CN210982669U - Full-automatic flexible line way board electricity measuring device - Google Patents

Abstract

The utility model discloses a device is surveyed to full-automatic flexible line way board electricity, this electricity survey device including be used for holding the automatic upper and lower unloading module 1 of the product that awaits measuring for take out the product of awaiting measuring from automatic upper and lower unloading module 1 and get and put module 2 and be used for carrying out the ICT test fixture module 3 that the clamp tightly carries out the ICT test to the product that awaits measuring. The utility model provides an electricity measuring device utilizes automatic upper and lower unloading module and product to get and put the module and has realized that the automation snatchs, removes, utilizes ICT test fixture module to realize the automatic positioning of the product that awaits measuring, has improved operating efficiency and location accuracy.

Description

Full-automatic flexible line way board electricity measuring device

Technical Field

The utility model relates to a device is surveyed to full-automatic flexible line way board electricity.

Background

A flexible printed circuit board (flexibleprintedcuittboard) is called a "flexible board" for short, and is commonly called an FPC in the industry, and is a printed circuit board made of a flexible insulating base material (mainly polyimide or a polyester film), [1] has many advantages that rigid printed circuit boards do not have. For example, it can be freely bent, rolled, folded. The FPC can be used for greatly reducing the volume of electronic products, and is suitable for the development of the electronic products in the directions of high density, miniaturization and high reliability. Therefore, the FPC is widely applied to the fields or products of aerospace, military, mobile communication, laptop computers, computer peripherals, PDAs, digital cameras and the like.

The flexible printed circuit board has a single side, double sides and a multi-layer board. The adopted base material is mainly a polyimide copper clad laminate. The material has high heat resistance and good dimensional stability, and is pressed with a covering film with mechanical protection and good electrical insulation performance to form a final product; the FPC also has the advantages of good heat dissipation and weldability, easy connection, low comprehensive cost and the like.

In order to ensure the welding condition test of the flexible printed circuit board, the flexible printed circuit board is tested by ICT online test at present. The ICT on-line test is a standard test means for testing the electrical performance and electrical connection of the components on the flexible circuit board to check the defects in production and manufacture and the defects of the components.

The conventional Flexible Printed Circuit (FPC) ICT online test process at present is as follows:

a. taking a test product from a Tray disc to be tested;

b. putting the product into a test fixture (one mold and one hole) for ICT function test;

c. manually placing the tested product into a finished product Tray;

d. carrying out appearance inspection on the product in the finished product Tray by a subsequent manual work;

the three processes of a, c and d all need manual operation, which is the main reason for low ICT testing efficiency and poor yield at present.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems existing in the prior art, the utility model aims to provide a device is surveyed to full-automatic flexible line way board electricity that can snatch, remove and fix a position the product that awaits measuring automatically.

In order to realize the utility model discloses an aim at, the device is surveyed to full-automatic flexible line way board electricity that provides here includes:

the automatic feeding and discharging module is used for containing a product to be detected;

the product taking and placing module is used for taking out a product to be detected from the automatic feeding and discharging module;

and the ICT test fixture module is used for positioning and clamping a product to be tested to perform ICT test.

Further, the utility model provides a device is surveyed to full-automatic flexible line way board electricity still includes CCD outward appearance detection module for the outward appearance to the product that awaits measuring detects.

Further, the number of the product work carrier plates is at least two.

The utility model has the advantages that: the utility model provides an electricity measuring device utilizes automatic upper and lower unloading module and product to get and put the module and has realized that the automation snatchs, removes, utilizes ICT test fixture module to realize the automatic positioning of the product that awaits measuring, has improved operating efficiency and location accuracy.

The CCD appearance detection is used for replacing manual work to carry out the appearance detection of the product, and the efficiency and the yield of the appearance detection are improved.

The ICT function test is carried out by replacing the one-die one-hole clamp with the one-die multi-hole clamp, and meanwhile, material taking and placing and test time are carried out in parallel, so that the test efficiency is improved.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention. It is obvious that the drawings in the following description are only some embodiments of the invention, and that for a person skilled in the art, other drawings can be derived from them without inventive effort. In the drawings:

fig. 1 is an overall structure diagram of the electrical measuring device provided by the present invention;

fig. 2 is a schematic structural view of the automatic feeding and discharging module of the present invention;

FIG. 3 is an enlarged view of a portion of the photosensor of FIG. 2;

fig. 4 is a schematic structural view of a product pick-and-place module according to the present invention;

fig. 5 is a schematic structural view of a first linear guide rail assembly according to the present invention;

fig. 6 is a schematic structural view of the pressing driving cylinder according to the present invention;

fig. 7 is a cylinder buffering floating joint of the present invention;

fig. 8 is a schematic structural diagram of an ICT test fixture module according to the present invention;

fig. 9 is a schematic structural view of a lower die assembly according to the present invention;

FIG. 10 is a schematic diagram of the detection of a product to be detected;

fig. 11 is a diagram illustrating a detection principle of the appearance detection module according to the present invention;

fig. 12 is a schematic structural view of the linear sliding processing assembly according to the present invention;

in the figure: 1-automatic feeding and discharging module, 2-product taking and placing module, 3-ICT test fixture module, 4-appearance detection module, 5-double-head test probe, 6-product to be tested, 11-motor, 12-driving synchronous pulley, 13-synchronous belt, 14-driven synchronous pulley, 15-tray, 16-ball screw, 17-optical axis guide rod, 18-photoelectric sensor, 19-upper fixed plate, 110-lower fixed plate, 111-mounting substrate, 112-induction iron sheet, 21-downward pressing driving cylinder, 22-cylinder buffering floating joint, 23-linear sliding processing assembly, 24-first linear guide rail assembly, 25-hollow stepping motor, 26-vacuum air pipe joint, 27 connecting workpiece and 28-PP suction nozzle assembly, 211-an air cylinder push rod, 212-an upper magnetic inductor, 213-a lower magnetic inductor, 231-a linear sliding workpiece A, 232-a linear sliding workpiece B, 233-a linear sliding workpiece C, 241-a guide rail, 242-a slide block, 31-a driving air cylinder, 32-a clamp upper die assembly, 33-a second linear guide rail assembly, 34-a lower die assembly, 35-a motor assembly, 36-a rotating carrier plate, 37-a sliding member, 38-a product working carrier plate, 39-a testing station, 321-a switching probe, 322-a switching pin, 323-a lead-out connector, 324-a PCB2 plate, 381-a PCB1 plate and 41-a CCD lens.

Detailed Description

Example embodiments will now be described more fully with reference to the accompanying drawings. Example embodiments may, however, be embodied in many different forms and should not be construed as limited to the examples set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of example embodiments to those skilled in the art.

Example one

Referring to fig. 1, the full-automatic flexible printed circuit board electrical measuring device provided by the embodiment comprises an automatic feeding module and an automatic discharging module 1 for containing products to be tested, a product taking and placing module 2 for taking out the products to be tested from the automatic feeding module and the automatic discharging module 1, and an ICT test fixture module 3 for positioning, clamping and carrying out ICT test on the products to be tested.

The working principle of the electric measuring device is as follows: taking out a product to be tested from the automatic feeding and discharging module 1 through the product taking and placing module 2, and placing the product into an ICT test fixture module 3 for ICT test; after the ICT test is finished, the product taking and placing module 2 takes out the product to be tested from the ICT test fixture module 3 and places the product on the automatic feeding module 1 and the automatic discharging module 1 for storage.

Example two

The fully-automatic flexible printed circuit board electrical measuring device provided by the embodiment comprises all technical characteristics of the fully-automatic flexible printed circuit board electrical measuring device provided by the embodiment, and in order to be capable of automatically detecting the appearance of a product to be detected, the fully-automatic flexible printed circuit board electrical measuring device provided by the embodiment further comprises an appearance detection module 4 for detecting the appearance of the product to be detected.

The appearance detection module 4 is connected with an external PC, and firstly can capture appearance good product images of a plurality of orders of magnitude and store the images in the PC as appearance good product templates, then obtains the appearance images of the products to be detected and compares the appearance images with the appearance good product templates stored in the PC, and identifies different points of the appearance of the products to be detected and the appearance good product templates to judge whether the products to be detected are defective products.

Here, the appearance detecting module 4 includes a CCD lens 41, and the appearance of the flexible circuit board is acquired by the CCD lens 41. And corresponding special CCD lens software is installed on the external PC and is used for identifying different points of the appearance of the product to be detected and the appearance non-defective template and judging whether the product to be detected is defective or not.

The principle of the CCD lens 41 detecting the product to be detected is shown in fig. 11, the CCD lens acquires an appearance image of the product to be detected and transmits the image to an external PC, the PC compares the appearance image of the product to be detected with an appearance good template existing therein, and the difference between the appearance of the product to be detected and the appearance good template is identified to determine whether the product to be detected is a defective product.

Referring to fig. 2, the automatic feeding and discharging module 1 according to the first and second embodiments of the present invention includes a motor 11, a driving synchronous pulley 12, a synchronous belt 13, a driven synchronous pulley 14, a tray 15, a ball screw 16, an optical axis guide rod 17, an upper fixing plate 19 and a lower fixing plate 110, wherein the ball screw 16 and the optical axis guide rod 17 are installed between the upper fixing plate 19 and the lower fixing plate 110, and the tray 15 is sleeved on the ball screw 16 and the optical axis guide rod 17; the driven synchronous belt pulley 14 is sleeved at one end of the ball screw 16 and drives the ball screw 16 to rotate; the driving synchronous pulley 12 is sleeved on an output shaft of the motor 11, and the driving synchronous pulley 12 and the driven synchronous pulley 14 are connected through a synchronous belt 13.

The working process of the automatic feeding and discharging module 1 is as follows: power is output to a ball screw 16 by an electrode 11 through a driving synchronous belt pulley 12, a driven synchronous belt pulley 14 and a synchronous belt 13 to do circular rotation motion, linear guide is conducted by matching with an optical axis guide rod 17, the Tray 15 is driven to do up-and-down linear motion, and a plastic Tray disc stacked on the Tray 15 can do up-and-down linear motion to meet the temporary storage function of the product before and after testing by placing the product to be tested on the Tray 15.

Wherein the tray 15 is sleeved on the ball screw 16 and the optical axis guide rod 17 through nuts.

In order to realize the limit function of tray 15, the utility model discloses an automatic upper and lower material module 1 still includes photoelectric sensor 18, and photoelectric sensor 18 is installed on mounting substrate 111, is provided with on the tray 15 with photoelectric sensor 18 mounted position assorted response iron sheet 112 photoelectric sensor 18 couples to and does real-time feedback in external control system P L C through electric wire, and external control system P L C is connected with motor 11, the stall of control motor 11.

The mounting substrate 111 is made of aluminum.

Referring to fig. 3, the photo sensor 18 includes a U-shaped notch, when the sensing iron 112 is inserted into the U-shaped notch of the photo sensor 18, indicating that the tray 15 has reached the position of the photo sensor 18, i.e. the set limit position, the photo sensor 18 outputs a signal to the external control system P L C, and the motor 11 is fed back and controlled to stop rotating through P L C, so as to achieve the limit.

Referring to fig. 4, the product taking and placing module 2 according to the first and second embodiments of the present invention includes a pressing driving cylinder 21, a cylinder buffering floating joint 22, a linear sliding processing assembly 23, a first linear guide rail assembly 24, a hollow stepping motor 25, a vacuum air pipe joint 26, a connecting workpiece 27, and a PP suction nozzle assembly 28. The downward pressing driving air cylinder 21 is connected with the linear sliding machining assembly 23 through an air cylinder buffering floating joint 22, and the hollow stepping motor 25 is arranged on the linear sliding machining assembly 23 to enable the linear sliding machining assembly and the linear sliding machining assembly to be connected; the linear sliding processing assembly 23 is arranged on the first linear guide rail assembly 24; the vacuum air pipe joint 26 is arranged at the upper end of the hollow stepping motor 25 through connecting a workpiece 27, the PP suction nozzle component 28 is arranged at the lower end of the hollow stepping motor 25, and the vacuum air pipe joint 26 is communicated with the PP suction nozzle component 28.

The working process of the product taking and placing module 2 is as follows: the pressing driving air cylinder 21 is pressed downwards, pressure is output to the linear sliding machining assembly 23 through the air cylinder buffering floating joint 22, the linear sliding machining assembly 23 slides on the first linear guide rail assembly 24 under the action of the pressing driving air cylinder 21, and the linear sliding machining assembly is additionally provided with the hollow stepping motor 25, the vacuum air pipe joint 26, a connecting workpiece 27 and the PP suction nozzle assembly 28 to do vertical linear motion together, so that the action of taking and placing products is achieved.

In addition, the hollow stepping motor performs rotation action when taking and placing products in a linear action, and the direction of taking and placing the products is adjusted; the vacuum pressure of the product taking and placing module 2 is generated by a vacuum pump, and reaches a 28-PP suction nozzle component through a vacuum air pipe joint 26, a connecting workpiece 27 and a hollow stepping motor 25, so as to adsorb and take and place the product.

Wherein the first linear guide assembly 24 includes a guide rail 241 and a slider 242, as shown in fig. 5. The guide rail 241 is fixed, and a groove is formed in one surface of the slider 242 contacting the guide rail 241 and moves linearly relative to the guide rail 241 through the groove.

The linear sliding processing assembly 23 in the product taking and placing module 2 is used for installing the hollow stepping motor 25, and then the direct current sliding processing assembly 23 is installed on the first linear guide rail assembly 24. The linear sliding processing assembly 23 can adopt any mounting bracket for mounting the hollow stepping motor 25, and herein used is a linear sliding processing assembly as shown in fig. 12, which comprises a linear sliding processing member a231, a linear sliding processing member B232 and a linear sliding processing member C233, wherein the linear sliding processing member a231 and the linear sliding processing member C233 are fixedly connected by means of a linear sliding processing member B232 (rod-shaped member) with a threaded head, the linear sliding processing member a231 and the cylinder floating joint 22 are connected by means of a thread, the linear sliding processing member C233 and the vacuum air pipe joint 26, the connecting processing member 27 and the PP suction nozzle assembly 28 are connected by means of a screw and a thread, so that the cylinder buffer floating joint 22, the linear sliding processing assembly 23, the vacuum air pipe joint 26, the connecting processing member 27 and the PP suction nozzle assembly 28 are connected as a whole, and when the cylinder 21 is driven to move linearly by pressing down, the air cylinder buffer floating joint 22, the linear sliding machining assembly 23, the vacuum air pipe joint 26, the connecting workpiece 27 and the PP suction nozzle assembly 28 move and stop simultaneously.

Referring to fig. 6, an upper magnetic inductor 212 and a lower magnetic inductor 213 for upper limit and lower limit are installed inside the cylinder body of the downward driving cylinder 21, the upper magnetic inductor 212 and the lower magnetic inductor 213 are electrically connected with an external control system P L C, the upper magnetic inductor 212 and the lower magnetic inductor 213 are used for realizing limit induction, the cylinder push rod 211 of the downward driving cylinder 21 is hidden in the cylinder body part of the downward driving cylinder 21 and is provided with a magnetic ring, the polarity of the magnetic ring of the upper magnetic inductor 212 and the magnetic ring of the lower magnetic inductor 213 is opposite to that of the magnetic ring of the cylinder push rod 211, when the cylinder push rod 211 senses with any one of the upper magnetic inductor 212 and the lower magnetic inductor 213, the magnetic inductor signals the external control system P L C, and the external control system P L C signals the electromagnetic valve controlling the cylinder to stop supplying air, at this time, the cylinder push rod stops operating, and the position is fixed.

Referring to fig. 7, the head of the cylinder buffering floating joint 22 is an internal thread mechanism and is connected and fastened with the external thread of the cylinder push rod 211 of the downward pressing driving cylinder 21; the bottom of the cylinder buffering floating joint 22 is a male screw joint and is connected and fastened with an internal screw thread processed at the head of the linear sliding processing assembly 23, so that the cylinder 21, the cylinder buffering floating joint 22 and the linear sliding processing assembly 23 are pressed down and move simultaneously as a whole when moving.

The connection workpiece 27 described herein is any connection member capable of connecting two members, such as a through member.

Referring to fig. 8, the ICT test fixture module 3 according to the first and second embodiments of the present invention includes a driving cylinder 31, an upper fixture module 32, a second linear guide rail module 33, a lower fixture module 34, a motor module 35, and a rotary carrier plate 36; the rotary carrier plate 36 is fixedly connected with the shaft end of the motor assembly 35, the lower die assembly 34 is mounted on the rotary carrier plate 36, the upper clamp die assembly 32 is mounted on the second linear guide rail assembly 33 through a sliding part 37, and the driving cylinder 31 drives the upper clamp die assembly 32 to move up and down; a product work carrier plate 38 for fixing a product to be detected is arranged on the lower die assembly 34, and a needle point area is arranged in the product work carrier plate 38; the upper fixture mold assembly 32 comprises adapter probes 321, adapter pins 322 and lead-out connectors 323, wherein the adapter probes 321 are electrically connected with the adapter pins 322, the adapter pins 322 are electrically connected with the lead-out connectors 323, and the lead-out connectors 323 are connected to external equipment through wires for ICT test.

The lower die assembly 34 is fixedly connected with the rotary carrier plate 36 through screw matching, the rotary carrier plate 36 is fixedly connected with the shaft end of the motor assembly 35, the rotary carrier plate 36 and the lower die assembly 34 are connected into a whole, and when the motor assembly 35 rotates, the motor assembly 35, the rotary carrier plate 36 and the lower die assembly rotate simultaneously.

Motor element 35 includes the motor, for the convenience of the stall of control motor, rotation rate and angle, the utility model discloses motor element 35 of record still includes motor controller, utilizes motor controller to realize the control of the stall of motor, rotation rate and angle.

The working process of the ICT test fixture module 3 is as follows: the product taking and placing module 2 is used for placing a product to be tested into the product work carrier plate 38 for positioning, and the motor assembly 35 is additionally provided with the lower die assembly 34 to rotate so as to be in a state of a test station 39; at this time, the belt clamp attached to the driving cylinder 31 is pressed down by the second linear guide assembly 33 to be attached to the lower mold assembly 34, and a plurality of products are tested simultaneously.

The second linear guide assembly 33 of the ICT test fixture module 3 is of the same construction as the first linear guide assembly 24, although other constructions that achieve a linear guide may be used.

Referring to fig. 10, the specific test procedure is as follows: the product 6 to be tested is placed into the product work carrier plate 38 through the product taking and placing module 2, the needle point area of the product 6 to be tested and the product work carrier plate 38 are provided with the needle point area conducting clamp upper die assembly 32, the bottom of the adapter probe 321 is in contact conduction with the needle point area arranged in the product work carrier plate 38 under the driving of the driving cylinder 31 through the double-head testing probe 5, the adapter probe 321 is electrically connected with the adapter pin 322, the adapter pin 322 is electrically connected with the derivation connector 323, the needle point area of the product 6 to be tested is electrically connected with the derivation connector 323, the derivation connector 323 is connected with external testing equipment through a lead, and ICT testing can be carried out on the product to be tested.

The relay probe 321 and the relay pin 322 are connected by soldering via a flexible wire 325, but other electrical connection methods may be used. The electrical connection between the pins 322 and the lead-out connector 323 can be achieved by any means, such as wire bonding, or PCB2 board 324 bonding, i.e., wiring is routed on the PCB2 board 324 to achieve electrical connection between the pins 322 and the lead-out connector 323.

The pin headers 322 and the lead-out connector 323 can be pin headers.

The pin point regions disposed in the product work carrier board 38 may be disposed directly on the product work carrier board 38, or may be disposed on the PCB1 board 381.

The needle point area recorded by the utility model comprises welding spots to be tested.

Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. This application is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the invention and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.

It will be understood that the invention is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the invention is limited only by the appended claims.

Claims (10)

1. The utility model provides a full-automatic flexible line way board electricity measuring device which characterized in that, the device includes:

the automatic feeding and discharging module (1) is used for containing a product to be detected;

the product taking and placing module (2) is used for taking out the product to be measured from the automatic feeding and discharging module (1);

and the ICT test fixture module (3) is used for positioning and clamping a product to be tested to perform ICT test.

2. The fully automatic flexible wiring board electrical measuring device of claim 1, wherein: the device also comprises an appearance detection module (4) for detecting the appearance of the product to be detected.

3. The fully automatic flexible wiring board electrical measuring device of claim 2, characterized in that: the appearance detection module (4) comprises a CCD lens (41).

4. A fully automatic flexible wiring board electrical measuring device according to claim 1 or 2 or 3, characterized in that: the automatic feeding and discharging module (1) comprises a motor (11), a driving synchronous pulley (12), a synchronous belt (13), a driven synchronous pulley (14), a tray (15), a ball screw (16), an optical axis guide rod (17), an upper fixing plate (19) and a lower fixing plate (110), wherein the ball screw (16) and the optical axis guide rod (17) are arranged between the upper fixing plate (19) and the lower fixing plate (110), and the tray (15) is sleeved on the ball screw (16) and the optical axis guide rod (17); the driven synchronous belt wheel (14) is sleeved at one end of the ball screw (16) and drives the ball screw (16) to rotate; the driving synchronous belt wheel (12) is sleeved on an output shaft of the motor (11), and the driving synchronous belt wheel (12) is connected with the driven synchronous belt wheel (14) through the synchronous belt (13).

5. The fully automatic flexible wiring board electrical measuring device of claim 4, wherein: the automatic feeding and discharging module further comprises a photoelectric sensor (18), the photoelectric sensor (18) is installed on the installation substrate (111), and an induction iron sheet (112) matched with the installation position of the photoelectric sensor (18) is arranged on the tray (15).

6. A fully automatic flexible wiring board electrical measuring device according to claim 1 or 2 or 3, characterized in that: the product taking and placing module (2) comprises a pressing driving air cylinder (21), an air cylinder buffering floating joint (22), a linear sliding machining assembly (23), a first linear guide rail assembly (24), a hollow stepping motor (25), a vacuum air pipe joint (26), a connecting machining piece (27) and a PP suction nozzle assembly (28), wherein the pressing driving air cylinder (21) is connected with the linear sliding machining assembly (23) through the air cylinder buffering floating joint (22), and the hollow stepping motor (25) is installed on the linear sliding machining assembly (23); the linear sliding machining assembly (23) is mounted on the first linear guide rail assembly (24); the vacuum air pipe joint (26) is arranged at the upper end of the hollow stepping motor (25) through the connecting machining piece (27), the PP suction nozzle component (28) is arranged at the lower end of the hollow stepping motor (25), and the vacuum air pipe joint (26) is communicated with the PP suction nozzle component (28).

7. The fully automatic flexible wiring board electrical measuring device of claim 6, wherein: the cylinder push rod (211) of the downward pressing driving cylinder (21) is hidden in a cylinder body part of the downward pressing driving cylinder (21) and is provided with a magnetic ring, and an upper magnetic inductor (212) and a lower magnetic inductor (213) which are opposite in polarity to the magnetic ring of the cylinder push rod (211) are arranged inside the cylinder body of the downward pressing driving cylinder (21).

8. A fully automatic flexible wiring board electrical measuring device according to claim 1 or 2 or 3, characterized in that: the ICT test fixture module (3) comprises a driving cylinder (31), an upper fixture die assembly (32), a second linear guide rail assembly (33), a lower die assembly (34), a motor assembly (35) and a rotary carrier plate (36); the rotary carrier plate (36) is fixedly connected with the shaft end of the motor assembly (35), the lower die assembly (34) is installed on the rotary carrier plate (36), the upper clamp die assembly (32) is installed on the second linear guide rail assembly (33) through a sliding part (37), and the driving cylinder (31) drives the upper clamp die assembly (32) to move up and down; a product work carrier plate (38) for fixing a product to be detected is distributed on the lower die assembly (34), and a needle point area is distributed in the product work carrier plate (38); mould subassembly (32) on the anchor clamps include switching probe (321), switching stitch (322) and derive connector (323), switching probe (321) with switching stitch (322) electricity is connected, switching stitch (322) with derive connector (323) electricity and be connected.

9. The fully automatic flexible wiring board electrical measuring device of claim 8, wherein: the number of product work carrier plates (38) is at least two.

10. The fully automatic flexible wiring board electrical measuring device of claim 8, wherein: the motor assembly (35) includes a motor and a motor controller for controlling stall, rotational speed and angle of the motor.

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