CN114798862A

CN114798862A - Processing device for two-way stretching flexible electronic device

Info

Publication number: CN114798862A
Application number: CN202210414271.6A
Authority: CN
Inventors: 陈欣欣
Original assignee: Harbin University
Current assignee: Harbin University
Priority date: 2022-04-20
Filing date: 2022-04-20
Publication date: 2022-07-29
Anticipated expiration: 2042-04-20
Also published as: CN114798862B

Abstract

The invention relates to the field of electronic device processing, in particular to a processing device for a bidirectional stretching flexible electronic device. The utility model provides a processingequipment of biaxial stretching flexible electron device, includes right wheel, lug, recess and left wheel, relative setting about left wheel and the right wheel is the annular on the right wheel and is provided with a plurality of lugs, is the annular on the left wheel and is provided with a plurality of recesses, and a plurality of recesses are corresponding with a plurality of lugs, and the interval between left wheel and the right wheel can be adjusted. The left wheel and the right wheel are connected between the left ends of the two supports in a rotating mode. Flexible electronic devices capable of biaxial stretching can be processed.

Description

Processing device for two-way stretching flexible electronic device

Technical Field

The invention relates to the field of electronic device processing, in particular to a processing device for a two-way stretching flexible electronic device.

Background

Flexible electronics is a new electronic technology for fabricating electronic devices of organic and inorganic materials on flexible substrates. Compared with the traditional electronic device, the flexible electronic device has higher flexibility, can adapt to different working environments to a certain extent, meets the requirement of the deformation of equipment on the extensibility and the flexibility of the flexible electronic device on the basis of not damaging the electronic performance of the flexible electronic device, provides new challenges and requirements for manufacturing materials of circuits, and cannot be used for manufacturing the bidirectional stretching flexible electronic device by the traditional processing device of the flexible electronic device.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention provides the processing device for the bidirectional stretching flexible electronic device, which has the beneficial effect that the bidirectional stretching flexible electronic device can be processed.

The utility model provides a processingequipment of biaxial stretching flexible electron device, includes right wheel, lug, recess and left wheel, relative setting about left wheel and the right wheel is the annular on the right wheel and is provided with a plurality of lugs, is the annular on the left wheel and is provided with a plurality of recesses, and a plurality of recesses are corresponding with a plurality of lugs, and the interval between left wheel and the right wheel can be adjusted.

The left wheel and the right wheel are connected between the left ends of the two supports in a rotating mode.

Still include motor II, motor II drive left wheel rotates.

The motor I drives the right wheel to rotate and drives the motor I to move left and right through the hydraulic cylinder.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a first schematic structural diagram of a processing device for biaxially oriented flexible electronic devices;

FIG. 2 is a schematic structural diagram II of a processing device for biaxially oriented flexible electronic devices;

FIG. 3 is a schematic structural diagram III of a processing device for biaxially oriented flexible electronic devices;

FIG. 4 is a first structural view of the stent;

FIG. 5 is a second schematic structural view of the stent;

FIG. 6 is a schematic structural view of a square bar;

FIG. 7 is a first schematic view of a ring;

FIG. 8 is a second schematic structural view of a ring;

FIG. 9 is a schematic view of the structure of the gantry;

FIG. 10 is a first schematic structural view of a flat block;

fig. 11 is a schematic structural diagram of a flat block.

In the figure: a support 101; a transverse slot 102; a rotating shaft 103; a right wheel 104; a bump 105; a motor I106; a motor II 107; a recess 108; a left wheel 109;

a square bar 201; an elastic rod 202; a middle block 203; a support plate 204; a fastening screw 205; a V-groove rod 206;

a circular ring 301; a tab 302; a traveler 303; a stopper 304; a hinge block 305; a semi-cylinder 306;

a gantry 401; a screw 402; a motor III 403; a motor mount 404; a clamp block 405; a hand screw 406; a swash plate 407; a bar 408;

a flat block 501; a vertical slot 502; a knife groove 503; a cutter 504.

Detailed Description

As shown in fig. 1 to 11, this example solves the problem of the strip material being pressed into a wave shape, which in turn facilitates the stretching of the strip material,

because the processingequipment of biaxial stretching flexible electron device includes right wheel 104, lug 105, recess 108 and left wheel 109, left wheel 109 and right wheel 104 set up relatively, a plurality of lugs 105 are the annular and set up on right wheel 104, a plurality of recesses 108 are the annular and set up on left wheel 109, a plurality of lugs 105 correspond with a plurality of recesses 108 respectively, the interval between left wheel 109 and the right wheel 104 can be adjusted, can place the metal strip raw materials between left wheel 109 and right wheel 104, then adjust the interval between left wheel 109 and the right wheel 104, then drive left wheel 109 and right wheel 104 and rotate in opposite directions, make a plurality of lugs 105 constantly impress the metal strip raw materials in a plurality of recesses 108, and then press the metal strip raw materials into the wave, and then make the metal strip raw materials be convenient for flexible, and do not influence the electric conductivity of metal strip raw materials. After the distance between the left wheel 109 and the right wheel 104 is reduced, the lug 105 can press the metal strip raw material into the groove 108 deeper, so that the amplitude of the wave shape formed by pressing the metal strip raw material is larger.

As shown in fig. 1-11, this example solves the problem of allowing both the left wheel 109 and the right wheel 104 to rotate on both brackets 101,

because processingequipment of biaxial stretching flexible electron device still includes support 101, cross slot 102 and pivot 103, support 101 is provided with two, the right-hand member of support 101 has set up cross slot 102, pivot 103 sets up on right wheel 104, both ends sliding connection is respectively on two cross slots 102 around the pivot 103, rotate between the left end of two supports 101 and connect left wheel 109, and then make left wheel 109 and right wheel 104 all can rotate at two supports 101, and make right wheel 104 remove about through pivot 103, and then adjust the interval between left wheel 109 and the right wheel 104.

As shown in fig. 1-11, this example solves the problem of motor II107 being used to drive the left wheel 109 in rotation,

the processing device for the biaxial tension flexible electronic device also comprises a motor II107, and the motor II107 is used for driving the left wheel 109 to rotate.

As shown in fig. 1-11, this example solves the problem of driving the rotating shaft 103 and the right wheel 104 to move left and right,

because the processing device of the biaxial tension flexible electronic device further comprises a motor I106, the motor I106 is used for driving the right wheel 104 to rotate, and the motor I106 can move left and right and can be driven by a hydraulic cylinder, so that the rotating shaft 103 and the right wheel 104 are driven to move left and right.

As shown in fig. 1-11, this example solves the problem of securing the ring 301 in the desired position,

because the processingequipment of biaxial stretching flexible electron device still includes ring 301, two supports 101 of fixed connection are respectively at the front and back both ends of ring 301 upside, are provided with a plurality of screw jacks on the ring 301, all can insert the screw in a plurality of screw jacks, and then can fix ring 301 in the position that needs.

As shown in fig. 1-11, this example solves the problem of smoothing out a wavy metal strip,

because the processing device of the bidirectional stretching flexible electronic device also comprises the hinged blocks 305 and the semi-cylinders 306, the two hinged blocks 305 are respectively arranged at the left end and the right end of the circular ring 301, the upper parts of the two hinged blocks 305 are respectively hinged with the semi-cylinders 306, the cambered surfaces on the two semi-cylinders 306 are oppositely arranged, the opposite surfaces of the two hinged blocks 305 are respectively provided with the compression springs I, the other ends of the two compression springs I are respectively and fixedly connected at the outer sides of the two semi-cylinders 306, the metal strip raw material pressed into wave shape can move between the two semi-cylinders 306, the two compression springs I respectively provide upward lifting force for the lower ends of the two semi-cylinders 306, so that the lower ends of the two semi-cylinders 306 are mutually extruded, and then the lower ends of the two semicylinders 306 are extruded on the wavy metal strip raw material, and the wavy metal strip is smoothed along with the continuous downward movement of the wavy metal strip raw material.

As shown in fig. 1-11, this example solves the problem of accommodating different amplitude undulations of the metal strip stock,

because the processingequipment of biaxial stretching flexible electron device still includes lug 302, traveller 303 and dog 304, two lugs 302 set up respectively in the left and right sides both ends of ring 301 upside, the outside of two articulated pieces 305 has all fixedly connected traveller 303, two traveller 303 sliding connection respectively is on two lugs 302, two dog 304 fixed connection respectively is in the outer end of two traveller 303, two compression spring II cup joints respectively on two traveller 303, compression spring II is located between lug 302 and the articulated piece 305, two inward power of articulated piece 305 is given respectively to two compression spring II, make two articulated pieces 305 and two semicylinders 306 have the trend of being close to each other all the time, and then make two semicylinders 306 in being close to each other, the lower extreme of two semicylinders 306 upwards lifts, further adapt to different range wavy metal strip raw materials.

As shown in fig. 1-11, this example solves the problem of machining a metal strip into a spring-like body consisting of a wave-shaped metal strip,

because the processing device of the biaxial stretching flexible electronic device further comprises the clamping blocks 405, the hand-screwed screws 406 and the cross bars 408, the two clamping blocks 405 are respectively connected to two ends of the cross bars 408 in a sliding mode, the two hand-screwed screws 406 are respectively connected to the left end and the right end of the cross bars 408 in a threaded mode, the two hand-screwed screws 406 are respectively abutted to the outer sides of the two clamping blocks 405, the cross bars 408 are located on the lower side of the circular ring 301, and the cross bars 408 can rotate by taking the axis of the circular ring 301 as an axis. The two clamping blocks 405 are close to each other to clamp the lower end of the wavy metal strip, then the transverse bar 408 is driven to rotate around the axis of the circular ring 301, and the wavy metal strip is further processed into a spiral shape, so that the wavy metal strip can be further stretched, and the metal strip is a spring-shaped body consisting of the wavy metal strips.

As shown in fig. 1-11, this example solves the problem of making it easier for a corrugated metal strip to enter the space between the two clamping blocks 405 to be clamped,

because the processing device of the biaxial tension flexible electronic device further comprises the inclined plates 407, the two inclined plates 407 are respectively arranged on the upper sides of the two clamping blocks 405, and the two inclined plates 407 are arranged in an inverted eight shape, so that the wavy metal strip can more easily enter the two clamping blocks 405 to be clamped.

As shown in fig. 1-11, this example solves the problem of reworking the corrugated metal strip into a helical configuration,

the processing device for the biaxial stretching flexible electronic device further comprises a screw 402 and a motor III403, the upper end of the screw 402 is fixedly connected to the cross bar 408, the output shaft of the motor III403 is fixedly connected to the lower end of the screw 402, and the motor III403 drives the screw 402 to rotate, so that the cross bar 408 can be driven to rotate by taking the axis of the circular ring 301 as the axis, and the wavy metal strip is processed into a spiral form again.

The processing device of the biaxial stretching flexible electronic device further comprises a door frame 401 and a motor frame 404, the door frame 401 is fixedly connected to the lower side of the circular ring 301, a motor III403 is fixedly connected to the motor frame 404, the motor frame 404 is vertically and slidably connected to the door frame 401, and the screw 402 is matched with the door frame 401 through threads.

As shown in fig. 1 to 11, this example solves the problem that while the motor III403 drives the transverse bar 408 to rotate around the axis of the circular ring 301 to machine the metal bar into a spiral form again, the metal bar is continuously pulled downwards,

the motor III403 drives the screw rod 402 to rotate, and meanwhile, the screw rod 402 can vertically slide relative to the portal 401, at the moment, the motor III403 vertically slides on the portal 401 through the motor frame 404, so that when the motor III403 drives the transverse strip 408 to rotate by taking the axis of the circular ring 301 as an axis to process the metal strip into a spiral form again, the metal strip can be continuously pulled downwards, and the metal strip is pulled down.

The processing device of the bidirectional stretching flexible electronic device further comprises a square rod 201, elastic rods 202, a middle block 203, a supporting plate 204, a fastening screw 205 and a V-shaped groove rod 206, the lower end of the supporting plate 204 is inserted into the support 101 on the front side, the supporting plate 204 can move left and right on the support 101 on the front side, the lower end of the supporting plate 204 is in threaded connection with the fastening screw 205, the fastening screw 205 is pressed on the support 101, the front portion of the square rod 201 is fixedly connected to the upper portion of the supporting plate 204, the middle portion of the square rod 201 is provided with the middle block 203, the two V-shaped groove rods 206 are arranged front and back relatively, the middle portions of the two V-shaped groove rods 206 are respectively in sliding connection with the front end and the back end of the square rod 201, the two V-shaped groove rods 206 are both arranged above the two supports 101, the front end and the back end of the square rod 201 are both fixedly connected with the elastic rods 202, and the other ends of the two elastic rods 202 are respectively and fixedly connected to the two V-shaped groove rods 206.

As shown in fig. 1-11, this example solves the problem of having the metal strip smoothly enter between two V-groove bars 206,

the support plate 204 can move left and right on the support 101, the left and right positions of the support plate 204, the square rod 201 and the two V-shaped groove rods 206 are adjusted, the two elastic rods 202 respectively give inward sliding force to the two V-shaped groove rods 206 along the square rod 201, so that the two V-shaped groove rods 206 always have a tendency of being close to each other, the middle block 203 can prevent the two V-shaped groove rods 206 from being too close to each other, after the left and right positions of the V-shaped groove rods 206 are adjusted, a flat metal strip on the unprocessed side enters the space between the two V-shaped groove rods 206, then the metal strip between the two V-shaped groove rods 206 can enter the space between the right wheel 104 and the left wheel 109 and is pressed into a wave shape, the two V-shaped groove rods 206 can guide the metal strip, and the metal strip can smoothly enter the space between the two V-shaped groove rods 206.

The processing device of the biaxial stretching flexible electronic device further comprises a flat block 501, a vertical groove 502, a cutter groove 503 and a cutter 504, wherein the flat block 501 is fixed in the middle of the upper side of the circular ring 301, the vertical groove 502 is arranged on the flat block 501, the cutter groove 503 is arranged on the right side of the flat block 501, the cutter groove 503 is communicated with the vertical groove 502, the cutter 504 is connected to the flat block 501 in a sliding mode, the cutter 504 can be inserted into the cutter groove 503, and the cutter 504 is driven to move through a hydraulic cylinder.

As shown in fig. 1-11, this example solves the problem of cutting the corrugated metal strip at a specific location,

the wavy metal strip coming down between the right wheel 104 and the left wheel 109 passes through the vertical groove 502, and then the cutter 504 moves into the cutter groove 503 to cut the wavy metal strip at a specific position, and the metal strip passes through the vertical groove 502 and the cutter groove 503 simultaneously to prevent the metal strip from shifting during cutting.

Claims

1. A processing device of a bidirectional stretching flexible electronic device comprises a right wheel (104), a convex block (105), a groove (108) and a left wheel (109), and is characterized in that: the left wheel (109) and the right wheel (104) are oppositely arranged left and right, the right wheel (104) is provided with a plurality of lugs (105) in an annular mode, the left wheel (109) is provided with a plurality of grooves (108) in an annular mode, the grooves (108) are corresponding to the lugs (105), and the distance between the left wheel (109) and the right wheel (104) can be adjusted.

2. The processing device of the biaxially oriented flexible electronic device of claim 1, wherein: the two supports (101) are arranged front and back, the transverse groove (102) is formed in the right portion of each support (101), the rotating shaft (103) is arranged on the right wheel (104), two ends of the rotating shaft (103) are connected to the two transverse grooves (102) in a sliding mode respectively, and the left wheel (109) is connected between the left ends of the two supports (101) in a rotating mode.

3. The processing device of the biaxially oriented flexible electronic device as claimed in claim 2, wherein: the left wheel (109) is driven to rotate by the motor II (107).

4. A device for processing biaxially oriented flexible electronic device according to claim 3, wherein: the device also comprises a motor I (106), wherein the motor I (106) drives the right wheel (104) to rotate, and the motor I (106) is driven to move left and right through a hydraulic cylinder.

5. The processing device of the biaxially oriented flexible electronic device as claimed in claim 2, wherein: the novel bracket is characterized by further comprising a circular ring (301), the lower parts of the two brackets (101) are fixedly connected to the front end and the rear end of the circular ring (301) respectively, and a plurality of screw insertion holes are formed in the circular ring (301).

6. The processing device of the biaxially oriented flexible electronic device according to claim 5, wherein: still including articulated piece (305) and semicylinder (306), both ends all are provided with articulated piece (305) about ring (301), and two semicylinders (306) articulate respectively on two articulated pieces (305), and the cambered surface on two semicylinders (306) sets up relatively, and the inboard of two articulated pieces (305) all is connected with compression spring I, and two compression spring I's the other end difference fixed connection is in the outside of two semicylinders (306).

7. The processing device of the biaxially oriented flexible electronic device according to claim 6, wherein: still include lug (302), traveller (303) and dog (304), the left and right both ends of ring (301) upside all are provided with lug (302), the equal fixedly connected with traveller (303) in the outside of two articulated blocks (305), two traveller (303) are horizontal sliding connection respectively on two lug (302), the equal fixedly connected with dog (304) in outer end of two traveller (303), all cup jointed compression spring II on two traveller (303), compression spring II is located between lug (302) and articulated block (305).

8. The processing device of the biaxially oriented flexible electronic device according to claim 7, wherein: still include clamp splice (405), hand screw (406) and horizontal bar (408), sliding connection has two clamp splices (405) on horizontal bar (408), and the equal threaded connection in both ends has hand screw (406) about horizontal bar (408), and two hand screws (406) push up respectively in the outside of two clamp splices (405), and horizontal bar (408) set up the downside at ring (301), and horizontal bar (408) can use the axis of ring (301) as the rotation of axes.

9. The apparatus of claim 8, wherein: the clamping device further comprises inclined plates (407), and the inclined plates (407) are arranged on the upper sides of the clamping blocks (405).

10. The apparatus of claim 8, wherein: the electric iron core is characterized by further comprising a screw (402) and a motor III (403), the upper end of the screw (402) is fixedly connected to the middle of the lower side of the cross bar (408), and an output shaft of the motor III (403) is fixedly connected to the lower end of the screw (402).