CN116031170B - Button diode test row is to seal color circle machine - Google Patents

Abstract

The invention discloses a button diode test alignment ink ring machine, which comprises: frame, discharge plate, receiving track, testing mechanism, unloading mechanism, ink ribbon mechanism, ink ring mechanism and receipts magazine, the discharge track connection receiving track of discharge plate, testing mechanism includes first mounting panel, the area material carousel, test assembly and first panel, test assembly fixed mounting is in first mounting panel one side, be provided with forward silo and reverse silo down on the unloading board, be provided with the shifting block on the partition panel between forward silo and the reverse silo down, reverse silo down communicates to the guide way on the reverse regulating block, the guide way is spiral downwards along the surface of reverse regulating block, ink ribbon mechanism fixed mounting is on the box of unloading mechanism below, the receipts magazine sets up in ink ribbon mechanism below. Compared with the prior art, the invention completes the electrical test and the pad printing ring in one step and automatically turns the reverse material.

Description

Button diode test row is to seal color circle machine

Technical Field

The invention belongs to the field of semiconductor element processing, and particularly relates to a button diode test alignment ink ring machine.

Background

A diode is an electronic device made of semiconductor materials (silicon, selenium, germanium, etc.). It has unidirectional conductivity, i.e. the diode is turned on when a forward voltage is applied to the anode of the diode. When reverse voltages are applied to the anode and cathode, the diode turns off. The on and off of the diode corresponds to the on and off of the switch.

In the process of diode processing, the electrical test and the rolling color ring are required to be carried out on the diode, in the existing processing technology, the electrical test and the rolling color ring are required to be carried out in different devices, the diode processing efficiency is low, and the automatic turning and turning of the diode in the transportation process cannot be controlled, so that the unification of the polarity of materials cannot be realized.

Disclosure of Invention

The invention aims at: the button type diode testing row direction color ring machine is provided, the electrical testing and the rolling color ring are completed in one step, meanwhile, the diode automatically turns over and changes the direction of a reverse material in the process of transporting to the rolling color ring module according to the identification of the forward direction and the reverse direction after the electrical testing, so that the requirement of uniform polarity of the material is met.

In order to achieve the above purpose, the present invention adopts the following technical scheme: a button diode test alignment ink ring machine, comprising: the device comprises a frame, a discharge tray, a receiving track, a testing mechanism, a discharging mechanism, an ink ribbon mechanism, an ink ring mechanism and a receiving box, wherein the discharge tray is fixedly arranged on a box body of the frame, a diode is arranged in the discharge tray, the discharging track of the discharge tray is connected with the receiving track, the testing mechanism comprises a first mounting plate, a ribbon turntable, a testing component and a first panel, the first mounting plate is fixedly arranged on the box body, the ribbon turntable is rotatably arranged in a first mounting groove on the first mounting plate, a first discharging hole of the receiving track is communicated to the first mounting groove, a first ribbon notch which is circumferentially arranged is arranged on the ribbon turntable, the testing component is fixedly arranged on one side of the first mounting plate, the first panel fixed mounting is on first mounting panel, first mounting groove is sealed to first panel, unloading mechanism includes the flitch, shifting block and reverse adjusting block, be provided with forward silo and reverse silo down on the flitch, be provided with the shifting block on the partition panel between forward silo and the reverse silo down, reverse silo intercommunication is to the guide way on the reverse adjusting block down, reverse adjusting block is semicircular columnar structure for the cross-section, the guide way is spiral downwards along the surface of reverse adjusting block, ink ribbon mechanism fixed mounting is on the box of unloading mechanism below, the receipts magazine sets up in ink ribbon mechanism below, ink ribbon mechanism fixed mounting is in ink ribbon mechanism one side.

As a further description of the above technical solution:

one side of the material receiving track is provided with a first material blocking cylinder, the output end of the first material blocking cylinder is connected with a first material blocking rod, and the first material blocking rod passes through the track panel of the material receiving track and then abuts against the diode.

As a further description of the above technical solution:

the material receiving track one side is also provided with a second material blocking cylinder, the output end of the second material blocking cylinder is connected with a second material blocking rod, and the second material blocking rod passes through the side wall of the material receiving track and then abuts against the diode.

As a further description of the above technical solution:

the test assembly comprises an anode driving cylinder, an anode test plate, an anode test electrode, a cathode driving cylinder, a cathode test plate and a cathode test electrode, wherein the anode test plate is fixedly arranged at the output end of the anode driving cylinder, the anode test plate is provided with the anode test electrode, the cathode test plate is fixedly arranged at the output end of the cathode driving cylinder, the cathode test plate is provided with the cathode test electrode, the anode test electrode and the cathode test electrode are symmetrically arranged at two sides of the first mounting plate, the anode test electrode passes through the first panel and then abuts against the diode, and the cathode test electrode passes through the first mounting plate and then abuts against the diode.

As a further description of the above technical solution:

the blanking mechanism further comprises a first vibrating piece and a second vibrating piece, the first vibrating piece is propped against one side of the reverse adjusting block, the second vibrating piece is propped against the blanking plate, and the second vibrating piece and the reverse adjusting block are symmetrically arranged on two sides of the blanking plate.

As a further description of the above technical solution:

the ink ribbon mechanism comprises a second mounting plate, an ink ribbon wheel and a second panel, wherein the second mounting plate is fixedly mounted on the box body, the ink ribbon wheel is rotatably mounted in a second mounting groove on the second mounting plate, a guide groove is further formed in the second mounting plate, a second ribbon gap which is circumferentially arranged is formed in the ink ribbon wheel, and the second panel is fixedly mounted on the second mounting plate.

As a further description of the above technical solution:

the ink ring mechanism comprises a driving motor, a driving shaft, an ink wheel and a printing wheel, wherein the driving motor is fixedly arranged on the frame through a first mounting bracket, the output end of the driving motor is connected with the driving shaft, the ink wheel is sleeved on the driving shaft, the wheel edge of the ink wheel is contacted with the wheel edge of the printing wheel, the printing wheel is fixedly arranged on the frame through a second mounting bracket, and the wheel edge of the printing wheel abuts against the surface of the diode after penetrating through a clearance groove on the second panel.

As a further description of the above technical solution:

the ink ring mechanism further comprises at least one intermediate wheel rotatably mounted on the second mounting bracket, the rim on one side of the intermediate wheel being in contact with the rim of the ink wheel and the rim on the opposite side being in contact with the rim of the print wheel.

As a further description of the above technical solution:

the receiving box is in sliding connection in the frame, is provided with the blanking mouth on the mesa of frame, and the blanking mouth position corresponds the setting in the ink ribbon material wheel below, and the blanking mouth communicates to the receipts silo of receiving the box.

In summary, due to the adoption of the technical scheme, the beneficial effects of the invention are as follows:

1. according to the invention, diodes in the discharging tray drop into the receiving rail downwards from the circular arc-shaped discharging rail, and sequentially enter the first charging notch on the charging turntable from the first discharging hole at the bottom of the receiving rail, the charging turntable is driven by the stepping motor, and when the diodes on the charging turntable rotate to one side of the first mounting plate, the test assembly performs electrical test on the diodes, and the diodes are identified as forward or reverse. And then the diode falls into the blanking mechanism from a notch below the first mounting groove. The poking block pokes the diode into different blanking grooves according to the direction judging result of the diode. The forward diode enters the forward discharging groove and directly falls into the guide groove from the lower part, the reverse diode enters the reverse discharging groove and enters the guide groove on the reverse adjusting block, the reverse diode automatically turns over and changes direction in the falling process of the spiral downward guide groove and falls into the guide groove from the guide groove, and the diodes of the follow-up rolling printing color rings are guaranteed to be forward, so that the requirement of uniform material polarity is met. The diode electrical test and the roll-on color ring are completed in one-stop mode, and meanwhile, after the electrical test, the diode automatically turns over and changes the direction of the reverse material in the process of transporting to the roll-on color ring module according to the identification of the forward direction and the reverse direction, so that the requirement of uniform polarity of the material is met.

2. In the invention, the material receiving box is connected on the frame in a sliding way, a material discharging opening is arranged on the table surface of the frame, the material discharging opening is correspondingly arranged below the ink ribbon material wheel, and the material discharging opening is communicated to the material receiving groove of the material receiving box. The diode through rolling seal color ring falls into the blanking mouth from the second mounting panel, and then falls into the receipts silo of the inside receipts magazine of frame, and the diode can not expose in the air, avoids the diode surface to be infected with the dust, effectively improves diode production quality.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a perspective view of a button diode test array color wheel machine.

Fig. 2 is a partial enlarged view at a in fig. 1.

Fig. 3 is a perspective view of a button diode test array color wheel machine.

Fig. 4 is a partial enlarged view at B in fig. 3.

Fig. 5 is a schematic side view of a button diode test array direction color wheel machine.

Fig. 6 is a partial enlarged view at C in fig. 5.

Fig. 7 is a partial enlarged view at D in fig. 5.

Fig. 8 is a perspective view of a button diode test row-direction color wheel machine.

Fig. 9 is a partial enlarged view at E in fig. 8.

Fig. 10 is a partial enlarged view of F in fig. 8.

FIG. 11 is a schematic diagram of a mechanism for testing color rings of a color ring printer with button-type diode.

Legend description:

1. a frame; 11. a case; 12. a table top; 2. a discharge tray; 21. a discharge rail; 3. a material receiving rail; 31. a first material blocking cylinder; 311. a first material blocking rod; 32. a track panel; 33. a second material blocking cylinder; 331. a second material blocking rod; 4. a testing mechanism; 41. a first mounting plate; 42. a belt turntable; 421. a first belt gap; 43. a testing component; 431. a positive electrode driving cylinder; 432. an anode test plate; 433. a positive electrode test electrode; 434. a negative electrode driving cylinder; a negative electrode 435, a test plate; 436. a negative electrode test electrode; 44. a first panel; 5. a blanking mechanism; 51. a blanking plate; 511. forward feeding trough; 512. a reverse blanking groove; 52. a shifting block; 53. a reverse adjusting block; 531. a guide groove; 54. a first vibrating member; 55. a second vibrating member; 6. an ink ribbon mechanism; 61. a second mounting plate; 611. a guide groove; 62. an ink ribbon wheel; 621. a second strip gap; 63. a second panel; 631. a clearance groove; 7. an ink ring mechanism; 71. a driving motor; 711. a first mounting bracket; 72. a drive shaft; 73. an ink wheel; 74. a printing wheel; 741. a second mounting bracket; 75. an intermediate wheel; 8. a receiving box; 9. a diode.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments 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 some embodiments of the present invention, but not all embodiments of the present invention. The components of the embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the invention, as presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

In describing embodiments of the present invention, it should be noted that, the azimuth or positional relationship indicated by the terms "upper", "inner", etc. are based on the azimuth or positional relationship shown in the drawings, or the azimuth or positional relationship that the inventive product is conventionally put in use, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific azimuth, be configured and operated in a specific azimuth, and thus should not be construed as limiting the present invention.

In the description of the present invention, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

Referring to fig. 1-11, the present invention provides a technical solution: a button diode test alignment ink ring machine, comprising: the device comprises a frame 1, a discharge tray 2, a receiving track 3, a testing mechanism 4, a discharging mechanism 5, an ink ribbon mechanism 6, an ink ring mechanism 7 and a receiving box 8, wherein the discharge tray 2 is fixedly arranged on a box body 11 of the frame 1, a diode 9 is arranged in the discharge tray 2, the discharge track 21 of the discharge tray 2 is connected with the receiving track 3, the testing mechanism 4 comprises a first mounting plate 41, a ribbon turntable 42, a testing component 43 and a first panel 44, the first mounting plate 41 is fixedly arranged on the box body 11, the ribbon turntable 42 is rotatably arranged in a first mounting groove on the first mounting plate 41, a first discharging hole of the receiving track 3 is communicated to the first mounting groove, a first ribbon notch 421 circumferentially arranged is arranged on the ribbon turntable 42, the testing component 43 is fixedly arranged on one side of the first mounting plate 41, the first panel 44 is fixedly mounted on the first mounting plate 41, the first panel 44 seals the first mounting groove, the blanking mechanism 5 comprises a blanking plate 51, a shifting block 52 and a reverse adjusting block 53, a forward blanking groove 511 and a reverse blanking groove 512 are arranged on the blanking plate 51, the shifting block 52 is arranged on a partition plate between the forward blanking groove 511 and the reverse blanking groove 512, the reverse blanking groove 512 is communicated with a guide groove 531 on the reverse adjusting block 53, the reverse adjusting block 53 is of a columnar structure with a semicircular section, the guide groove 531 spirals downwards along the surface of the reverse adjusting block 53, the ink ribbon mechanism 6 is fixedly mounted on the box 11 below the blanking mechanism 5, the material receiving box 8 is arranged below the ink ribbon mechanism 6, and the ink ribbon ring mechanism 7 is fixedly mounted on one side of the ink ribbon mechanism 6. Diode 9 in discharge tray 2 falls into receiving in the material track 3 downwards from convex ejection of compact track 21 to in receiving the first discharge gate on the material carousel 42 is got into in proper order from receiving the material track 3 bottom in the first area material breach 421, the material carousel 42 passes through step motor drive, when diode 9 rotates to first mounting panel 41 one side (test assembly 43 department) on the material carousel 42, test assembly 43 carries out the electrical test to diode 9, and discerns that diode 9 is forward or reverse. The diode 9 then falls into the blanking mechanism 5 from the notch below the first mounting groove. The poking block 52 pokes the diode 9 into different blanking grooves according to the distinguishing result of the diode 9. The forward diode 9 enters the forward discharging groove 511 and directly falls into the guide groove 611 from the lower part, the reverse diode 9 enters the reverse discharging groove 512 and enters the guide groove 531 on the reverse adjusting block 53, the reverse diode 9 automatically turns over and changes direction in the falling process of the spiral downward guide groove 531, and falls into the guide groove 611 from the guide groove 531, so that the diode 9 of the subsequent pad printing ring is ensured to be forward, and the requirement of uniform material polarity is met.

One side of the material receiving track 3 is provided with a first material blocking cylinder 31, the output end of the first material blocking cylinder 31 is connected with a first material blocking rod 311, and the first material blocking rod 311 passes through the track panel 32 of the material receiving track 3 and then abuts against the diode 9. The first blocking cylinder 31 can drive the first blocking rod 311 to move, so that the end part of the first blocking rod 311 passes through the track panel 32 of the material receiving track 3 and then abuts against the diode 9, the diode 9 is limited to fall, and the blanking switching is realized.

The material receiving track 3 one side still is provided with the second and keeps off material cylinder 33, and the output of second keeps off material cylinder 33 is connected with the second and keeps off material pole 331, and the second keeps off material pole 331 and supports on diode 9 after passing the lateral wall that connects material track 3. The second material blocking cylinder 33 can drive the second material blocking rod 331 to move, the end part of the second material blocking rod 331 penetrates through the side wall of the material receiving track 3 and then is blocked below the diode 9, the diode 9 is limited to fall, and blanking switching is achieved.

The test assembly 43 includes a positive driving cylinder 431, a positive test plate 432, a positive test electrode 433, a negative driving cylinder 434, a negative test plate 435 and a negative test electrode 436, wherein the positive test plate 432 is fixedly installed at the output end of the positive driving cylinder 431, the positive test plate 432 is provided with the positive test electrode 433, the negative test plate 435 is fixedly installed at the output end of the negative driving cylinder 434, the negative test plate 435 is provided with the negative test electrode 436, the positive test electrode 433 and the negative test electrode 436 are symmetrically arranged at two sides of the first mounting plate 41, the positive test electrode 433 is propped against the diode 9 after passing through the first panel 44, and the negative test electrode 436 is propped against the diode 9 after passing through the first mounting plate 41. During the electrical test, the positive electrode driving cylinder 431 drives the positive electrode testing plate 432 to move toward the first mounting plate 41, the positive electrode testing electrode 433 on the positive electrode testing plate 432 passes through the first panel 44 and contacts the front surface of the diode 9, and the negative electrode testing electrode 436 on the back surface of the first mounting plate 41 acts in the same way, so as to realize the electrical test of the diode 9 and distinguish the forward direction or the reverse direction of the diode 9.

The blanking mechanism 5 further comprises a first vibrating member 54 and a second vibrating member 55, the first vibrating member 54 is abutted against one side of the reverse adjusting block 53, the second vibrating member 55 is abutted against the blanking plate 51, and the second vibrating member 55 and the reverse adjusting block 53 are symmetrically arranged on two sides of the blanking plate 51. The first vibration member 54 vibrates by a vibration motor or other means to promote the vibration of the diode 9 in the reverse adjustment block 53 for blanking, and the second vibration member 55 is similar. Since the second vibration member 55 is provided on the back surface of the blanking plate 51, the second vibration member 55 can also promote the blanking of the diode 9 in the forward blanking groove 511 and the reverse blanking groove 512.

The ink ribbon mechanism 6 includes a second mounting plate 61, an ink ribbon wheel 62 and a second panel 63, the second mounting plate 61 is fixedly mounted on the box 11, the ink ribbon wheel 62 is rotatably mounted in a second mounting groove on the second mounting plate 61, a guide groove 611 is further provided on the second mounting plate 61, a second ribbon gap 621 circumferentially arranged is provided on the ink ribbon wheel 62 (the ink ribbon wheel 62 is driven by a stepping motor), and the second panel 63 is fixedly mounted on the second mounting plate 61. The guide groove 611 is correspondingly arranged below the blanking mechanism 5, the guide groove 611 is of a funnel-shaped structure with a wide upper part and a narrow lower part, the diode 9 in the guide groove 611 falls into the second strip gap 621 on the ink strip wheel 62, and when the ink strip wheel 62 rotates to one side of the second mounting plate 61 (the position of the ink ring mechanism 7), the wheel edge of the ink wheel 74 in the ink ring mechanism 7 passes through the clearance groove 631 on the second panel 63 and then abuts against the surface of the diode 9, so that the color ring rolling of the diode 9 is realized.

The color ring mechanism 7 comprises a driving motor 71, a driving shaft 72, an ink wheel 73 and a printing wheel 74, wherein the driving motor 71 is fixedly arranged on the frame 1 through a first mounting bracket 711, the output end of the driving motor 71 is connected with the driving shaft 72, the ink wheel 73 is sleeved on the driving shaft 72, the rim of the ink wheel 73 is contacted with the rim of the printing wheel 74, the printing wheel 74 (rotatably arranged on a second mounting bracket 741) is fixedly arranged on the frame 1 through a second mounting bracket 741, and the rim of the printing wheel 74 abuts against the surface of the diode 9 after passing through a clearance groove 631 on the second panel 63. When the color ring mechanism 7 rolls the color ring, the output end of the driving motor 71 is connected with the driving shaft 72 through a coupling, the driving shaft 72 drives the ink wheel 73 (the ink wheel dips in ink from the ink box in the rotation motion) to rotate, the ink on the ink wheel 73 transits to the printing wheel 74 due to the contact between the wheel edge of the ink wheel 73 and the wheel edge of the printing wheel 74, and the printing wheel 74 rolls the color ring on the diode 9. The working principle of the color ring mechanism 7 is the prior art, but is not repeated

Referring to fig. 11, the ink ring mechanism 7 further includes at least one intermediate wheel 75, the intermediate wheel 75 being rotatably mounted on the second mounting frame 741, the rim on one side of the intermediate wheel 75 being in contact with the rim of the ink wheel 73 and the rim on the opposite side being in contact with the rim of the print wheel 74. There are 4 intermediate wheels 75 between the ink wheel 73 and the two print wheels 74 (the intermediate wheels 75 are used to transfer ink from the ink wheel 73 to the print wheels 74), and since the rim of one intermediate wheel 75 is in contact with the rim of the ink wheel 73, the rims of the 4 intermediate wheels 75 are in contact with each other, and the rim of one intermediate wheel 75 is in contact with the rim of the print wheel 74, the 4 intermediate wheels 75 can transfer ink from one ink wheel 73 to two print wheels 74.

The material receiving box 8 is slidably connected to the frame 1, a material discharging port is arranged on the table top 12 of the frame 1, the material discharging port is correspondingly arranged below the ink ribbon material wheel 62, and the material discharging port is communicated to a material receiving groove of the material receiving box 8. The diode 9 passing through the roll printing ring falls into the blanking port from the second mounting plate 61, then falls into the receiving groove of the receiving box 8 in the frame 1, the diode 9 is not exposed in the air, dust is prevented from being adhered to the surface of the diode 9, and the production quality of the diode 9 is effectively improved.

Working principle: diode 9 in discharge tray 2 falls into receiving in the material track 3 downwards from convex ejection of compact track 21 to in receiving the first discharge gate on the material carousel 42 is got into in proper order from receiving the material track 3 bottom in the first area material breach 421, the material carousel 42 passes through step motor drive, when diode 9 rotates to first mounting panel 41 one side (test assembly 43 department) on the material carousel 42, test assembly 43 carries out the electrical test to diode 9, and discerns that diode 9 is forward or reverse. The diode 9 then falls into the blanking mechanism 5 from the notch below the first mounting groove. The poking block 52 pokes the diode 9 into different blanking grooves according to the distinguishing result of the diode 9. The forward diode 9 enters the forward discharging groove 511 and directly falls into the guide groove 611 from the lower part, the reverse diode 9 enters the reverse discharging groove 512 and enters the guide groove 531 on the reverse adjusting block 53, the reverse diode 9 automatically turns over and changes direction in the falling process of the spiral downward guide groove 531, and falls into the guide groove 611 from the guide groove 531, so that the diode 9 of the subsequent pad printing ring is ensured to be forward, and the requirement of uniform material polarity is met. The diode 9 passing through the roll printing ring falls into the blanking port from the second mounting plate 61, then falls into the receiving groove of the receiving box 8 in the frame 1, the diode 9 is not exposed in the air, dust is prevented from being adhered to the surface of the diode 9, and the production quality of the diode 9 is effectively improved.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims (8)

1. A button diode test alignment ink ring machine, comprising: frame (1), discharge plate (2), connect material track (3), testing mechanism (4), unloading mechanism (5), ink ribbon mechanism (6), ink ring mechanism (7) and receive magazine (8), discharge plate (2) fixed mounting is in on box (11) of frame (1), be provided with diode (9) in discharge plate (2), discharge track (21) of discharge plate (2) are connected connect material track (3), testing mechanism (4) include first mounting panel (41), ribbon carousel (42), test assembly (43) and first panel (44), first mounting panel (41) fixed mounting is in on box (11), ribbon carousel (42) rotatable install in first mounting groove on first mounting panel (41), first discharge gate intercommunication of material track (3) is to first mounting groove, be provided with first ribbon breach (421) of arranging on ribbon carousel (42), test assembly (43) are in first panel (41) fixed mounting panel (44), first panel (41) are in one side of sealing down, first panel (41) fixed mounting panel (44) are in first mounting panel (41) fixed mounting panel (5) The automatic ink-jet printing machine comprises a shifting block (52) and a reverse adjusting block (53), wherein a forward feeding trough (511) and a reverse feeding trough (512) are arranged on a blanking plate (51), the shifting block (52) is arranged on a partition plate between the forward feeding trough (511) and the reverse feeding trough (512), the reverse feeding trough (512) is communicated to a guide groove (531) on the reverse adjusting block (53), the reverse adjusting block (53) is of a columnar structure with a semicircular section, the guide groove (531) is spirally downward along the surface of the reverse adjusting block (53), an ink-jet printing mechanism (6) is fixedly arranged on a box body (11) below the blanking mechanism (5), the ink-jet printing box (8) is arranged below the ink-jet printing mechanism (6), and an ink-jet printing ring mechanism (7) is fixedly arranged on one side of the ink-jet printing mechanism (6);

the test assembly (43) comprises an anode driving cylinder (431), an anode testing plate (432), an anode testing electrode (433), a cathode driving cylinder (434), an anode testing plate (435) and an anode testing electrode (436), wherein the anode testing plate (432) is fixedly installed at the output end of the anode driving cylinder (431), the anode testing plate (432) is provided with the anode testing electrode (433), the anode testing plate (435) is fixedly installed at the output end of the cathode driving cylinder (434), the anode testing electrode (436) is arranged on the anode testing plate (435), the anode testing electrode (433) and the anode testing electrode (436) are symmetrically arranged at two sides of the first mounting plate (41), the anode testing electrode (433) is abutted to the diode (9) after penetrating through the first mounting plate (41), and the anode testing electrode (436) is abutted to the diode (9) after penetrating through the first mounting plate (41).

2. The button diode test row ink pad machine according to claim 1, wherein a first material blocking cylinder (31) is arranged on one side of the material receiving track (3), the output end of the first material blocking cylinder (31) is connected with a first material blocking rod (311), and the first material blocking rod (311) passes through a track panel (32) of the material receiving track (3) and then abuts against the diode (9).

3. The button diode test row ink ring machine according to claim 2, wherein a second material blocking cylinder (33) is further arranged on one side of the material receiving track (3), an output end of the second material blocking cylinder (33) is connected with a second material blocking rod (331), and the second material blocking rod (331) passes through the side wall of the material receiving track (3) and then abuts against the diode (9).

4. The button diode test row-direction ink-ring machine according to claim 1, wherein the blanking mechanism (5) further comprises a first vibrating member (54) and a second vibrating member (55), the first vibrating member (54) is abutted against one side of the reverse adjusting block (53), the second vibrating member (55) is abutted against the blanking plate (51), and the second vibrating member (55) and the reverse adjusting block (53) are symmetrically arranged on two sides of the blanking plate (51).

5. The button diode test row-direction ink ring machine according to claim 1, wherein the ink ribbon mechanism (6) comprises a second mounting plate (61), an ink ribbon wheel (62) and a second panel (63), the second mounting plate (61) is fixedly mounted on the box body (11), the ink ribbon wheel (62) is rotatably mounted in a second mounting groove on the second mounting plate (61), a guide groove (611) is further formed in the second mounting plate (61), a second ribbon notch (621) circumferentially arranged is formed in the ink ribbon wheel (62), and the second panel (63) is fixedly mounted on the second mounting plate (61).

6. The button diode test row ink ring machine according to claim 5, wherein the ink ring mechanism (7) comprises a driving motor (71), a driving shaft (72), an ink wheel (73) and a printing wheel (74), the driving motor (71) is fixedly installed on the frame (1) through a first installation bracket (711), an output end of the driving motor (71) is connected with the driving shaft (72), the ink wheel (73) is sleeved on the driving shaft (72), a wheel edge of the ink wheel (73) is in contact with a wheel edge of the printing wheel (74), the printing wheel (74) is fixedly installed on the frame (1) through a second installation bracket (741), and the wheel edge of the printing wheel (74) abuts against the surface of the diode (9) after passing through a clearance groove (631) on the second panel (63).

7. A coin-operated diode test line ink ring machine as claimed in claim 6, characterized in that the ink ring mechanism (7) further comprises at least one intermediate wheel (75), said intermediate wheel (75) being rotatably mounted on the second mounting bracket (741), the rim of one side of the intermediate wheel (75) being in contact with the rim of the ink wheel (73) and the rim of the opposite side being in contact with the rim of the print wheel (74).

8. The button diode test row-direction ink ring machine according to claim 5, wherein the material receiving box (8) is slidably connected to the frame (1), a blanking port is arranged on a table top (12) of the frame (1), the blanking port is correspondingly arranged below the ink ribbon material wheel (62), and the blanking port is communicated to a material receiving groove of the material receiving box (8).