CN117008040B - Electric energy meter detection device for voltage power line carrier wave and application method thereof - Google Patents

Abstract

An electric energy meter detection device for a voltage power line carrier wave and a use method thereof belong to the field of electric energy meter detection equipment. Comprises a shell, a transmission device, a power device and a control device; the upper end of the shell is provided with a power device; the lower end of the power device is provided with a transmission device; the inside bottom of shell is provided with controlling means. The bottom plate is fixedly connected to the bottom ends of the opposite surfaces of the two side plates I; the upper end of the bottom plate is fixedly connected with a motor, and the output shaft of the motor is fixedly connected with a transmission block; two ends of one side plate I are provided with openings, a slideway is arranged on the bottom surface of each opening, an observation window is arranged on the other side plate I, and two partition plates are fixedly connected between the two side plates I. The invention can limit the light irradiation position through the sealed shell, so that a worker only observes the light irradiation position, the single inspection area is reduced, the situation that the worker looks at dislocation is avoided, the working efficiency is prevented from being influenced, and meanwhile, the invention can automatically replace the circuit board.

Description

Electric energy meter detection device for voltage power line carrier wave and application method thereof

Technical Field

The invention relates to an electric energy meter detection device of a voltage power line carrier wave and a use method thereof, belonging to the field of electric energy meter detection equipment.

Background

When the circuit board in the electric energy meter is detected, the following detection needs to be carried out:

1. see the state of the element

And taking a failed circuit board, and firstly observing whether the circuit board has obvious element damage, such as electrolytic capacitor burnout and bulge, resistance burnout, burnout of a power device and the like.

2. Soldering of a circuit board

If the printed circuit board has deformation and warpage; whether welding spots fall off or not, and obviously cold joint exists; the copper-clad sheet of the circuit board is not warped and burnt to turn black.

3. Insert for viewing element

Such as integrated circuits, diodes, circuit board power transformers, etc., are not misplaced.

4. Simple test of resistance capacitance

The universal meter is used for simply testing suspected elements such as resistance, capacitance and inductance in the measuring range, and whether the resistance value of the resistor is increased, the capacitance is short-circuited, the open circuit and the capacitance value are changed, the inductance is short-circuited, the open circuit and the like is tested.

5. Power-on test

After the simple observation and test, the fault cannot be removed, and the power-on test can be performed. Firstly, testing whether the power supply of the circuit board is normal. Such as whether the ac power supply of the circuit board is abnormal, whether the voltage regulator output is abnormal, whether the switching power supply output and waveform are abnormal, etc.

6. Brushing program

For programmable elements such as a singlechip, a DSP, a CPLD and the like, the process of brushing the program again can be considered, and circuit faults caused by abnormal program operation can be eliminated.

When the first three detection periods are carried out, the detection needs to be carried out through naked eyes, but the elements and welding spots on the circuit board are more and more dense, the observation dislocation phenomenon can be caused after the observation time is long, and the previously observed position is difficult to find after the observation dislocation, so that the working efficiency is reduced, and therefore, the improvement is necessary.

Disclosure of Invention

The invention aims to solve the problems in the background art and provides an electric energy meter detection device for a voltage power line carrier and a use method thereof.

The invention achieves the above purpose, adopts the following technical scheme:

an electric energy meter detection device for a voltage power line carrier wave comprises a shell, a transmission device, a power device and a control device; the upper end of the shell is provided with a power device; the lower end of the power device is provided with a transmission device; the inside bottom of shell is provided with controlling means.

A method of using an electric energy meter detection device for a voltage power line carrier, the method comprising the steps of:

step one: placing the circuit board on a conveyor belt, and starting the conveyor belt to enable the circuit board to fall into the rectangular groove through the inclined plate and the notch;

step two: the bidirectional motor is started in the forward direction, the sliding plate is driven to move through the transmission shaft II, and then the light source is driven to move, so that the circuit board is locally illuminated, and the observation is convenient;

step three: starting the motor to enable the notch to be communicated with the corresponding rectangular groove, enabling the circuit board in the rectangular groove to be discharged through the discharge hole, then reversely starting the motor, moving to the original position, and repeating the step one.

Compared with the prior art, the invention has the beneficial effects that: the invention can limit the light irradiation position through the sealed shell, so that a worker only observes the light irradiation position, the single inspection area is reduced, the situation that the worker looks at dislocation is avoided, the working efficiency is prevented from being influenced, and meanwhile, the invention can automatically replace the circuit board.

Drawings

FIG. 1 is a front view of an electric energy meter detection device for a voltage power line carrier wave of the present invention;

FIG. 2 is a cross-sectional view taken along the direction A-A in FIG. 1;

FIG. 3 is a front view of a housing, power unit of an electric energy meter detection device for a voltage power line carrier wave of the present invention;

FIG. 4 is a top view of the housing of an electric energy meter detection device for a voltage power line carrier of the present invention;

FIG. 5 is a front view of a transmission of an electric energy meter detection device for a voltage power line carrier of the present invention;

FIG. 6 is a top view of a transmission of an electric energy meter detection device for a voltage power line carrier of the present invention;

fig. 7 is a front view of a control device of an electric energy meter detection device of the present invention for a voltage power line carrier;

FIG. 8 is a top view of a rectangular plate of an electric energy meter detection device for a voltage power line carrier wave of the present invention;

FIG. 9 is a bottom view of a rotating plate of an electric energy meter detection device for a voltage power line carrier wave of the present invention;

FIG. 10 is a front view of a drive wheel I of an electric energy meter detection device for a voltage power line carrier wave of the present invention;

FIG. 11 is a side cross-sectional view of a drive wheel I of an electric energy meter detection device for a voltage power line carrier of the present invention;

FIG. 12 is a front view of a driving wheel II of the electric energy meter detecting device of the voltage power line carrier wave of the invention;

fig. 13 is a side view cross-section of a driving wheel ii of an electric energy meter detecting device for a voltage power line carrier according to the present invention.

Detailed Description

The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the invention, but not all embodiments, and all other embodiments obtained by those skilled in the art without making creative efforts based on the embodiments of the present invention are all within the protection scope of the present invention.

The first embodiment is as follows: as shown in fig. 1-13, the present embodiment describes an electric energy meter detection device for a voltage power line carrier, which includes a housing 1, a transmission device 2, a power device 3 and a control device 4; the upper end of the shell 1 is provided with a power device 3; the lower end of the power device 3 is provided with a transmission device 2; the inner bottom end of the housing 1 is provided with a control device 4.

The shell 1 comprises a side plate I11, a bottom plate 12, two motors 13, a transmission block 14, a side plate II 16 and two partition plates 19; two side plates I11 and II 16 are arranged, and the adjacent side plates I11 and II 16 are fixedly connected to form a rectangular frame; the bottom plate 12 is fixedly connected to the bottom ends of the opposite surfaces of the two side plates I11; the upper end of the bottom plate 12 is fixedly connected with a motor 13, and the output shaft of the motor 13 is fixedly connected with a transmission block 14; two ends of one side plate I11 are provided with openings 18, the bottom surface of each opening 18 is provided with a slideway 111, and two partition plates 19 are fixedly connected between the two side plates I11; a circular groove 17 is formed in the outer side face of each side plate II 16; the outer side face of the side face I11 provided with the notch 18 is fixedly connected with an inclined plate 5, and the other end of the inclined plate 5 is provided with a conveying belt 6.

The length of the bottom plate 12 is smaller than that of the side plate I11, and a discharge hole 15 is formed between two ends of the bottom plate 12 and the corresponding side plate II 16.

The power device 3 comprises a motor bracket 31, a bidirectional motor 32, a transmission shaft I33, a spring 34 and a transmission shaft II 35; the bidirectional motor 32 is fixedly connected to the upper end of the side plate I11 through a motor bracket 31; a transmission shaft I33 is fixedly connected to one output shaft of the bidirectional motor 32, and a transmission shaft II 35 is fixedly connected to the other output shaft of the bidirectional motor 32; the upper end of the side plate II 16 is fixedly connected with a supporting plate 110, and a transmission shaft II 35 penetrates through the supporting plate 110; and a spring 34 is further arranged on the transmission shaft II 35.

And a thread is arranged on the transmission shaft II 35.

The transmission device 2 comprises a sliding plate 21, a sealed shell 23, a light source 24, a connecting block 25, an L-shaped control plate 27, a sliding block 28 and a cross rod 29; the sliding plate 21 is provided with a vertical perforation 22, and the upper end of the sliding plate 21 is fixedly connected with a sealing shell 23 communicated with the perforation 22; a light source 24 is arranged at the top end of the inner part of the sealed shell 23; the top end of the sealing shell 23 is fixedly connected with a connecting block 25; the connecting block 25 is provided with a threaded hole 26 in threaded connection with a transmission shaft II 35, and the spring 34 is positioned between the supporting plate 110 and the connecting block 25; the two sides of the sliding plate 21 are symmetrically and fixedly connected with an L-shaped control plate 27, the L-shaped control plate 27 is positioned at the notch 18 of the side plate I11, and the lower end of the L-shaped control plate 27 is fixedly connected with a sliding block 28 which is in sliding fit with a sliding way 111; the end of the L-shaped control plate 27 far away from the sliding plate 21 is fixedly connected with a cross rod 29; the sliding plate 21 is positioned at the upper ends of the two partition plates 19; the cross bar 29 is located outside the side plate ii 16.

The control device 4 comprises a driving wheel I41, a belt 42, a driving wheel II 43, a driving rod 44, a rectangular plate 46, a connecting shaft 48 and a rotating plate 49; the two driving wheels I41, the belts 42 and the driving wheels II 43 are respectively arranged, the two driving wheels I41 are respectively connected to the driving shaft I33 and the driving shaft II 35 in a key way, the two driving wheels II 43 are connected in the circular grooves 17 on the outer sides of the two side plates II 16 through bearings, and the belts 42 are arranged between each driving wheel I41 and the corresponding driving wheel II 43; the length of the belt 42 is larger than twice the distance between the driving wheels I41 and II 43; the lower end of the rotating plate 49 is provided with a chute 410 which is in sliding fit with the transmission block 14, and two notches 491 are arranged on the rotating plate 49 at the same side of the chute 410; the upper end of the rotating plate 49 is fixedly connected with a connecting shaft 48; the connecting shaft 48 is connected to the lower end of the rectangular plate 46 through a bearing; the rectangular plates 46 are positioned at the lower ends of the two separation plates 19, and rectangular grooves 47 vertically penetrating the rectangular plates 46 are formed in the rectangular plates 46; two transmission rods 44 are symmetrically and fixedly connected to two sides of the rectangular plate 46; each transmission rod 44 is provided with a spiral groove 45, and the transmission rods 44 pass through the corresponding transmission wheels II 43.

An annular groove I411 is formed in the side face of the driving wheel I41, and a connecting block I413 in sliding fit with the annular groove I411 is arranged in the annular groove I; the other end of the connecting block I413 is fixedly connected with a semicircular shell I412; the belt 42 is arranged at the gap between the semicircular shell I412 and the driving wheel I41.

An annular groove II 421 is formed in the outer circular surface of the driving wheel II 43, and a connecting block II 423 in sliding fit with the annular groove II 421 is arranged in the annular groove II 421; an annular groove III is formed in one side of the driving wheel II 43, and the other side of the driving wheel II 43 is positioned in the circular groove 17; a connecting block III 424 which is in sliding fit with the annular groove III is arranged in the annular groove III; the connecting blocks II 423 and III 424 are fixedly connected with a semicircular shell II 422; the belt 42 is arranged at a gap between the semicircular shell II 422 and the driving wheel II 43; the transmission wheel II 43 is sleeved on the transmission rod 44 through a central round hole, and a limiting block 426 which is in sliding fit with the spiral groove 45 is fixedly connected to the inner wall of the round hole.

The semicircular shells I412 and II 422 on the driving wheels I41 and II 43 can prevent the belt 42 from being separated from the driving wheels I41 and II 43 when being pushed by the cross bar 29.

A method of using an electric energy meter detection device for a voltage power line carrier, the method comprising the steps of:

step one: placing the circuit board on the conveyor belt 6, and starting the conveyor belt 6 to enable the circuit board to fall into the rectangular groove 47 through the inclined plate 5 and the notch 18;

step two: the bidirectional motor 32 is started in the forward direction, the sliding plate 21 is driven to move through the transmission shaft II 35, and then the light source 24 is driven to move, so that the circuit board is partially illuminated, and the observation is convenient;

step three: the motor 13 is started, the notch 491 is communicated with the corresponding rectangular groove 47, the circuit board in the rectangular groove 47 is discharged through the discharge hole 15, then the motor 13 is reversely started, the motor is moved to the original position, and the step one is repeated.

The working principle of the invention is as follows: when the device is used, the bidirectional motor 32 is started positively, the bidirectional motor 32 drives the connecting block 25 to move to the left side shown in fig. 1 through the transmission shaft II 35, meanwhile, the connecting block 25 drives the sliding plate 21 to move together, the sliding plate 21 drives the L-shaped control plates 27 at two sides to move leftwards, the L-shaped control plates 27 at the left side expose the left opening 18, the circuit board falls into the rectangular groove 47 through the sloping plate 5 and the opening 18, when one end of the L-shaped control plates 27 parallel to the side plate II 16 contacts the inner wall of the side plate II 16 along with the rotation of the bidirectional motor 32, the connecting block 25 is separated from the threads on the transmission shaft II 35, the connecting block 25 compresses the spring 34, when the bidirectional motor 32 drives the transmission shaft II 35 to rotate, the sliding plate 21 does not move horizontally any more, and when one end of the L-shaped control plates 27 parallel to the side plate II 16 contacts the inner wall of the side plate II 16, one end of the L-shaped control plate 27 exposed out of the side plate II 16 drives the cross rod 29 to move, the cross rod 29 pushes the belt 42 to move, the belt 42 is tensioned, the transmission shaft II 35 is connected with the transmission wheel I41 in a key way, when the transmission shaft II 35 rotates, the transmission wheel I41 is driven to rotate, the tensioned belt 42 is driven to move, the belt 42 drives the transmission wheel II 43 to rotate through friction force, a limiting block 426 on the transmission wheel II 43 rotates along with the transmission wheel II, further the transmission rod 44 positioned at the left side is driven to move to the right side through the cooperation of the limiting block 426 and a spiral groove 45 on the corresponding transmission rod 44 until the rectangular groove 47 with the circuit board moves between the two separation plates 19, the other rectangular groove 47 moves to the position of the notch 18 positioned at the right side, when the rectangular plate 46 moves to the right side, the sliding plate 21 drives the L-shaped control plate 27 positioned at the right end of the right side to move to the leftmost side, so that the belt 42 positioned at the right side is not in a tensioned state, after the rectangular plate 46 moves rightwards, the rectangular plate 46 drives the transmission rod 44 at the right end to move together, the transmission rod 44 drives the transmission wheel II 43 at the right side to rotate through the spiral groove 45, and meanwhile, the bidirectional motor 32 drives the transmission shaft I33 to rotate;

the bidirectional motor 32 is reversely started, because the spring 34 is in a compressed state, the connecting block 25 is always abutted against the left end of the screw thread of the transmission shaft II 35 through the elasticity of the spring 34, when the bidirectional motor 32 drives the transmission shaft II 35 to reversely rotate, the connecting block 25 is matched with the screw thread on the transmission shaft II 35 again under the action of the spring 34, the transmission shaft II 35 drives the sliding plate 21 to move rightwards through the connecting block 25, and the steps are repeated, so that the circuit board enters the other rectangular groove 47; after the L-shaped control plate 27 positioned at the right end of the sliding plate 21 is contacted with the inner wall of the side plate II 16, the connecting block 25 is separated from the screw thread on the transmission shaft II 35 again, and the spring 34 is stretched, so that the connecting block 25 is abutted against the right end of the screw thread on the transmission shaft II 35 under the elastic force of the spring 34, and the connecting block 25 can be matched with the screw thread again after the bidirectional motor 32 is started positively;

in the process of moving the slide plate 21 rightwards, the slide plate 21 drives the light source 24 to move rightwards, because the slide plate 21, the two partition plates 19, the rectangular plate 46 and the side plate I11 form a space which is darker than external light, when the light source 24 passes through the through holes 22 and irradiates on the circuit board in the rectangular groove 47, areas with different brightness are formed on the circuit board, when a worker observes, only the areas irradiated by the light source 24 need to be observed, and because the bright and dark areas on the circuit board are distinguished obviously, the worker can observe elements, welding spots and the like on the circuit board only from the positions irradiated by the light source 24 for inspection, and for the elements and welding spots in dark areas, the light problem can not be observed, so that the observable range of the worker is reduced, and after the observation time of the worker is longer, the situation of observation dislocation caused by eye fatigue is reduced; in the process of reciprocating movement of the sliding plate 21, the circuit board continuously enters the corresponding rectangular groove 47 from the notch 18 to finish feeding;

after the observation is completed, the rectangular plate 46 moves to the lower end of the corresponding notch 18 again, then the motor 13 is started, the motor 13 drives the rotating plate 49 to rotate through the rectangular transmission block 14, the notch 491 is communicated with the corresponding rectangular groove 47, the circuit board is further moved downwards to pass through the discharge hole 15, and then the motor 13 is reversely started to move the rotating plate 49 to the original position, and in the process, the L-shaped control plate 27 is not contacted with the side plate II 16;

in the process of horizontally moving the rectangular plate 46 and the rotating plate 49 left and right, when the rectangular plate 46 contacts the inner wall of the side plate II 16, only one transmission block 14 in sliding fit with the sliding groove 410 at the lower end of the rotating plate 49 is arranged in the sliding groove.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

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

Claims (6)

1. An electric energy meter detection device of voltage power line carrier wave, its characterized in that: comprises a shell (1), a transmission device (2), a power device (3) and a control device (4); the upper end of the shell (1) is provided with a power device (3); the lower end of the power device (3) is provided with a transmission device (2); the control device (4) is arranged at the bottom end of the interior of the shell (1);

the shell (1) comprises a side plate I (11), a bottom plate (12), two motors (13), a transmission block (14), a side plate II (16) and two partition plates (19); two side plates I (11) and two side plates II (16) are respectively arranged, and the adjacent side plates I (11) and II (16) are fixedly connected to form a rectangular frame; the bottom plate (12) is fixedly connected to the bottom ends of the opposite surfaces of the two side plates I (11); the upper end of the bottom plate (12) is fixedly connected with a motor (13), and the output shaft of the motor (13) is fixedly connected with a transmission block (14); two ends of one side plate I (11) are provided with openings (18), the bottom surface of each opening (18) is provided with a slideway (111), the other side plate I (11) is provided with an observation window, and two partition plates (19) are fixedly connected between the two side plates I (11); a circular groove (17) is formed in the outer side face of each side plate II (16); an inclined plate (5) is fixedly connected to the outer side face of the side face I (11) provided with the notch (18), and a conveyor belt (6) is arranged at the other end of the inclined plate (5);

the power device (3) comprises a motor bracket (31), a bidirectional motor (32), a transmission shaft I (33), a spring (34) and a transmission shaft II (35); the bidirectional motor (32) is fixedly connected to the upper end of the side plate I (11) through a motor bracket (31); a transmission shaft I (33) is fixedly connected to one output shaft of the two-way motor (32), and a transmission shaft II (35) is fixedly connected to the other output shaft of the two-way motor (32); the upper end of the side plate II (16) is fixedly connected with a supporting plate (110), and a transmission shaft II (35) penetrates through the supporting plate (110); a spring (34) is also arranged on the transmission shaft II (35);

the transmission device (2) comprises a sliding plate (21), a sealed shell (23), a light source (24), a connecting block (25), an L-shaped control board (27), a sliding block (28) and a cross rod (29); the sliding plate (21) is provided with a vertical perforation (22), and the upper end of the sliding plate (21) is fixedly connected with a sealing shell (23) communicated with the perforation (22); a light source (24) is arranged at the top end of the inner part of the sealed shell (23); the top end of the sealing shell (23) is fixedly connected with a connecting block (25); the connecting block (25) is provided with a threaded hole (26) in threaded connection with the transmission shaft II (35), and the spring (34) is positioned between the supporting plate (110) and the connecting block (25); the two sides of the sliding plate (21) are symmetrically and fixedly connected with an L-shaped control plate (27), the L-shaped control plate (27) is positioned at the opening (18) of the side plate I (11), and the lower end of the L-shaped control plate (27) is fixedly connected with a sliding block (28) which is in sliding fit with the sliding way (111); one end of the L-shaped control plate (27) far away from the sliding plate (21) is fixedly connected with a cross rod (29); the sliding plate (21) is positioned at the upper ends of the two separation plates (19); the cross bar (29) is positioned at the outer side of the side plate II (16);

the control device (4) comprises a driving wheel I (41), a belt (42), a driving wheel II (43), a driving rod (44), a rectangular plate (46), a connecting shaft (48) and a rotating plate (49); the two driving wheels I (41), the belt (42) and the driving wheels II (43) are respectively provided with two driving wheels I (41) which are respectively connected to the driving shaft I (33) and the driving shaft II (35) in a key way, the two driving wheels II (43) are connected in circular grooves (17) on the outer sides of the two side plates II (16) through bearings, and the belt (42) is arranged between each driving wheel I (41) and the corresponding driving wheel II (43); the length of the belt (42) is larger than twice of the distance between the driving wheel I (41) and the driving wheel II (43); the lower end of the rotating plate (49) is provided with a sliding groove (410) which is in sliding fit with the transmission block (14), and two notches (491) are arranged on the rotating plate (49) at the same side of the sliding groove (410); the upper end of the rotating plate (49) is fixedly connected with a connecting shaft (48); the connecting shaft (48) is connected to the lower end of the rectangular plate (46) through a bearing; the rectangular plates (46) are positioned at the lower ends of the two separation plates (19), and rectangular grooves (47) vertically penetrating the rectangular plates (46) are formed in the rectangular plates (46); two transmission rods (44) are symmetrically and fixedly connected to two sides of the rectangular plate (46); each transmission rod (44) is provided with a spiral groove (45), and the transmission rods (44) penetrate through the corresponding transmission wheels II (43).

2. The electric energy meter detection device of claim 1, wherein: the length of the bottom plate (12) is smaller than that of the side plate I (11), and a discharge hole (15) is formed between two ends of the bottom plate (12) and the corresponding side plate II (16).

3. The electric energy meter detection device of claim 2, wherein: and a thread is arranged on the transmission shaft II (35).

4. A device for detecting an electric energy meter of a voltage power line carrier according to claim 3, wherein: an annular groove I (411) is formed in the side face of the driving wheel I (41), and a connecting block I (413) in sliding fit with the annular groove I (411) is arranged in the annular groove I; the other end of the connecting block I (413) is fixedly connected with a semicircular shell I (412); the belt (42) is arranged at a gap between the semicircular shell I (412) and the driving wheel I (41).

5. The electric energy meter detection device of claim 4, wherein: an annular groove II (421) is formed in the outer circular surface of the driving wheel II (43), and a connecting block II (423) in sliding fit with the annular groove II (421) is arranged in the annular groove II; an annular groove III (425) is formed in one side of the driving wheel II (43), and the other side of the driving wheel II (43) is positioned in the circular groove (17); a connecting block III (424) which is in sliding fit with the annular groove III (425) is arranged in the annular groove III; the semicircular shells II (422) are fixedly connected to the connecting blocks II (423) and III (424); the belt (42) is arranged at a gap between the semicircular shell II (422) and the driving wheel II (43); the driving wheel II (43) is sleeved on the driving rod (44) through a central round hole, and a limiting block (426) which is in sliding fit with the spiral groove (45) is fixedly connected to the inner wall of the round hole.

6. The method for using the electric energy meter detection device for the voltage power line carrier according to claim 5, wherein the method comprises the following steps: the using method comprises the following steps:

step one: placing the circuit board on a conveyor belt (6), and starting the conveyor belt (6) to enable the circuit board to fall into a rectangular groove (47) through an inclined plate (5) and a notch (18);

step two: the bidirectional motor (32) is started in the forward direction, the sliding plate (21) is driven to move through the transmission shaft II (35), and the light source (24) is driven to move, so that the circuit board is partially illuminated, and the observation is convenient;

step three: and starting the motor (13), enabling the notch (491) to be communicated with the corresponding rectangular groove (47), enabling the circuit board in the rectangular groove (47) to be discharged through the discharge hole (15), then reversely starting the motor (13), moving to the original position, and repeating the step one.