feeding assembly, the photoelectric sensors are connected with the photoelectric sensors, the photoelectric sensors are disposed on the photoelectric sensors, the photoelectric sensors are 366, the photoelectric sensors, the.

The top of support 8 is equipped with two limiting plates 10 that are used for spacing aluminium base board 2 material loading along the length direction of material loading transmission band 7, two limiting plates 10 all set up in the top of support 8 through a support frame symmetry, one side that the one end of support 8 is located location platform 1 still is equipped with one and is used for keeping out baffle 11 that aluminium base board 2 removed, and baffle 11 still is equipped with an inductor 12 that is used for responding to aluminium base board 2 contact baffle 11 to the outside, the opposite side of support 8 principle location platform 1 still is equipped with one through a solid fixed ring is fixed and is pushed away material cylinder 13, it still is equipped with a push pedal 14 that is used for promoting aluminium base board 2 towards the output of location platform 1 to push. An operator firstly places a plurality of aluminum substrates 2 on a feeding conveying belt 7, a driving motor 9 drives the feeding conveying belt 7 to drive, the aluminum substrates 2 are conveyed through the feeding conveying belt 7, the aluminum substrates 2 are limited through two limiting plates 10 during conveying, then the aluminum substrates 2 are abutted through a baffle plate 11, a sensor 12 senses the aluminum substrates 2 and then controls the feeding conveying belt 7 to stop conveying, and a material pushing cylinder 13 then pushes the aluminum substrates 2 into a positioning table 1 through a pushing plate 14.

The top of the positioning table 1 is provided with a clamping groove 15 for positioning the aluminum substrate 2, one side of the clamping groove 15 facing the push plate 14 is in an open shape, two sides of an opening end of the clamping groove 15 are respectively provided with a cut-off plate 16 in a rotatable manner, the outward side of each cut-off plate 16 is also provided with a rectangular plate 17 used for resisting a rotation range, the bottom end of each cut-off plate 16 is driven by a rotating motor 18, each second photoelectric sensor 6 on the positioning table 1 is fixedly arranged at four corners of the top of the positioning table 1, and an emitting end of each second photoelectric sensor 6 on the positioning table 1 faces towards the position.

The conveying assembly comprises a conveying frame 19, a discharging roller 20 and a receiving roller 21, a plurality of rollers 22 are arranged on the conveying frame 19 along the length direction, the discharging roller 20 is rotatably arranged on one side of the conveying frame 19 far away from the positioning table 1, the receiving roller 21 is rotatably arranged on one side of the conveying frame 19 close to the positioning table 1, a limiting roller 23 for limiting is further arranged between the discharging roller 20 and the receiving roller 21 on one side of the discharging roller 20, the receiving roller 21 is driven by a winding motor 24, an output end of the winding motor 24 is matched with one end of the receiving roller 21 through a driving belt 25 and a driving wheel, and a limiting assembly for preventing the copper foil 3 from rolling during conveying is further arranged on the conveying frame 19 between the limiting roller 23 and the receiving roller 21 on one side of the limiting roller 23. When the transmission assembly conveys the copper foil 3, one end of the copper foil 3 is wound by the discharge roller 20, the free end of the copper foil 3 is wound by the receiving roller 21, then the winding motor 24 is driven to the winding roller by the transmission belt 25 to rotate, the copper foil 3 can be transmitted on the plurality of rollers 22, the limiting roller 23 plays a primary limiting role on the copper foil 3, the limiting assembly plays a further limiting role on the transmission of the copper foil 3, and the copper foil 3 is prevented from fluctuating in the transmission process.

Spacing subassembly includes that two structures are the same and be used for compressing tightly the hold-down mechanism of copper foil 3 and constitute, two hold-down mechanisms set up in the upper and lower end of copper foil 3 along the direction of height symmetry of transmission frame 19, and every hold-down mechanism comprises a clamping cylinder 26 and two elevator 27, two clamping cylinders 26 all are the horizontal state symmetry and set up in the upper and lower both ends of copper foil 3, every two elevator 27 are fixed in the both ends of corresponding clamping cylinder 26 respectively, and the both sides of every elevator 27 still are equipped with a socket board 28 respectively, every socket board 28 still overlaps respectively and locates on a round bar 29, still overlap respectively on the round bar 29 between every elevator 27 and the transmission frame 19 and be equipped with a first spring 30, and the middle part of every round bar 29 still is equipped with a fender dish 31 respectively. When spacing subassembly carries on spacingly to copper foil 3, two hold-down mechanism carry on spacingly with copper foil 3 respectively, and operating personnel dials two elevator 27 outwards, and copper foil 3 passes between two clamping cylinders 26, loosens two elevator 27 after that, because all be equipped with a first spring 30 on two round bars 29 that the bell and spigot joint board 28 cover of every elevator 27 both sides was established, consequently, two elevator 27 compress tightly copper foil 3 along with it, have played further spacing effect to it.

The transmission frame 19 between the limiting assembly and the material receiving roller 21 is also provided with a buffer mechanism below the copper foil 3, the four second photoelectric sensors 6 on the transmission assembly are all arranged on the transmission frame 19 above the buffer mechanism, the distance between every two second photoelectric sensors 6 is the same, the buffer mechanism is composed of a buffer plate 32, four insertion rods 33 are vertically arranged on the periphery of the bottom of the buffer plate 32 downwards, the buffer plate 32 is also arranged in a shell 34, hollow columns 35 inserted with the corresponding insertion rods 33 are respectively arranged on the periphery of the top of the inner side of the shell 34, second springs 36 are fixedly sleeved on the four insertion rods 33 between the bottom of the buffer plate 32 and the top of the inner side of the shell 34, when the aluminum substrate 2 is pressed on the aluminum substrate 3 by the pressing assembly, the buffer mechanism plays a buffer effect on the pressing between the aluminum substrate 2 and the copper foil 3, the four E L130 first photoelectric sensors 5 on the pressing assembly correspond to the four E L130 second photoelectric sensors 6 on the transmission frame 19 above the buffer assembly, the aluminum substrate 2 and the buffer plate 32 can be accurately pressed on the aluminum substrate by the copper foil 3, and the buffer plate 32, and the aluminum substrate can be accurately pressed on the buffer plate, and the aluminum substrate, and the buffer plate 32, and the aluminum substrate can be accurately pressed on the aluminum substrate, and accurately pressed by the buffer plate 32, and the buffer plate, and the aluminum substrate, and the buffer plate 32, and the aluminum substrate can be accurately pressed by the buffer plate, and the buffer plate 32, and the buffer plate, and the aluminum substrate.

The pressing assembly comprises a Y-direction moving mechanism, a Z-direction moving mechanism, a telescopic mechanism and a downward pressing air cylinder 37, the Y-direction moving mechanism is arranged at the top of a high frame body 38, the Z-direction moving mechanism is arranged on the Y-direction moving mechanism, the telescopic mechanism is arranged on the Z-direction moving mechanism, the downward pressing air cylinder 37 is arranged at one end of the telescopic mechanism, the Y-direction moving mechanism is composed of a first sliding groove 39 and a first sliding block 40, the first sliding groove 39 is arranged at the top of the high frame body 38 in a horizontal state along the length direction of the transmission frame 19, a first screw rod 41 is arranged in the first sliding groove 39 along the length direction, the first sliding block 40 is sleeved on the first screw rod 41, and the first screw rod 41 is further driven by a first driving motor 42. When the stitching assembly is driven, the pressing cylinder 37 moves through the Y-direction moving mechanism, the Z-direction moving mechanism and the telescoping mechanism, when the pressing cylinder 37 moves through the Y-direction moving mechanism, the first driving motor 42 drives the first screw rod 41 to rotate, the first sliding block 40 moves in the first sliding groove 39 through the first screw rod 41, and the Z-direction moving mechanism moves through the first sliding block 40.

The Z-direction moving mechanism is composed of a second sliding chute 43, a second sliding block 44 and a long shaft cylinder 45, an installation part 46 for installing the second sliding chute 43 is arranged at the outward end of the first sliding block 40, the second sliding chute 43 is fixed on the first sliding block 40 in a vertical state, the second sliding block 44 is arranged in the second sliding chute 43 in a sliding manner, the long shaft cylinder 45 is arranged at the top end of the second sliding chute 43 in a vertical state, the output end of the long shaft cylinder 45 penetrates through one side of the second sliding chute 43 and the second sliding block 44 to be fixedly connected, and an installation plate 47 for installing the telescopic mechanism is further arranged at the outward end of the second sliding block 44. When the Z-direction moving mechanism is driven, the long axis cylinder 45 pushes the second slider 44 to move in the second sliding slot 43, and the telescopic mechanism can move up and down along with the second slider 44.

The telescopic mechanism is composed of a rectangular box 48 and a mechanical arm 49, the rectangular box 48 is fixed on one side of the mounting plate 47 in a horizontal state, the mechanical arm 49 is movably arranged in the rectangular box 48, two electric air rods 50 are symmetrically hinged between the top outward end of the rectangular box 48 and the top of the second sliding chute 43, a second screw 51 and two guide rods 52 are arranged on the top and two sides of the rectangular box 48 along the length direction respectively, the tail ends of the top and two sides of the mechanical arm 49 are sleeved on the second screw 51 and the two guide rods 52 through a sleeving ring 53, the second screw 51 is driven by a second driving motor 54, the output end of the second driving motor 54 is matched with one end of the second screw 51 through a belt 55 and a belt wheel, and a folded plate 56 used for mounting the downward pressing air cylinder 37 is arranged on the outward end of the mechanical arm 49. When the telescopic mechanism is driven, the second driving motor 54 drives the second screw 51 to rotate, and the mechanical arm 49 is sleeved on the second screw 51 through a sleeving ring 53, so that the mechanical arm 49 moves on the two guide rods 52 through the second screw 51, and the two electric air rods 50 play a role of stably supporting the rectangular box 48, thereby ensuring the stability of the telescopic mechanism during up-and-down movement.

The pressing cylinder 37 is fixed on the top of the folded plate 56 in a vertical state, an output shaft of the pressing cylinder 37 penetrates through the folded plate 56 and extends downwards, a pressing plate 57 is further arranged at an output end of the pressing cylinder 37, two sides of the top of the pressing plate 57 vertically and upwards penetrate through the folded plate 56 and are provided with two stabilizing bars 58, four suckers 59 used for sucking the aluminum substrate 2 are further uniformly distributed around the bottom of the pressing plate 57, a square plate 60 is further arranged at the bottom of the folded plate 56, a mounting ring 61 used for mounting each first photoelectric sensor 5 is further arranged around the square plate 60, the output end of each first photoelectric sensor 5 is downwards arranged in the corresponding mounting ring 61, the four first photoelectric sensors 5 are respectively and oppositely arranged between the positioning table 1 and the four second photoelectric sensors 6 on the transmission assembly, after the pressing cylinder 37 is moved to the upper side of the aluminum substrate 2 on the positioning table 1 through the Z-direction moving mechanism and the Y-direction moving mechanism, the pressing cylinder 37 is moved to the upper side of the aluminum substrate 2 on the positioning table 1, the pressing cylinder 37 is moved towards the pressing plate 57 to the lower side of the aluminum substrate 2, and the aluminum substrate 2 is finally moved to the copper foil 2 after the four E L130 and the aluminum substrate 3 are pressed and the aluminum substrate 2, the aluminum substrate 2 is finally, the aluminum substrate 2 is pressed and the aluminum substrate 2, the aluminum substrate 3, the.

According to the working principle of the invention, an operator firstly places a plurality of aluminum substrates 2 on a feeding conveyor belt 7, a transmission motor 9 drives the feeding conveyor belt 7 to transmit, the plurality of aluminum substrates 2 are transmitted by the feeding conveyor belt 7, the plurality of aluminum substrates 2 are limited by two limiting plates 10 during transmission, the aluminum substrates 2 are abutted by baffles 11, after sensing the aluminum substrates 2, the feeding conveyor belt 7 is controlled to stop transmission, a pushing cylinder 13 pushes the aluminum substrates 2 to a clamping groove 15 on a positioning table 1 through a pushing plate 14, then two opening plates 16 are respectively closed through corresponding rotating motors 18, the aluminum substrates 2 can be accurately positioned in the clamping groove 15, when the transmission assembly transmits the copper foil 3, one end of the copper foil 3 is wound through a discharge roller 20, the free end of the copper foil 3 is wound through a take-up roller 21, then a motor 24 is driven to a take-up roller through a transmission belt 25 to rotate, the copper foil 3 can be transmitted on a plurality of rollers 22, the limiting rod 23 plays a preliminary limiting role for limiting the limiting function for limiting the limiting of limiting a limiting assembly 3, the limiting assembly for conveying the copper foil 3, the limiting assembly for the further feeding of the copper foil 3, the limiting assembly, the aluminum substrate 3 is carried out to pass through a further action, the buffer pressing mechanism 7, the buffer mechanism 7 moves along with a buffer mechanism 7, the buffer mechanism 7 is driven by a buffer mechanism 7, the buffer mechanism 7 is driven by a buffer mechanism, the buffer mechanism 7, the buffer mechanism 7, the buffer mechanism 7, the buffer mechanism 7 is driven by the buffer mechanism 7, the buffer mechanism 7 is driven by the buffer mechanism 7, the buffer mechanism 7, the buffer mechanism 7, the buffer mechanism 7, the buffer mechanism.

Claims

1. An aluminum substrate foil plate pressing device is characterized by comprising a positioning table (1), a feeding assembly for feeding an aluminum substrate (2), a transmission assembly for feeding a copper foil (3), a pressing assembly, a discharging transmission belt (4) and four first photoelectric sensors (5) for positioning and pressing between the aluminum substrate (2) and the copper foil (3), wherein the positioning table (1) is arranged between the feeding assembly and the transmission assembly, the feeding direction of the feeding assembly is perpendicular to the feeding direction of the transmission assembly, the pressing assembly is arranged beside the transmission assembly, the four first photoelectric sensors (5) are all arranged on the pressing assembly, the discharging transmission belt (4) is arranged on one side of the transmission assembly, which is far away from the pressing assembly, the positioning table (1) and the transmission assembly are also provided with four second photoelectric sensors (6) corresponding to each first photoelectric sensor (5), the feeding assembly comprises a feeding transmission belt (7), the feeding transmission belt (7) is arranged on a support (8) in a horizontal state, and the feeding transmission belt (7) is driven by a transmission motor (9).

2. The aluminum substrate foil laminating device according to claim 1, wherein two limiting plates (10) for limiting the feeding of the aluminum substrate (2) are arranged above the support (8) along the length direction of the feeding conveyor belt (7), the two limiting plates (10) are symmetrically arranged at the top of the support (8) through a supporting frame, a baffle (11) for resisting the movement of the aluminum substrate (2) is further arranged at one side of the support (8) on the positioning table (1), and the outside of the baffle (11) is also provided with an inductor (12) for inducing the aluminum substrate (2) to contact the baffle (11), the opposite side of the bracket (8) principle positioning table (1) is also fixedly provided with a material pushing cylinder (13) through a fixing ring, and the output end of the material pushing cylinder (13) facing the positioning table (1) is also provided with a push plate (14) for pushing the aluminum substrate (2).

3. The aluminum substrate foil laminating device as claimed in claim 2, wherein a slot (15) for positioning the aluminum substrate (2) is formed in the top of the positioning table (1), one side of the slot (15) facing the pushing plate (14) is open, an opening plate (16) is rotatably disposed on each of two sides of the open end of the slot (15), a rectangular plate (17) for resisting a rotation range is further disposed on the outward side of each opening plate (16), the bottom end of each opening plate (16) is driven by a rotating motor (18), each second photoelectric sensor (6) on the positioning table (1) is further fixedly disposed at four corners of the top of the positioning table (1), and the emitting end of each second photoelectric sensor (6) on the positioning table (1) faces towards the top.

4. A pressing apparatus for aluminum substrate foil according to claim 3, wherein the conveying assembly includes a conveying frame (19), a discharging roller (20) and a receiving roller (21), the conveying frame (19) has a plurality of rollers (22) along a length direction, the discharging roller (20) is rotatably disposed on the conveying frame (19) at a side away from the positioning table (1), the receiving roller (21) is rotatably disposed on the conveying frame (19) at a side close to the positioning table (1), a limiting roller (23) for limiting is further disposed at a side of the discharging roller (20) between the discharging roller (20) and the receiving roller (21), the receiving roller (21) is further driven by a motor (24), and an output end of the winding motor (24) is further coupled to an end of the receiving roller (21) by a driving belt (25) and a driving wheel, one side of the limit roller (23) is positioned on a transmission frame (19) between the limit roller (23) and the receiving roller (21) and is also provided with a limit component for preventing the copper foil (3) from fluctuating during conveying.

5. The aluminum base plate foil laminating device according to claim 4, wherein the limiting component comprises two pressing mechanisms with the same structure and used for pressing the copper foil (3), the two pressing mechanisms are symmetrically arranged at the upper end and the lower end of the copper foil (3) along the height direction of the transmission frame (19), each pressing mechanism comprises a pressing cylinder (26) and two lifting blocks (27), the two pressing cylinders (26) are symmetrically arranged at the upper end and the lower end of the copper foil (3) in a horizontal state, each two lifting blocks (27) are respectively fixed at the two ends of the corresponding pressing cylinder (26), both sides of each lifting block (27) are respectively provided with a sleeved connection plate (28), each sleeved connection plate (28) is respectively sleeved on a round rod (29), and a first spring (30) is respectively sleeved on the round rod (29) between each lifting block (27) and the transmission frame (19), and the middle part of each round rod (29) is also provided with a baffle disc (31).

6. The aluminum substrate foil laminating apparatus according to claim 5, wherein a buffer mechanism is further disposed below the copper foil (3) on the conveying rack (19) between the limiting assembly and the material receiving roller (21), and the four second photoelectric sensors (6) on the transmission component are all arranged on a transmission frame (19) above the buffer mechanism, the distance between every two second photoelectric sensors (6) is the same, the buffer mechanism is composed of a buffer plate (32), four insertion rods (33) are vertically arranged downwards on the periphery of the bottom of the buffer plate (32), the buffer plate (32) is also arranged in a shell (34), and the periphery of the top of the inner side of the shell (34) is also respectively provided with a hollow column (35) which is connected with the corresponding connecting rod (33) in an inserting way, and the four connecting rods (33) between the bottom of the buffer plate (32) and the top of the inner side of the shell (34) are also fixedly sleeved with a second spring (36).

7. The aluminum substrate foil laminating device according to claim 6, wherein the laminating assembly comprises a Y-direction moving mechanism, a Z-direction moving mechanism, a telescopic mechanism and a pressing cylinder (37), the Y-direction moving mechanism is disposed on the top of a high frame body (38), the Z-direction moving mechanism is disposed on the Y-direction moving mechanism, the telescopic mechanism is disposed on the Z-direction moving mechanism, the pressing cylinder (37) is disposed at one end of the telescopic mechanism, the Y-direction moving mechanism comprises a first sliding chute (39) and a first sliding block (40), the first sliding chute (39) is disposed on the top of the high frame body (38) in a horizontal state along the length direction of the transmission frame (19), a first screw rod (41) is disposed in the first sliding chute (39) along the length direction, and the first sliding block (40) is sleeved on the first screw rod (41), and the first screw (41) is also driven by a first drive motor (42).

8. The aluminum substrate foil laminating device according to claim 7, wherein the Z-direction moving mechanism comprises a second sliding groove (43), a second sliding block (44) and a long axis cylinder (45), an outward end of the first sliding block (40) is provided with an installation portion (46) for installing the second sliding groove (43), the second sliding groove (43) is vertically fixed on the first sliding block (40), the second sliding block (44) is slidably arranged in the second sliding groove (43), the long axis cylinder (45) is vertically arranged at a top end of the second sliding groove (43), an output end of the long axis cylinder (45) penetrates through the second sliding groove (43) to be fixedly connected with one side of the second sliding block (44), and an outward end of the second sliding block (44) is further provided with an installation plate (47) for installing the telescopic mechanism.

9. The aluminum substrate foil laminating device according to claim 8, wherein the telescopic mechanism comprises a rectangular box (48) and a mechanical arm (49), the rectangular box (48) is horizontally fixed on one side of the mounting plate (47), the mechanical arm (49) is movably arranged in the rectangular box (48), two electric air rods (50) are symmetrically hinged between the outward end of the top of the rectangular box (48) and the top of the second sliding chute (43), a second screw (51) and two guide rods (52) are respectively arranged on the top and two sides of the rectangular box (48) along the length direction, the top and two ends of the mechanical arm (49) are respectively sleeved on the second screw (51) and the two guide rods (52) through a sleeving ring (53), the second screw (51) is further driven by a second driving motor (54), the output end of the second driving motor (54) and one end of the second screw (51) are further driven by a belt (55) and a mechanical arm (49) The pulleys cooperate, and the outward end of the mechanical arm (49) is also provided with a folded plate (56) for installing the pressing cylinder (37).

10. The aluminum substrate foil laminating device of claim 9, wherein the pressing cylinder (37) is vertically fixed on the top of the folded plate (56), the output shaft of the pressing cylinder (37) extends downward through the folded plate (56), the output end of the pressing cylinder (37) is further provided with a pressing plate (57), two sides of the top of the pressing plate (57) are further provided with two stabilizing rods (58) vertically and upward through the folded plate (56), four sucking discs (59) for sucking the aluminum substrate (2) are further uniformly distributed around the bottom of the pressing plate (57), the bottom of the folded plate (56) is further provided with a square plate (60), the corners around the square plate (60) are further provided with a mounting ring (61) for mounting each first photoelectric sensor (5), the output end of each first photoelectric sensor (5) is downwardly arranged in the corresponding mounting ring (61), and the four first photoelectric sensors (5) are respectively arranged opposite to the four second photoelectric sensors (6) on the positioning table (1) and the transmission assembly.