CN115910882A - Efficient diode dotting equipment with automatic material arranging function - Google Patents

Abstract

The invention provides high-efficiency diode dotting equipment with an automatic material arranging function, which comprises a dotting component, an aggregate component, a feeding component, a discharging component and an auxiliary material pushing structure, wherein the aggregate component is arranged on the dotting component; the dotting component and the feeding component are respectively arranged on two opposite sides of the collecting component, and the discharging component and the dotting component are arranged on the same side. The auxiliary material pushing structure comprises an L-shaped mounting upright rod, a push-pull driving motor and a Z-shaped material pushing block; the feeding assembly comprises a horizontal feeding conveying section and a fan-shaped feeding section which are connected with each other; the discharging assembly comprises a horizontal material guiding section, a semi-arc turning material guiding section and a horizontal discharging conveying section which are sequentially connected with one another; the electric heating tubes are arranged on two opposite sides of the turning material guiding section along the radian direction of the turning material guiding section; a drying channel is formed between the electric heating tubes at two opposite sides. The problem of the diode in disorder scattered placement after dotting is solved, the diode can be placed in order, the drying of the diode pin ink is accelerated through the auxiliary drying channel, and the situation that the ink drops or scrapes the flowers is avoided.

Description

Efficient diode dotting equipment with automatic material arranging function

Technical Field

The invention relates to the technical field of diode processing, in particular to high-efficiency diode dotting equipment with an automatic material arranging function.

Background

The Chinese granted announcement No. CN114566448A, the granted announcement date is 2022, 05 and 31, the patent name is a high-efficiency diode dotting device, which comprises a dotting component, a feeding component, an aggregate component and a charging barrel; the collecting component comprises a connecting plate, a plurality of bearing plates are arranged on the outer side surface of the connecting plate in a circumferential extending mode, the upper surface of each bearing plate is enclosed into a diode storage space through a baffle, an electric telescopic rod is installed at the bottom of each bearing plate, and the power output end of the electric telescopic rod penetrates through the bearing plates and extends out of the diode storage space; the bottom of the charging barrel is coaxially provided with a rotating motor; the dotting assembly comprises a first linear sliding table, a second linear sliding table, a first dotting structure and a second dotting structure, and the first linear sliding table is arranged above the charging barrel; the second linear sliding table is connected with the first linear sliding table through a sliding block, and the first dotting structure and the second dotting structure are arranged in parallel along the length direction of the sliding block respectively. The prior art has the following defects: the diode that the completion was got ready falls into the feed cylinder in unison, carries out the ejection of compact from the discharge gate again, because the diode pin ink that just accomplished after getting ready is not totally dried thoroughly, touches each other with other diodes after falling into the feed cylinder, the condition of ink disappearance often appears, leads to doing over again. In view of such circumstances, improvement is urgently required.

Disclosure of Invention

Based on the above, the invention aims to provide the efficient diode dotting equipment with the automatic material arranging function, the diode pins after dotting firstly pass through the drying channel and then enter the horizontal output conveyer belt, so that the problem that the diodes are scattered and placed after dotting is solved, the diodes can be placed in order, ink drying of the diode pins is assisted and accelerated through the drying channel, the situation that the ink drops or scratches cannot occur is ensured, and the production efficiency is also ensured.

The invention provides high-efficiency diode dotting equipment with an automatic material arranging function, which comprises a dotting component, an aggregate component, a feeding component, a discharging component and an auxiliary material pushing structure, wherein the aggregate component is arranged on the dotting component; the dotting component and the feeding component are respectively arranged on two opposite sides of the collecting component, and the discharging component and the dotting component are arranged on the same side.

The collecting component comprises a connecting plate, four bearing plates are uniformly distributed and extended in the circumferential direction of the outer side surface of the connecting plate, the upper surface of each bearing plate is surrounded by a baffle to form a diode storage space, a first electric telescopic rod is mounted at the bottom of each bearing plate, and the power output end of the first electric telescopic rod penetrates through the bearing plates and extends into the diode storage space; a support column abdicating hole is formed in the middle of the connecting plate, a bearing is coaxially installed in the support column abdicating hole, and a support column is coaxially connected in the bearing in a penetrating manner; the upper part of the supporting column extends out of the upper surface of the connecting plate, and the lower part of the supporting column extends out of the lower surface of the connecting plate; the lower surface of the connecting plate is provided with a driving plate around the coaxial central projection of the supporting column, the lower surface of the driving plate is provided with a gear surface, one side, close to the dotting assembly, of the lower portion of the supporting column is provided with a rotary driving motor, a power output end of the rotary driving motor is connected with a driving gear through an output shaft, and the driving gear is meshed with the gear surface on the lower surface of the driving plate.

The auxiliary material pushing structure comprises an L-shaped mounting vertical rod, a push-pull driving motor and a Z-shaped material pushing block, the L-shaped mounting vertical rod is mounted on the upper surface of the supporting column and is arranged close to one side of the dotting component, connecting rods are convexly arranged on the upper portion of the L-shaped mounting vertical rod close to the two opposite sides of the diode storage space, the lower portion of the Z-shaped material pushing block is arranged between the connecting rods on the two sides, and a rotating shaft which penetrates through the lower portion of the Z-shaped material pushing block and is rotatably connected with the Z-shaped material pushing block is arranged between the connecting rods on the two sides; the upper part of the L-shaped installation vertical rod is far away from one side of the diode storage space, and a push-pull driving motor is installed at a position corresponding to the lower part of the Z-shaped material pushing block; the power output end of the push-pull driving motor penetrates through the L-shaped mounting upright rod and is connected with the lower part of the Z-shaped material pushing block; the upper part of the Z-shaped material pushing block is higher than the upper surface of the diode storage space.

The feeding assembly comprises a horizontal feeding conveying section and a fan-shaped feeding section which are connected with each other; the discharging assembly comprises a horizontal material guiding section, a semi-arc turning material guiding section and a horizontal discharging conveying section which are sequentially connected with one another; the width of the turning and guiding section is larger than that of the horizontal guiding section; electric heating tubes are arranged on two opposite sides of the turning material guiding section along the radian direction of the turning material guiding section; a drying channel is formed between the electric heating tubes on the two opposite sides; the feeding direction of the horizontal feeding conveying section is the same as the discharging direction of the horizontal discharging conveying section; the horizontal material guiding section is located below the supporting columns.

Preferably, the subassembly of dotting includes sharp slip table, mounting panel, two flexible motors, two store up an ink section of thick bamboo, two and beat a pen, sharp slip table pass through the slide with the upper surface middle part of mounting panel is connected, two flexible motors is installed respectively the relative both sides of mounting panel lower surface, two store up an ink section of thick bamboo respectively with the power take off end of two flexible motors is connected, two beat a pen respectively with two store up the china ink mouth of an ink section of thick bamboo and connect.

Preferably, the diameter of the diode tube body is set to be A, the distance from the upper surface of the Z-shaped material pushing block to the upper surface of the diode storage space is set to be B, and B < A.

Preferably, the lower surface of the horizontal material guiding section is connected with a second electric telescopic rod through a convex block, and a power output end of the second electric telescopic rod penetrates through the convex block and extends towards one side, close to the outlet, of the upper part of the diode storage space.

Preferably, the power output end of the second electric telescopic rod is connected with a compression spring.

Preferably, a material blocking structure is arranged at a position, close to the fan-shaped feeding section, of the horizontal feeding conveying section through a connecting frame; the material blocking structure comprises a third electric telescopic rod, and a material blocking plate is connected to the power output end of the third electric telescopic rod.

The invention has the beneficial effects that: the diodes sequentially enter the diode storage space through the feeding assembly, when the diode storage space on the bearing plate rotates to the position of the dotting assembly, dotting is carried out by the dotting assembly, and then the diodes subjected to dotting are pushed into the discharging assembly by the auxiliary material pushing structure to be discharged, so that the problem that the diodes are scattered after being dotted is solved, the diodes can be automatically and orderly arranged and placed, preparation is also carried out for the later processing procedure, and discharging output is not required to be carried out by adopting a vibrating screen; when the diode enters the turning material guiding section, the auxiliary drying can be carried out on the ink on the pins at the two sides, so that the condition that the ink falls off or is scratched or damaged is also ensured; the structure only adds the action of pushing the diodes to the discharging component after the dispensing is finished, and the arrangement, arrangement and output of the diodes are synchronously realized during the operation, so that the efficient production and processing are ensured.

Drawings

Fig. 1 is a perspective view of the present invention.

Fig. 2 is a front view of the present invention.

Fig. 3 is a front view of the feeding assembly (with a blocking structure).

Fig. 4 is a front view of the present invention (with a mounting table).

The reference signs are: the device comprises a dotting component 10, a power output end 11 of a second electric telescopic rod, a horizontal material guiding section 12, a second electric telescopic rod 13, an electric heating tube 14, an overturning material guiding section 15, an L-shaped installation vertical rod 16, a driving gear 17, a rotary driving motor 18, a bearing 19, a driving plate 20, a first electric telescopic rod 21, a power output end 22 of the first electric telescopic rod, a diode storage space 23, a horizontal discharging conveying section 24, a lug 25, a horizontal feeding conveying section 26, a fan-shaped feeding section 27, a supporting column 28, a push-pull driving motor 29, a Z-shaped material pushing block 31, a connecting rod 30, a discharging component 32, a linear sliding table 36, an installation plate 35, a telescopic motor 39, an ink storage cylinder 34, a dotting pen 33, a connecting plate 37, a feeding component 38, a third electric telescopic rod 40, a material blocking plate 41, a connecting frame 42 and an installation table 43.

Detailed Description

For a better understanding of the features and technical solutions of the present invention, together with the specific objects and functions attained by the invention, reference is made to the following detailed description and accompanying drawings that form a part hereof.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Referring to fig. 1-4, the invention provides a high-efficiency diode dotting device with an automatic material arranging function, which comprises a dotting component 10, an aggregate component 45, a feeding component 38, a discharging component 32 and an auxiliary material pushing structure 46; dotting component 10 and pan feeding component 38 set up the relative both sides in subassembly 45 that gathers materials respectively, and ejection of compact subassembly 32 sets up with dotting component 10 homonymy.

The assembly 45 that gathers materials includes connecting plate 37, and the lateral surface circumference extension equipartition of connecting plate 37 is provided with four bearing board 44, and the upper surface of each bearing board 44 all encloses through baffle 43 and establishes formation diode parking space 23, and in this embodiment, every diode parking space 23 encloses by 4 baffles 43 with two liang of modes of placing side by side and establishes and form. The bottom of the bearing plate 44 is provided with a first electric telescopic rod 21, and the power output end 22 of the first electric telescopic rod penetrates through the bearing plate 44 and extends into the diode storage space 23; the diodes are sequentially stacked in the diode storage space 23, when dotting operation is performed, the power output end 22 of the first electric telescopic rod jacks the stacked diodes from the bottom to a predetermined height, so that the dotting component 10 can dotte the diodes at the top, and then the stacked diodes are continuously jacked to the predetermined height and then are pushed into the discharging component 32 by the auxiliary material pushing structure 46.

A support column abdicating hole is formed in the middle of the connecting plate 37, a bearing 19 is coaxially installed in the support column abdicating hole, a support column 28 is coaxially connected in the bearing 19 in a penetrating mode, and the support column 28 is installed on the production line through an installation platform 43. The upper part of the supporting column 28 extends out of the upper surface of the connecting plate 37, and the lower part of the supporting column 28 extends out of the lower surface of the connecting plate 37; the lower surface of the connecting plate 37 is convexly provided with a driving plate 20 around the coaxial center of the supporting column 28, the lower surface of the driving plate 20 is provided with a gear surface, one side of the lower part of the supporting column 28, which is close to the dotting assembly 10, is provided with a rotary driving motor 18, the power output end of the rotary driving motor 18 is connected with a driving gear 17 through an output shaft, and the driving gear 17 is meshed with the gear surface on the lower surface of the driving plate 20. In actual operation, the power output of the rotary driving motor 18 drives the driving gear 17 to rotate, the driving gear 17 rotates to synchronously drive the driving plate 20 to rotate, and the driving plate 20 synchronously drives the connecting plate 37 to rotate, so that the position of each diode storage space 23 is circularly changed.

The auxiliary material pushing structure 46 comprises an L-shaped mounting upright rod 16, a push-pull driving motor 29 and a Z-shaped material pushing block 31, wherein the L-shaped mounting upright rod 16 is mounted on the upper surface of the supporting column 28 and is arranged close to one side of the dotting component 10, connecting rods 30 are convexly arranged on two opposite sides of the upper part of the L-shaped mounting upright rod 16 close to the direction of the diode storage space 23, the lower part of the Z-shaped material pushing block 31 is arranged between the connecting rods 30 on the two sides, and a rotating shaft 47 which penetrates through the lower part of the Z-shaped material pushing block 31 and is rotatably connected with the Z-shaped material pushing block 31 is arranged between the connecting rods 30 on the two sides; the upper part of the L-shaped installation upright rod 16 is far away from one side of the diode storage space 23, and a push-pull driving motor 29 is installed at a position corresponding to the lower part of the Z-shaped material pushing block 31; the power output end of the push-pull driving motor 29 penetrates through the L-shaped mounting upright rod 16 and is connected with the lower part of the Z-shaped material pushing block 31; the upper portion of the Z-shaped pusher block 31 is higher than the upper surface of the diode storage space 23. The diameter of the diode tube body is set to be A, the distance between the upper surface of the Z-shaped material pushing block 31 and the upper surface of the diode storage space 23 is set to be B, and B < A. In actual operation, the power output of the push-pull driving motor 29 drives the Z-shaped material pushing block 31 to swing around the rotating shaft 47 as a rotating fulcrum, so as to push the diode pushed out of the diode storage space 23 into the horizontal material guiding section 12.

The feeding assembly 38 comprises a horizontal feeding conveying section 26 and a fan-shaped feeding section 27 which are connected with each other; the discharging component 32 comprises a horizontal material guiding section 12, a semi-arc turning material guiding section 15 and a horizontal discharging conveying section 24 which are sequentially connected with one another; the width of the turning material guiding section 15 is larger than that of the horizontal material guiding section 12. The feeding direction of the horizontal feeding conveying section 26 is the same as the discharging direction of the horizontal discharging conveying section 24; the horizontal guide section 12 is located below the support column 28. Through such structure setting, save the processing space, the equidirectional material loading and the ejection of compact only need set up a processing station and can monitor the material loading and the ejection of compact, saves the station.

The electric heating tubes 14 are arranged on the two opposite sides of the turning material guiding section 15 along the radian direction; a drying channel is formed between the electric heating tubes 14 at two opposite sides. After the diode enters the overturning material guide section 15, the pins on the two sides of the diode are positioned in the drying channel, and the diode is dried in the process of passing through the drying channel, so that the drying speed of the ink on one pin of the diode is accelerated.

The dotting component 10 comprises a linear sliding table 36, a mounting plate 35, two telescopic motors 39, two ink storage cylinders 34 and two dotting pens 33, wherein the linear sliding table 36 is connected with the middle part of the upper surface of the mounting plate 35 through a sliding seat, the two telescopic motors 39 are respectively mounted on two opposite sides of the lower surface of the mounting plate 35, the two ink storage cylinders 34 are respectively connected with power output ends of the two telescopic motors 39, and the two dotting pens 33 are respectively connected with ink outlets of the two ink storage cylinders 34. The linear sliding table 36 can drive the two telescopic motors 39, the two ink storage cylinders 34 and the two dotting pens 33 to move back and forth along the length direction of the linear sliding table through the mounting plate 35, when dotting operation is needed, the two telescopic motors 39 drive the two ink storage cylinders 34 and the two dotting pens 33 to move downwards to a preset height to allow the two dotting pens 33 to dotte, after the dotting operation is completed, the two telescopic motors 39 drive the two ink storage cylinders 34 and the two dotting pens 33 to reset, and the operation is repeated.

The lower surface of the horizontal material guiding section 12 is connected with a second electric telescopic rod 13 through a convex block 25, and a power output end 11 of the second electric telescopic rod penetrates through the convex block 25 and extends towards one side of the upper part of the diode storage space 23 close to the outlet. In actual operation, before dotting the assembly 10, the power output end 11 of the second electric telescopic rod presses the diode at the corresponding position into the diode storage space 23, so that the stability of the diode during dotting operation is ensured, and the dotting quality is improved. In order to avoid the diode from being damaged by pressure, the power output end of the second electric telescopic rod 13 is connected with a compression spring, and the compression spring is in contact with the diode, so that the compression acting force on the diode is effectively reduced.

The horizontal feeding conveying section 26 is provided with a material blocking structure at a position close to the fan-shaped feeding section 27 through a connecting frame 42; the material blocking structure comprises a third electric telescopic rod 40, and the power output end of the third electric telescopic rod is connected with a material blocking plate 41. In actual operation, the power output end of the third electric telescopic rod drives the material baffle plate 41 to descend, so that the horizontal feeding conveying section 26 is blocked, and feeding is temporarily performed, so that the position of the diode storage space 23 can be replaced.

In the invention, diodes sequentially enter the diode storage space through the feeding assembly, when the diode storage space which finishes charging rotates to the position of the dotting assembly, the power output end 11 of the second electric telescopic rod tightly presses the diodes at the corresponding positions, the dotting assembly performs dotting, and then the auxiliary material pushing structure pushes the diodes which finish dotting into the discharging assembly for discharging.

The diode sorting device solves the problem that the diodes are scattered and placed after being dotted, the diodes can be automatically placed in order, preparation is made for the later processing procedure, and discharging output is not needed to be carried out by adopting a vibrating screen; when the diode enters the turning material guiding section, the auxiliary drying can be carried out on the ink on the pins at the two sides, so that the condition that the ink falls off or is scratched or damaged is also ensured; the structure only adds the action of pushing the diodes to the discharging component after the dispensing is finished, and the arrangement, arrangement and output of the diodes are synchronously realized during the operation, so that the efficient production and processing are ensured.

The above-mentioned embodiments only express one embodiment of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (6)

1. The utility model provides a take automatic material all in one piece function's high efficiency diode equipment of dotting, is including dotting subassembly (10), its characterized in that: the device also comprises a material collecting component (45), a material feeding component (38), a material discharging component (32) and an auxiliary material pushing structure (46); the dotting component (10) and the feeding component (38) are respectively arranged on two opposite sides of the collecting component (45), and the discharging component (32) and the dotting component (10) are arranged on the same side;

the aggregate assembly (45) comprises a connecting plate (37), four supporting plates (44) are uniformly arranged on the outer side surface of the connecting plate (37) in a circumferential extending mode, the upper surface of each supporting plate (44) is surrounded by a baffle (43) to form a diode storage space (23), a first electric telescopic rod (21) is installed at the bottom of each supporting plate (44), and a power output end (22) of each first electric telescopic rod penetrates through each supporting plate (44) and extends into the diode storage space (23); a support column abdicating hole is formed in the middle of the connecting plate (37), a bearing (19) is coaxially and concentrically arranged in the support column abdicating hole, and a support column (28) is coaxially and concentrically connected in the bearing (19) in a penetrating manner; the upper part of the supporting column (28) extends out of the upper surface of the connecting plate (37), and the lower part of the supporting column (28) extends out of the lower surface of the connecting plate (37); a driving plate (20) is convexly arranged on the lower surface of the connecting plate (37) around the coaxial center of the supporting column (28), the lower surface of the driving plate (20) is a gear surface, a rotary driving motor (18) is arranged on one side, close to the dotting assembly (10), of the lower portion of the supporting column (28), the power output end of the rotary driving motor (18) is connected with a driving gear (17) through an output shaft, and the driving gear (17) is meshed with the gear surface on the lower surface of the driving plate (20);

the auxiliary material pushing structure (46) comprises an L-shaped mounting vertical rod (16), a push-pull driving motor (29) and a Z-shaped material pushing block (31), the L-shaped mounting vertical rod (16) is mounted on the upper surface of the supporting column (28) and arranged close to one side of the dotting component (10), connecting rods (30) are convexly arranged on two opposite sides of the upper portion of the L-shaped mounting vertical rod (16) close to the direction of the diode storage space (23), the lower portion of the Z-shaped material pushing block (31) is arranged between the connecting rods (30) on two sides, and a rotating shaft (47) which penetrates through the lower portion of the Z-shaped material pushing block (31) and is rotatably connected with the Z-shaped material pushing block (31) is arranged between the connecting rods (30) on two sides; the upper part of the L-shaped installation upright rod (16) is far away from one side of the diode storage space (23) and a push-pull driving motor (29) is installed at the position corresponding to the lower part of the Z-shaped pushing block (31); the power output end of the push-pull driving motor (29) penetrates through the L-shaped mounting upright rod (16) and is connected with the lower part of the Z-shaped material pushing block (31); the upper part of the Z-shaped material pushing block (31) is higher than the upper surface of the diode storage space (23);

the feeding assembly (38) comprises a horizontal feeding conveying section (26) and a fan-shaped feeding section (27) which are connected with each other;

the discharging assembly (32) comprises a horizontal material guiding section (12), a semi-arc turning material guiding section (15) and a horizontal discharging conveying section (24) which are sequentially connected with one another; the width of the turning and guiding section (15) is larger than that of the horizontal guiding section (12); the electric heating tubes (14) are arranged on two opposite sides of the turning material guiding section (15) along the radian direction of the turning material guiding section; a drying channel is formed between the electric heating tubes (14) at two opposite sides;

the feeding direction of the horizontal feeding conveying section (26) is the same as the discharging direction of the horizontal discharging conveying section (24); the horizontal guide section (12) is positioned below the supporting column (28).

2. The high-efficiency diode dotting equipment with the automatic material adjusting function as claimed in claim 1, characterized in that: beat subassembly (10) and include sharp slip table (36), mounting panel (35), two flexible motor (39), two storage ink cartridge (34), two beat pen (33), sharp slip table (36) through the slide with the upper surface middle part of mounting panel (35) is connected, two flexible motor (39) are installed respectively the relative both sides of mounting panel (35) lower surface, two store up ink cartridge (34) respectively with the power take off end of two flexible motor (39) is connected, two beat pen (33) respectively with two the china ink outlet of storing up ink cartridge (34) is connected.

3. The high-efficiency diode dotting equipment with the automatic material adjusting function according to claim 1, characterized in that: the diameter of the diode tube body is set to be A, the distance between the upper surface of the Z-shaped pushing block (31) and the upper surface of the diode storage space (23) is set to be B, and B < A.

4. The high-efficiency diode dotting equipment with the automatic material adjusting function as claimed in claim 2, characterized in that: the lower surface of the horizontal material guiding section (12) is connected with a second electric telescopic rod (13) through a convex block (25), and a power output end (11) of the second electric telescopic rod penetrates through the convex block (25) and extends towards one side, close to the outlet, of the upper portion of the diode storage space (23).

5. The high-efficiency diode dotting equipment with the automatic material adjusting function according to claim 4, characterized in that: and the power output end of the second electric telescopic rod (13) is connected with a compression spring.

6. The high-efficiency diode dotting equipment with the automatic material adjusting function according to claim 5, wherein: a material blocking structure is arranged at the position, close to the fan-shaped feeding section (27), of the horizontal feeding conveying section (26) through a connecting frame (42); the material blocking structure comprises a third electric telescopic rod (40), and a power output end of the third electric telescopic rod is connected with a material blocking plate (41).

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