CN214358588U

CN214358588U - FPC lamp strip material loading machine

Info

Publication number: CN214358588U
Application number: CN202022313652.4U
Authority: CN
Inventors: 魏余红; 黄燕荣
Original assignee: Dongguan Kezhuo Robot Co ltd
Current assignee: Guangdong Kezhuo Semiconductor Equipment Co ltd
Priority date: 2020-10-17
Filing date: 2020-10-17
Publication date: 2021-10-08
Anticipated expiration: 2030-10-17

Abstract

The utility model discloses a feeding machine for FPC lamp strips, which comprises a workbench, a control computer, a feeding mechanism, a first transfer mechanism, a positioning mechanism and a second transfer mechanism, wherein the feeding mechanism, the first transfer mechanism, the positioning mechanism and the second transfer mechanism are all arranged on the workbench; the feeding mechanism is used for separating the FPC light bar from the bottom diaphragm; the first transfer mechanism comprises a first CCD sensor and a clamping manipulator; the first CCD sensor is used for acquiring coordinates of the FPC light bar separated from the bottom diaphragm and feeding the coordinates back to the control computer, and the clamping manipulator clamps the FPC light bar according to the coordinates acquired by the first CCD sensor; the positioning mechanism is used for adjusting and positioning the position of the FPC light bar; the second transfer mechanism comprises a multi-axis manipulator; the multi-axis manipulator is used for transferring the FPC light bar positioned in the positioning mechanism out of the machine; the utility model discloses a set up various mechanism joint work, can realize the automatic feeding of FPC lamp strip, had job stabilization and efficient advantage.

Description

FPC lamp strip material loading machine

Technical Field

The utility model relates to a FPC feeding equipment technical field, in particular to FPC lamp strip material loading machine.

Background

At present, the backlight source applied to the display screen of the electronic product is also provided with an LED lamp bead on the top. The LED lamp beads are carried on the FPC to form an FPC lamp strip, the LED lamp beads are electrically connected with the electronic product mainboard through the FPC, and the brightness of the backlight source is adjusted through control of the electronic product mainboard.

In the past, when the degree of automation was relatively low, the enterprise can usually adopt the mode of artifical material loading, and operating personnel adopts the mode of staff to place FPC lamp strip in the FPC assembly machine. In order to improve the efficiency of material loading, the technical personnel of this trade have researched and developed FPC and have got the material tool, and FPC gets the material tool and adopts the principle of negative pressure to adsorb FPC lamp strip to the multiaxis manipulator carries out the automation and gets the material loading in the linkage.

However, the FPC light bar is generally placed on a bottom film for storage, and the bottom film can be loaded only through the steps of transportation, manipulator positioning and material taking jig negative pressure suction, wherein in the step of material taking jig negative pressure suction, the material taking jig directly sucks and transfers the FPC light bar on the bottom film through the driving of the manipulator, and since the bottom film has certain viscosity, the FPC light bar and the bottom film may be adhered in the process of tool suction, which results in inaccurate suction; and after all FPC lamp strips on the bottom membrane are transferred away, the bottom membrane needs to be additionally transferred away, so that the working time of the same manipulator is occupied, and the overall efficiency is slowed down.

Therefore, it is necessary to develop a FPC feeding machine with stable operation and high efficiency to meet the current production requirement.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an FPC lamp strip material loading machine to solve above-mentioned problem.

The utility model discloses a following technical scheme realizes above-mentioned purpose:

a feeding machine for FPC light bars comprises a workbench and a control computer,

the automatic feeding device also comprises a feeding mechanism, a first transfer mechanism, a positioning mechanism and a second transfer mechanism which are all arranged on the workbench;

the feeding mechanism is used for separating the FPC light bar from the bottom diaphragm;

the first transfer mechanism comprises a first CCD sensor and a clamping manipulator; the first CCD sensor is used for acquiring coordinates of the FPC light bar separated from the bottom diaphragm and feeding the coordinates back to the control computer, and the clamping manipulator clamps the FPC light bar according to the coordinates acquired by the first CCD sensor;

the positioning mechanism is used for adjusting and positioning the position of the FPC light bar;

the second transfer mechanism comprises a multi-axis manipulator; the multi-axis manipulator is used for transferring the FPC light bar positioned in the positioning mechanism out of the machine.

Further, the feeding mechanism comprises a feeding frame, a feeding conveying belt, a rubber belt conveying roller, a feeding three-axis sliding rail pair and a first negative pressure sucker; the feeding frame is arranged on the workbench; the feeding conveyer belt is arranged beside the feeding frame; the adhesive tape conveying roller is arranged below the feeding conveying belt and is connected with an adhesive tape conveying motor in a driving way; the feeding three-shaft sliding rail pair is arranged above the feeding frame and the feeding conveying belt; the first negative pressure sucker is arranged on the feeding triaxial slide rail pair.

Furthermore, a feeding frame infrared sensor is arranged at the top in the feeding frame; a material lifting module is arranged beside the feeding frame; the feeding frame infrared sensor is electrically connected with the control computer; the material lifting module is connected with a lifting plate in a sliding manner; the lifting plate extends into the feeding frame.

Furthermore, the feeding three-axis sliding rail pair comprises a feeding X-axis sliding rail pair, a feeding Y-axis sliding rail pair and a feeding Z-axis cylinder which are all driven by an air source; the feeding X-axis sliding rail pair is arranged on the workbench; the feeding Y-axis sliding rail pair is arranged on the feeding X-axis sliding rail pair; the feeding Z-axis cylinder is arranged on the Y-axis sliding rail pair; the first negative pressure sucker is arranged at the output end of the feeding Z-axis sliding rail pair.

Furthermore, the first transfer mechanism also comprises a transfer three-axis slide rail pair and a material infrared sensor; the transfer triaxial slide rail pair comprises a transfer X-axis lead screw slide rail pair, a transfer Y-axis lead screw slide rail pair and a transfer Z-axis cylinder, wherein the transfer X-axis lead screw slide rail pair and the transfer Y-axis lead screw slide rail pair are driven by lead screw motors respectively; the X-axis screw transfer sliding rail pair is arranged on the workbench; the transfer Y-axis lead screw sliding rail pair is arranged on the transfer X-axis lead screw sliding rail pair; the transfer Z-axis cylinder is arranged on the transfer Y-axis lead screw slide rail pair; the clamping manipulator is arranged on the transfer Z-axis cylinder; the material infrared sensor is arranged on the workbench, is electrically connected with the control computer and is used for identifying the separation state of the FPC light bar and the bottom diaphragm.

Furthermore, the positioning mechanism comprises a positioning Y-axis lead screw slide rail pair, a material placing table, a left limiting baffle, a right limiting baffle, a front limiting baffle and a rear limiting baffle; the positioning Y-axis lead screw sliding rail pair is arranged on the workbench and is in driving connection with a motor; the material placing table is connected to the positioning Y-axis lead screw sliding rail pair in a sliding manner; the left and right limiting baffles are respectively arranged on the left and right sides of the material placing table and are in driving connection with left and right limiting cylinders; the front and rear limiting baffles are respectively arranged on the front side and the rear side of the material placing table and are connected with front and rear limiting cylinders in a driving mode.

Further, the second transfer mechanism further comprises a second negative pressure sucker and a second CCD sensor; the second negative pressure sucker is arranged on the output end of the multi-axis manipulator; the second CCD sensor is arranged on the workbench and used for acquiring coordinates of the FPC light bar clamped by the multi-axis manipulator and feeding the coordinates back to the control computer, and the multi-axis manipulator adjusts the position of the FPC light bar according to the coordinates acquired by the second CCD sensor.

Furthermore, the clamping manipulator adopts a pneumatic finger.

Furthermore, the multi-axis manipulator adopts a four-axis SCARA robot.

The utility model has the advantages that the work is stable and the efficiency is high, the utility model can realize the automatic feeding of the FPC lamp strip by arranging the feeding mechanism, the first transfer mechanism, the positioning mechanism and the second transfer mechanism; the single-sided adhesive tape is provided with a feeding mechanism and a first transfer mechanism, traction force is provided by an adhesive tape conveying roller through a single-sided adhesive tape, the single-sided adhesive tape is wound on the surface of a feeding conveying belt for recycling, the FPC lamp strip is stripped, the first transfer mechanism clamps the connecting part of the FPC lamp strip to clamp the whole FPC lamp strip, compared with the mode that the FPC lamp strip is sucked by a sucking disc directly and then a bottom membrane is transferred away, the separation mode can not cause grabbing and running, sticking and pressure explosion of lamp beads, and the bottom membrane is recycled through a single-sided adhesive tape, a manipulator in the feeding mechanism does not need to transfer the bottom membrane away, the working stroke is shortened, and the working efficiency is improved; the second transfer mechanism transfers the clamped FPC lamp to the positioning mechanism for physical contact positioning, and the positioning is accurately realized by mutually pushing and positioning the two groups of limiting blocks, so that the time spent on setting excessive CCD sensors for program calculation is avoided, the cost can be reduced, and the working efficiency is increased; after the positioning is finished, the second transfer mechanism sucks up the FPC light bar, contour coordinates are obtained through the CCD sensor, final fine adjustment is carried out on the contour coordinates and the set coordinates, the FPC light bar is transferred to the FPC light bar assembling machine accurately and finally, the whole process is stable in work and high in efficiency.

Drawings

Fig. 1 is a schematic view of the overall structure of the left side of the present invention;

fig. 2 is a schematic diagram of the overall structure in the right direction of the present invention;

fig. 3 is a schematic structural view of the feeding mechanism of the present invention;

fig. 4 is a schematic structural diagram of a first transfer mechanism of the present invention;

FIG. 5 is an enlarged view of the structure at A in FIG. 1;

fig. 6 is an enlarged schematic view of the structure at B in fig. 4.

1. A connection portion of the FPC light bar; 100. a work table; 200. a feeding mechanism; 210. a feeding frame; 211. a feeding frame infrared sensor; 212. a material lifting module; 213. a lifting plate; 220. a feeding conveyor belt; 230. a tape transport roller; 231. single-sided film; 240. feeding a three-axis sliding rail pair; 241. feeding an X-axis sliding rail pair; 242. feeding Y-axis slide rail pairs; 243. a feeding Z-axis cylinder; 250. a first negative pressure suction cup; 300. a first transfer mechanism; 310. transferring a three-axis sliding rail pair; 311. transferring an X-axis lead screw sliding rail pair; 312. transferring a Y-axis lead screw sliding rail pair; 313. a Z-axis transferring cylinder; 320. clamping the manipulator; 330. a material infrared sensor; 340. a first CCD sensor; 400. a positioning mechanism; 401. a material placing table; 402. a left limit baffle and a right limit baffle; 403. front and rear limit baffles; 404. a left limiting cylinder and a right limiting cylinder; 405. a front and a rear limit cylinders; 406. positioning a space; 407. positioning a Y-axis lead screw slide rail pair; 500. a second transfer mechanism; 510. a multi-axis manipulator; 520. a second negative pressure suction cup; 530. a second CCD sensor.

Detailed Description

In order to make the above objects, features and advantages of the present invention more comprehensible, embodiments of the present invention are described in detail below with reference to the accompanying drawings. It should be noted that the drawings of the present invention are simplified and use non-precise ratios, and are only used for the purpose of facilitating and clearly assisting the description of the embodiments of the present invention.

As shown in fig. 1 to 6, a feeding machine for FPC light bars includes a workbench 100 and a control computer,

the automatic feeding device further comprises a feeding mechanism 200, a first transfer mechanism 300, a positioning mechanism 400 and a second transfer mechanism 500 which are all arranged on the workbench 100;

the feeding mechanism 200 is used for separating the FPC light bar from the bottom film, and comprises a feeding frame 210, a feeding conveyer belt 220, a tape conveyer roller 230, a feeding triaxial slide rail pair 240 and a first negative pressure suction cup 250;

the feeding frame 210 is disposed on the worktable 100; a feeding frame infrared sensor 211 is arranged at the top inside the feeding frame 210; a material lifting module 212 is arranged beside the feeding frame 210; the feeding frame infrared sensor 211 is electrically connected with the control computer; the material lifting module 212 is connected with a lifting plate 213 in a sliding manner; the lifting plate 213 extends into the feeding frame 210; when feeding, a worker puts a bottom membrane in the feeding frame 210, a plurality of FPC light bars are placed on the bottom membrane in an array mode, the material lifting module 212 drives the lifting plate 213 to lift the bottom membrane in the feeding frame 210 one by one until the bottom membrane reaches the feeding frame infrared sensor 211, the stroke distance of the feeding three-axis sliding rail pair 240 can be reduced by the mode, the feeding efficiency is higher, when the feeding frame infrared sensor 211 detects that no material exists, a warning can be sent to remind the worker to add the material, and the material lifting module 212 is controlled to reset to the lowest layer;

the feeding conveyer belt 220 is arranged beside the feeding frame 210; the belt conveying roller 230 is disposed below the feeding conveying belt 220 and is drivingly connected to a belt conveying motor (not shown); the single-sided film 231 is arranged on the adhesive tape conveying roller 230, the single-sided film 231 provides traction force through the adhesive tape conveying roller 230 and is wound on the surface of the feeding conveying belt 220 for recovery, one side, with viscosity, of the single-sided film 231 faces upwards, a bottom film can be adhered in the recovery process for recovery, and the FPC lamp strip can be stripped in the process that the foremost end of the conveying belt is recovered along the single-sided film 231 and waits for the first transfer mechanism 300 to clamp; compared with the traditional mode that the FPC light bar is adsorbed by the negative pressure sucker and then the bottom diaphragm is adsorbed on the waste material groove, the recovery mode of the bottom diaphragm can reduce the stroke workload of the sliding rail pair carried by the negative pressure sucker and accelerate the working efficiency;

the feeding three-axis sliding rail pair 240 is arranged above the feeding frame 210 and the feeding conveyor belt 220 and comprises a feeding X-axis sliding rail pair 241, a feeding Y-axis sliding rail pair 242 and a feeding Z-axis cylinder 243 which are driven by air sources; the feeding X-axis sliding rail pair 241 is arranged on the workbench 100; the feeding Y-axis slide rail pair 242 is arranged on the feeding X-axis slide rail pair 241; the feeding Z-axis cylinder 243 is arranged on the Y-axis slide rail pair; the first negative pressure sucker 250 is arranged at the output end of the feeding Z-axis slide rail pair; the first negative pressure suction cup 250 is linked with the feeding X-axis slide rail pair 241, the feeding Y-axis slide rail pair 242 and the feeding Z-axis cylinder 243 to transfer the bottom membrane in the feeding frame 210 to the feeding conveying belt 220;

the first transfer mechanism 300 comprises a transfer three-axis slide rail pair 310, a clamping manipulator 320, a material infrared sensor 330 and a first CCD sensor 340; the transfer triaxial slide rail pair 310 comprises a transfer X-axis lead screw slide rail pair 311, a transfer Y-axis lead screw slide rail pair 312 and a transfer Z-axis cylinder 313, wherein the transfer X-axis lead screw slide rail pair, the transfer Y-axis lead screw slide rail pair 312 and the transfer Z-axis cylinder are driven by a lead screw motor; the X-axis screw transfer slide rail pair 311 is arranged on the workbench 100; the transfer Y-axis lead screw slide rail pair 312 is arranged on the transfer X-axis lead screw slide rail pair 311; the transfer Z-axis cylinder 313 is arranged on the transfer Y-axis lead screw slide rail pair 312; the clamping manipulator 320 is a pneumatic finger and is arranged on the transfer Z-axis cylinder 313, and the clamping manipulator 320 clamps the FPC light bar according to the coordinates acquired by the first CCD sensor 340; the material infrared sensor 330 is arranged on the workbench 100, is electrically connected with the control computer, and is used for identifying the separation state of the FPC light bar and the bottom membrane; the first CCD sensor 340 is used for acquiring coordinates of the FPC light bar separated from the bottom diaphragm and feeding the coordinates back to the control computer; when the FPC light bar is peeled off from the bottom membrane to the front end of the feeding conveyor belt 220 during operation, the FPC light bar is identified by the material infrared sensor 330, the material infrared sensor 330 sends a signal to a control computer so as to control the belt conveyor roller 230 to pause and operate, then the first CCD sensor 340 acquires coordinates of the connecting part 1 of the FPC light bar, as shown in an X amplification part, the clamping manipulator 320 transfers the three-axis slide rail pair 310 in a linkage manner to acquire the coordinates according to the first CCD sensor 340, clamp the connecting part 1 of the FPC light bar and shift to set adsorption coordinates; the first CCD sensor 340 used for acquiring coordinates of the connecting part 1 of the FPC light bar is arranged, the clamping manipulator 320 is linked for clamping, the transfer can be carried out in a mode of not damaging the FPC light bar, the mode of clamping the connecting part 1 of the FPC light bar is compared with the mode of directly sucking the FPC light bar on the bottom membrane by adopting a negative pressure sucker in the past, the transfer mode utilizes the mode that adhesive paper slides to separate the FPC light bar on the bottom membrane, and the combination of a pneumatic finger and the CCD sensor is used, the connecting part of the FPC light bar is positioned for clamping, the problems of adhesion and inaccurate absorption caused by the direct absorption of the negative pressure sucker in the past are avoided, and the risk of clamping and exploding the lamp beads is avoided;

the positioning mechanism 400 is used for adjusting and positioning the position of the FPC light bar; the positioning mechanism 400 comprises a positioning Y-axis lead screw slide rail pair 407, a material placing table 401, a left limiting baffle 402, a right limiting baffle 402 and a front limiting baffle 403 and a rear limiting baffle 403; the positioning Y-axis lead screw slide rail pair 407 is arranged on the workbench 100 and is in driving connection with a lead screw motor; the material placing table 401 is connected to the positioning Y-axis lead screw slide rail pair 407 in a sliding manner; the left and right limiting baffles 402 are respectively arranged at the left and right sides of the material placing table 401 and are in driving connection with left and right limiting cylinders 404; the front and rear limit baffles 403 are respectively arranged on the front and rear sides of the material placing table 401 and are connected with a front and rear limit cylinder 405 in a driving manner; when the front and rear limiting cylinders 405 and the left and right limiting cylinders 404 are driven to have full strokes, a positioning space 406 is defined between the left and right limiting baffles 402 and the front and rear limiting baffles 403, and four sides of the positioning space 406 are perpendicular to each other and fit with the FPC light bar; after the FPC light bar is clamped by the clamping manipulator 320, the material placing table 401 is driven by the Y-axis lead screw sliding rail pair 407 to slide to a position below a set adsorption coordinate, then the clamping manipulator 320 is loosened, the FPC light bar is transferred to the material placing table 401, then the material placing table 401 is reset to an initial position, the left limiting cylinder 404, the right limiting cylinder 404, the front limiting cylinder 405, the left limiting cylinder and the rear limiting cylinder 405 respectively drive the left limiting baffle 402, the right limiting baffle 403, the front limiting baffle 403 and the rear limiting baffle 403 to simultaneously approach the center of the material placing table 401, and the FPC light bar is pushed until the FPC light bar is pushed to the set position of the center; because the FPC lamp strips are laid on the bottom membrane in an array mode for storage, the positions of the FPC lamp strips are different, after the clamping manipulator 320 clamps the FPC lamp strips, unpredictable deviation can occur due to certain adhesive force of the bottom membrane, and if an extra CCD sensor is adopted for comparison operation adjustment, too long time can be spent, so that physical contact positioning can be conducted through the positioning mechanism 400, positioning is fast and accurate, time spent on program calculation due to the fact that too many CCD sensors are arranged is avoided, cost can be reduced, and working efficiency is improved;

the second transfer mechanism 500 comprises a multi-axis manipulator 510, a second negative pressure sucker 520 and a second CCD sensor 530; the multi-axis manipulator 510 is a four-axis SCARA robot, and is used for transferring the FPC light bar positioned in the positioning mechanism 400 out of the machine; the second negative pressure suction cup 520 is disposed on an output end of the multi-axis robot 510; the second CCD sensor 530 is disposed on the workbench 100, and is configured to acquire coordinates of the FPC light bar when being clamped by the multi-axis manipulator 510, and feed the coordinates back to the control computer, and the multi-axis manipulator 510 adjusts the position of the FPC light bar according to the coordinates acquired by the second CCD sensor 530; the working stroke of the second transfer mechanism 500 is that after the FPC light bar is positioned in the positioning mechanism 400, the multi-axis manipulator 510 and the second negative pressure suction cup 520 suck the FPC light bar, the second CCD sensor 530 scans the contour coordinates of the FPC light bar and sends the contour coordinates to the control computer, and then the control computer compares the contour coordinates with the set coordinates, and since the FPC light bar is positioned in the positioning mechanism 400, excessive comparison operation is not required, the multi-axis manipulator 510 is controlled to adjust the position of the FPC light bar, and after the set coordinates are adjusted, the FPC light bar is transferred out of the machine.

The working principle is as follows:

continuing to refer to fig. 3, firstly, feeding is performed, a worker puts the bottom diaphragms in the feeding frame 210, and the material lifting module 212 drives the lifting plate 213 to lift the bottom diaphragms in the feeding frame 210 one by one until the bottom diaphragms reach the feeding frame infrared sensor 211; the first negative pressure suction cup 250 is linked with the feeding X-axis slide rail pair 241, the feeding Y-axis slide rail pair 242 and the feeding Z-axis cylinder 243 to transfer the bottom membrane in the feeding frame 210 to the feeding conveying belt 220;

continuing to refer to fig. 5, then, performing bottom film separation, wherein the single-sided film 231 provides traction force through the tape transport roller 230 and is wound on the surface of the feeding transport belt 220 for circulation, the sticky side of the single-sided film 231 faces upwards, the single-sided film can be stuck with the bottom film for recovery in the circulation process, and the FPC light bar can be peeled off and waits for the first transfer mechanism 300 to clamp in the process that the bottom film is recovered along the single-sided film 231 at the foremost end of the transport belt;

then taking out the FPC light bar, when the FPC light bar is peeled off from the bottom membrane to the front end of the material conveying belt 220, the FPC light bar is identified by the material infrared sensor 330, the material infrared sensor 330 sends a signal to a control computer so as to control the rubber belt conveying roller 230 to pause and work, then the first CCD sensor 340 acquires the coordinate of the connecting part 1 of the FPC light bar, the clamping manipulator 320 transfers the three-axis sliding rail pair 310 in a linkage manner to acquire the coordinate according to the first CCD sensor 340, the connecting part 1 of the FPC light bar is clamped, and the FPC light bar is displaced to a set adsorption coordinate;

continuing to refer to fig. 6, then positioning the FPC light bar, after the FPC light bar is clamped by the clamping manipulator 320, the material placing table 401 is slid to a position below a set adsorption coordinate by driving of the Y-axis screw slide rail pair 407, then the clamping manipulator 320 is released, and the FPC light bar is transferred onto the material placing table 401, then the material placing table 401 is reset to an initial position, the left and right limiting cylinders 404 and the front and rear limiting cylinders 405 respectively drive the left and right limiting baffles 402 and the front and rear limiting baffles 403 to simultaneously approach to the center of the material placing table 401, and push the FPC light bar until the FPC light bar is pushed to a set position of the center;

and finally, transferring the FPC light bar out of the machine, after the FPC light bar is positioned in the positioning mechanism 400, sucking the FPC light bar by the multi-axis manipulator 510 and the second negative pressure sucker 520, scanning the contour coordinates of the FPC light bar by the second CCD sensor 530, sending the contour coordinates to the control computer, comparing the contour coordinates with the set coordinates by the control computer, controlling the multi-axis manipulator 510 to adjust the position of the FPC light bar, and transferring the FPC light bar out of the FPC light bar assembly machine to be assembled after the position of the FPC light bar is adjusted to the set coordinates.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides a FPC lamp strip material loading machine, includes workstation and control computer, its characterized in that:

2. The FPC lamp strip feeding machine of claim 1, characterized in that: the feeding mechanism comprises a feeding frame, a feeding conveying belt, a rubber belt conveying roller, a feeding three-axis sliding rail pair and a first negative pressure sucker; the feeding frame is arranged on the workbench; the feeding conveyer belt is arranged beside the feeding frame; the adhesive tape conveying roller is arranged below the feeding conveying belt and is connected with an adhesive tape conveying motor in a driving way; the feeding three-shaft sliding rail pair is arranged above the feeding frame and the feeding conveying belt; the first negative pressure sucker is arranged on the feeding triaxial slide rail pair.

3. The FPC lamp strip feeding machine of claim 2, characterized in that: a feeding frame infrared sensor is arranged at the top in the feeding frame; a material lifting module is arranged beside the feeding frame; the feeding frame infrared sensor is electrically connected with the control computer; the material lifting module is connected with a lifting plate in a sliding manner; the lifting plate extends into the feeding frame.

4. The FPC lamp strip feeding machine of claim 2, characterized in that: the feeding three-axis sliding rail pair comprises a feeding X-axis sliding rail pair, a feeding Y-axis sliding rail pair and a feeding Z-axis cylinder which are driven by an air source; the feeding X-axis sliding rail pair is arranged on the workbench; the feeding Y-axis sliding rail pair is arranged on the feeding X-axis sliding rail pair; the feeding Z-axis cylinder is arranged on the Y-axis sliding rail pair; the first negative pressure sucker is arranged at the output end of the feeding Z-axis sliding rail pair.

5. The FPC lamp strip feeding machine of claim 1, characterized in that: the first transfer mechanism further comprises a transfer three-axis slide rail pair and a material infrared sensor; the transfer triaxial slide rail pair comprises a transfer X-axis lead screw slide rail pair, a transfer Y-axis lead screw slide rail pair and a transfer Z-axis cylinder, wherein the transfer X-axis lead screw slide rail pair and the transfer Y-axis lead screw slide rail pair are driven by lead screw motors respectively; the X-axis screw transfer sliding rail pair is arranged on the workbench; the transfer Y-axis lead screw sliding rail pair is arranged on the transfer X-axis lead screw sliding rail pair; the transfer Z-axis cylinder is arranged on the transfer Y-axis lead screw slide rail pair; the clamping manipulator is arranged on the transfer Z-axis cylinder; the material infrared sensor is arranged on the workbench, is electrically connected with the control computer and is used for identifying the separation state of the FPC light bar and the bottom diaphragm.

6. The FPC lamp strip feeding machine of claim 1, characterized in that: the positioning mechanism comprises a positioning Y-axis lead screw slide rail pair, a material placing table, a left limiting baffle, a right limiting baffle and a front limiting baffle; the positioning Y-axis lead screw sliding rail pair is arranged on the workbench and is in driving connection with a motor; the material placing table is connected to the positioning Y-axis lead screw sliding rail pair in a sliding manner; the left and right limiting baffles are respectively arranged on the left and right sides of the material placing table and are in driving connection with left and right limiting cylinders; the front and rear limiting baffles are respectively arranged on the front side and the rear side of the material placing table and are connected with front and rear limiting cylinders in a driving mode.

7. The FPC lamp strip feeding machine of claim 1, characterized in that: the second transfer mechanism further comprises a second negative pressure sucker and a second CCD sensor; the second negative pressure sucker is arranged on the output end of the multi-axis manipulator; the second CCD sensor is arranged on the workbench and used for acquiring coordinates of the FPC light bar clamped by the multi-axis manipulator and feeding the coordinates back to the control computer, and the multi-axis manipulator adjusts the position of the FPC light bar according to the coordinates acquired by the second CCD sensor.

8. The FPC lamp strip feeding machine of claim 1, characterized in that: the clamping manipulator adopts a pneumatic finger.

9. The FPC lamp strip feeding machine of claim 1, characterized in that: the multi-axis manipulator adopts a four-axis SCARA robot.