CN114986587A - Hybrid circuit parts manufacturing device for energy-saving equipment assembly - Google Patents

Abstract

The invention relates to the technical field of auxiliary devices for circuit board production, in particular to a hybrid circuit part manufacturing device applied to energy-saving equipment assembly. According to the automatic feeding device, along with the rotation of the roller, the movable seat drives the platform to horizontally move through the matching effect of the chute structure and the guide post, so that the circuit board raw materials are fed, the automation degree is high, the labor intensity of workers is effectively reduced, and the working efficiency is improved.

Description

Hybrid circuit parts manufacturing device for energy-saving equipment assembly

technical field

The invention relates to the technical field of circuit board production accessories, in particular to a hybrid circuit component manufacturing device applied to the assembly of energy-saving equipment.

Background technique

The circuit board is a very important component in the hybrid circuit components. In the process of producing the circuit board, the circuit board material needs to be cut according to the specified size. At present, the method of cutting the circuit board material is to first cut the circuit board material. The raw material is fixed on the worktable, and then the staff cuts the raw material of the circuit board with a cutter. However, the existing method of cutting the circuit board manually cuts the circuit board, and the labor intensity of the staff is relatively large, which leads to their work. less efficient.

SUMMARY OF THE INVENTION

The main purpose of the present invention is to provide a hybrid circuit component manufacturing device applied to the assembly of energy-saving equipment, so as to effectively solve the problems pointed out in the background art.

In order to achieve the above object, the technical scheme adopted in the present invention is:

The hybrid circuit component manufacturing device applied to the assembly of energy-saving equipment includes a bottom plate, a roller and a moving seat, the roller is installed on the bottom plate in a horizontal manner, and a chute structure is arranged on the outer circumferential wall of the roller. The movable seat is elastically slidably installed on the bottom plate, the end of the movable seat facing the roller is fixedly provided with a guide column, the end of the guide column facing away from the movable seat is slidably installed in the chute structure, and the movable seat is fixedly provided with a guide column. A platform, an eccentric wheel is fixed coaxially at one end of the roller, a sliding seat is horizontally slidable above the platform, and one end of the sliding seat facing the eccentric wheel is in sliding contact with the circumferential outer wall of the eccentric wheel, and the sliding seat A cutting assembly is fixedly arranged on the upper part.

Further, the chute structure includes a spiral part, an arc part and a straight part, the spiral part is located in the upper half of the outer circumferential wall of the drum, the arc part is located in the lower half of the outer circumferential wall of the drum, the One end of the arc part is communicated with one end of the helical part, the other end of the arc part is communicated with the other end of the helical part through a straight chute, and the end of the outer wall of the eccentric circumference close to the center of the circle faces the highest point of the helical part, so The end of the peripheral outer wall of the eccentric that is far from the center of the circle faces the lowest point of the arc portion.

Further, a support plate is fixed on the bottom plate, a guide plate is slidably arranged on the support plate, a limit plate is fixed at one end of the guide plate facing away from the eccentric wheel, and the bottom end of the guide plate is close to the eccentric wheel. A fixing block is fixed at the position of the sliding seat, the bottom end of the fixing block is fixedly connected with the top end of the sliding seat, a first spring is arranged between the fixing block and the support plate, and the bottom end of the sliding seat is provided with a mounting groove; The cutting assembly includes a first motor, the first motor is fixedly installed in the installation slot, the output end of the first motor is provided with an output shaft, and the end of the output shaft facing away from the first motor is fixedly provided with a cutting knife.

Further, a guide rail is fixedly arranged on the bottom plate, the movable seat is slidably installed on the guide rail, a fixed plate is fixedly arranged on the bottom plate, and a sliding column is slidably arranged on the fixed plate, and the sliding column moves toward One end of the seat is fixedly connected with the movable seat, a second spring is fixedly arranged between the fixed plate and the movable seat, the second spring is sleeved outside the sliding column, and the end of the sliding column facing away from the movable seat is fixedly provided with a second spring. bezel.

Further, two stabilizing plates are arranged on the bottom plate, the positions of the two stabilizing plates are symmetrical, a top plate is fixedly arranged at the top of the two stabilizing plates, a cylinder is fixedly arranged on the top plate, and the output end of the cylinder is arranged There is a telescopic shaft, the telescopic shaft slides through the top plate, the end of the telescopic shaft facing away from the cylinder is fixed with a pressure plate, the end of the pressure plate facing away from the telescopic shaft is provided with anti-skid patterns, and the top plate is fixed with a mounting frame, The cylinder is fixed on the top plate through a mounting bracket.

Further, a support frame is fixedly arranged on the bottom plate, a rotating shaft is rotatably arranged on the support frame, the roller is fixedly sleeved on the rotating shaft, and a through hole is provided at the center of the eccentric wheel, and the through hole is arranged at the center of the eccentric wheel. The inner diameter of the hole is larger than the outer diameter of the rotating shaft, a second motor is fixedly arranged on the bottom plate, a transmission shaft is arranged at the output end of the second motor, and a driving wheel is fixedly arranged at the end of the transmission shaft facing away from the second motor. A driven wheel is fixedly sleeved on the circumferential outer wall of the rotating shaft, and a belt is sleeved on the drive wheel and the driven wheel.

Further, the top of the guide rail is fixedly provided with stoppers at positions close to the two ends.

Further, the end of the sliding seat facing the eccentric wheel is provided with an arc structure, the arc structure of the sliding seat is in contact with the circumferential outer wall of the eccentric wheel, and the contact form between the sliding seat and the eccentric wheel is line contact.

After adopting the above-mentioned technical scheme, the beneficial effects of the present invention are:

Firstly, the circuit board raw material is placed on the platform. With the rotation of the roller, through the cooperation of the chute structure and the guide column, the movable seat drives the platform to move horizontally to realize the feeding of the circuit board raw material. When the platform reaches the designated position After that, the eccentric wheel drives the cutting assembly to reciprocate once to automatically complete the cutting of the circuit board raw materials. The degree of automation is high, which effectively reduces the labor intensity of the staff and improves the work efficiency.

Description of drawings

In order to explain the embodiments of the present invention or the technical solutions in the prior art more clearly, the following briefly introduces the accompanying drawings that need to be used in the description of the embodiments or the prior art. Obviously, the accompanying drawings in the following description are only These are some embodiments described in the present invention. For those of ordinary skill in the art, other drawings can also be obtained based on these drawings without any creative effort.

Fig. 1 is the schematic perspective view of the right front apex angle downward oblique view structure of the present invention;

2 is a schematic front plan view of the structure of the present invention;

Figure 3 is a schematic perspective view of a part of the structure at the sliding seat of the present invention, which is obliquely viewed from the left front apex;

4 is a schematic perspective view of the structure of the bottom right rear top angle downward oblique view of the connection diagram of the bottom plate, the stabilization plate, the top plate, the cylinder, the telescopic shaft, the pressure plate and the mounting frame of the present invention;

5 is a schematic top view of the overall structure of the present invention;

Reference numerals: 1. Bottom plate; 2. Roller; 3. Moving seat; 4. Guide column; 5. Platform; 6. Eccentric wheel; 7. Sliding seat; 8. Spiral part; 9. Arc part; Linear part; 11, support plate; 12, guide plate; 13, limit plate; 14, fixed block; 15, first spring; 16, first motor; 17, output shaft; 18, cutting knife; 19, guide rail; 20, fixed plate; 21, sliding column; 22, second spring; 23, baffle plate; 24, stabilization plate; 25, top plate; 26, cylinder; 27, telescopic shaft; 28, pressure plate; 29, anti-skid pattern; 30, Mounting frame; 31, support frame; 32, shaft; 33, through hole; 34, second motor; 35, transmission shaft; 36, driving wheel; 37, driven wheel; 38, belt; 39, stopper.

Detailed ways

The specific embodiments of the present invention will be described in further detail below with reference to the accompanying drawings and embodiments. The following examples are intended to illustrate the present invention, but not to limit the scope of the present invention.

In the hybrid circuit component manufacturing device of the present invention applied to the assembly of energy-saving equipment, the installation methods, connection methods or setting methods of all the above-mentioned components are common mechanical methods, and the specific structures, models and coefficient indicators of all the components are Its own technology can be implemented as long as it can achieve its beneficial effects, so it will not be repeated.

In the hybrid circuit component manufacturing apparatus applied to the assembly of energy-saving equipment of the present invention, unless otherwise stated, the orientation words included in the term, such as "up and down, left and right, front and rear, inside and outside, and vertical and horizontal" only represent that the term is used conventionally. The orientation under the state, or the common name understood by those skilled in the art, should not be regarded as a limitation of the term. The number and order of the terms are used for name distinction only, and the terms "comprising", "comprising" or any other variation thereof are intended to encompass a non-exclusive inclusion such that a process, method, article or Apparatus includes not only those elements, but also other elements not expressly listed or inherent to such a process, method, article or apparatus.

As shown in Figure 1-5, the hybrid circuit component manufacturing device applied to the assembly of energy-saving equipment includes a bottom plate 1, a roller 2 and a moving base 3. The outer wall is provided with a chute structure, the movable seat 3 is elastically slidably installed on the bottom plate 1, the end of the movable seat 3 facing the roller 2 is fixedly provided with a guide column 4, and the end of the guide column 4 facing away from the movable seat 3 is slidably installed on the chute. In the structure, a platform 5 is fixed on the movable seat 3, an eccentric wheel 6 is fixed coaxially at one end of the roller 2, a sliding seat 7 is slid horizontally above the platform 5, and one end of the sliding seat 7 is facing the eccentric wheel 6 and the eccentric wheel. The circumferential outer wall of the wheel 6 is in sliding contact, and a cutting assembly is fixed on the sliding seat 7 .

In the process of use, first place the circuit board raw material on the platform 5, and with the rotation of the roller 2, through the cooperation of the chute structure and the guide column 4, the movable seat 3 drives the platform 5 to move horizontally, so as to realize the control of the circuit board. For the feeding of raw materials, when the platform 5 reaches the designated position, the eccentric wheel 6 drives the cutting assembly to reciprocate once, and automatically completes the cutting of the raw materials of the circuit board. The degree of automation is high, which effectively reduces the labor intensity of the staff and improves the work efficiency.

As a preferred example of the above embodiment, the chute structure includes a spiral portion 8 , an arc portion 9 and a straight portion 10 . The spiral portion 8 is located at the upper half of the circumferential outer wall of the drum 2 , and the arc portion 9 is located at the lower portion of the circumferential outer wall of the drum 2 . Half, one end of the arc part 9 is communicated with one end of the helical part 8, the other end of the arc part 9 is communicated with the other end of the helical part 8 through a straight chute, and one end of the outer wall of the eccentric 6 near the center of the circle faces the helical part 8 The highest point of the eccentric wheel 6, the end of the outer wall of the eccentric 6 away from the center of the circle faces the lowest point of the arc part 9.

During use, when the guide post 4 is located at the junction of the straight part 10 and the helical part 8, the platform 5 at this time is at the initial position. During the rotation of the roller 2, the guide post 4 first slides along the helical part 8, so that the guide The column 4 slides horizontally, and the guide column 4 drives the moving base 3, the platform 5 and the circuit board material on the platform 5 to move horizontally. When the guide column 4 slides into the arc part 9 from the spiral part 8, the roller 2 also Continue to rotate while the platform 5 remains stationary. At this time, under the action of the eccentric wheel 6, the cutting assembly reciprocates once to realize the cutting of the raw material of the circuit board. Slide into the straight part 10, at this time, the moving base 3 returns to the initial position under the elastic reset force, the staff only needs to remove the circuit board that has been cut on the platform 5 and place the new circuit board material on the platform 5. That is, the feeding and cutting of the circuit board are automatically completed by mechanical means, with a high degree of automation and high work efficiency.

As a preference of the above-mentioned embodiment, a support plate 11 is fixedly arranged on the bottom plate 1 , a guide plate 12 is slidably arranged on the support plate 11 , and a limit plate 13 is fixedly arranged at the end of the guide plate 12 facing away from the eccentric wheel 6 , and the bottom of the guide plate 12 is fixed with a limit plate 13 . A fixing block 14 is fixedly arranged at the position where the end is close to the eccentric wheel 6 , the bottom end of the fixing block 14 is fixedly connected with the top end of the sliding seat 7 , a first spring 15 is arranged between the fixing block 14 and the support plate 11 , and the bottom end of the sliding seat 7 is arranged There is an installation slot; the cutting assembly includes a first motor 16, the first motor 16 is fixedly installed in the installation slot, the output end of the first motor 16 is provided with an output shaft 17, and the end of the output shaft 17 facing away from the first motor 16 is fixedly provided with a cutting Knife 18.

During use, during the rotation of the eccentric wheel 6, due to the structural characteristics of the eccentric wheel 6, the sliding seat 7 reciprocates and translates, the sliding seat 7 drives the cutting assembly to reciprocate, and the first motor 16 in the cutting assembly drives the cutting knife 18 to rotate , the circuit board raw material is cut by the reciprocating cutting knife 18, the degree of automation is high, and the work efficiency is high.

As a preferable example of the above embodiment, a guide rail 19 is fixedly arranged on the base plate 1 , the movable base 3 is slidably installed on the guide rail 19 , a fixed plate 20 is fixedly arranged on the base plate 1 , and a sliding column 21 is slidably arranged on the fixed plate 20 . One end of 21 facing the movable seat 3 is fixedly connected with the movable seat 3, a second spring 22 is fixedly arranged between the fixed plate 20 and the movable seat 3, the second spring 22 is sleeved outside the sliding column 21, and the sliding column 21 faces away from the movable seat One end of 3 is fixedly provided with a baffle 23 .

During use, the movable seat 3 slides along the guide rail 19. During the horizontal movement of the movable seat 3, when the guide column 4 slides into the linear portion 10, due to the elastic deformation force of the second spring 22, the movable seat 3 moves. The seat 3 returns to the initial position to complete a feeding and cutting operation, and the work efficiency is high.

As a preference of the above embodiment, two stabilizing plates 24 are provided on the bottom plate 1, the two stabilizing plates 24 are symmetrical in position, a top plate 25 is fixedly arranged at the top of the two stabilizing plates 24, and a cylinder 26 is fixedly arranged on the top plate 25, and the cylinder 26 outputs The end is provided with a telescopic shaft 27, the telescopic shaft 27 slides through the top plate 25, the end of the telescopic shaft 27 facing away from the cylinder 26 is fixedly provided with a pressure plate 28, the end of the pressure plate 28 facing away from the telescopic shaft 27 is provided with anti-skid lines 29, and the top plate 25 is fixedly arranged There is a mounting bracket 30 , and the cylinder 26 is fixed on the top plate 25 through the mounting bracket 30 .

During use, when the moving base 3 and the platform 5 are driven to the designated station, at this time, the cylinder 26 drives the pressing plate 28 to move downward through the telescopic shaft 27, and the pressing plate 28 moves downward to contact with the circuit board raw material, The pressing plate 28 presses the raw material of the circuit board on the platform 5, and the effect of pressing the raw material of the circuit board can be enhanced by the action of the anti-skid pattern 29, and the reliability of use can be improved.

As a preference of the above-mentioned embodiment, a support frame 31 is fixedly arranged on the bottom plate 1, a rotating shaft 32 is rotatably arranged on the support frame 31, the roller 2 is fixedly sleeved on the rotating shaft 32, and a through hole 33 is disposed at the center of the eccentric wheel 6 , the inner diameter of the through hole 33 is larger than the outer diameter of the rotating shaft 32, a second motor 34 is fixedly arranged on the bottom plate 1, the output end of the second motor 34 is provided with a transmission shaft 35, and the end of the transmission shaft 35 facing away from the second motor 34 is fixedly provided with a transmission shaft 35. The driving wheel 36 and the peripheral outer wall of the rotating shaft 32 are fixedly sleeved with a driven wheel 37 , and the driving wheel 36 and the driven wheel 37 are provided with a belt 38 on the transmission sleeve.

During use, the second motor 34 drives the rotating shaft 32 to rotate through the driving pulley 36, the driven pulley 37 and the belt 38, and the rotating shaft 32 drives the roller 2 and the eccentric wheel 6 to rotate synchronously, thereby realizing the feeding and cutting of the circuit board raw materials, Improve work efficiency.

As a preferable example of the above-mentioned embodiment, the top end of the guide rail 19 is fixedly provided with a stopper 39 at the position close to the two ends.

During use, the stopper 39 can limit the position of the movable base 3 to prevent the movable base 3 from separating from the guide rail 19 and improve the reliability of use.

As a preference of the above embodiment, the end of the sliding seat 7 facing the eccentric wheel 6 is provided with an arc-shaped structure, the arc-shaped structure of the sliding seat 7 is in contact with the circumferential outer wall of the eccentric wheel 6, and the contact form between the sliding seat 7 and the eccentric wheel 6 is a line touch.

During use, the arc-shaped structure makes the contact form between the sliding seat 7 and the eccentric wheel 6 change to line contact, which can reduce frictional resistance and improve ride comfort.

The above are only the preferred embodiments of the present invention. It should be pointed out that for those skilled in the art, without departing from the technical principles of the present invention, several improvements and modifications can also be made. These improvements and modifications It should also be regarded as the protection scope of the present invention.

Claims (8)

1. A hybrid circuit component manufacturing device applied to the assembly of energy-saving equipment, characterized in that it comprises a bottom plate (1), a roller (2) and a moving seat (3), and the roller (2) is installed horizontally and rotatably On the bottom plate (1), the outer circumferential wall of the roller (2) is provided with a chute structure, the moving seat (3) is elastically slidably mounted on the bottom plate (1), and the moving seat (3) faces the roller One end of the cylinder (2) is fixedly provided with a guide column (4), and one end of the guide column (4) facing away from the moving seat (3) is slidably installed in the chute structure, and the moving seat (3) is fixedly provided with a guide column (4). A platform (5), an eccentric wheel (6) is fixed coaxially at one end of the roller (2), a sliding seat (7) is horizontally slidable above the platform (5), and the sliding seat (7) The end facing the eccentric wheel (6) is in sliding contact with the circumferential outer wall of the eccentric wheel (6), and a cutting assembly is fixed on the sliding seat (7). 2. The hybrid circuit component manufacturing device applied to the assembly of energy-saving equipment according to claim 1, wherein the chute structure comprises a spiral part (8), an arc part (9) and a straight part (10) , the spiral part (8) is located in the upper half of the outer circumferential wall of the drum (2), the arc part (9) is located in the lower half of the outer circumferential wall of the drum (2), the arc part (9) One end of the eccentric wheel (6) is connected to one end of the spiral part (8), the other end of the arc part (9) is connected to the other end of the spiral part (8) through a linear chute, and the outer circumferential wall of the eccentric wheel (6) is close to the center of the circle. One end faces the highest point of the spiral part (8), and the end of the outer circumferential wall of the eccentric wheel (6) away from the center of the circle faces the lowest point of the arc part (9). 3 . The hybrid circuit component manufacturing device applied to the assembly of energy-saving equipment according to claim 1 , wherein a support plate ( 11 ) is fixedly arranged on the bottom plate ( 1 ), and a support plate ( 11 ) is fixed on the support plate ( 11 ). 4 . A guide plate (12) is provided in the sliding through, the end of the guide plate (12) facing away from the eccentric wheel (6) is fixedly provided with a limit plate (13), and the bottom end of the guide plate (12) is close to the eccentric wheel (6) A fixing block (14) is fixedly arranged at the position of the fixing block (14), the bottom end of the fixing block (14) is fixedly connected with the top end of the sliding seat (7), and a first the spring (15), the bottom end of the sliding seat (7) is provided with a mounting groove; The cutting assembly includes a first motor (16), the first motor (16) is fixedly installed in the installation groove, an output shaft (17) is provided at the output end of the first motor (16), and the output shaft ( 17) The end facing away from the first motor (16) is fixedly provided with a cutting knife (18). 4 . The hybrid circuit component manufacturing device applied to the assembly of energy-saving equipment according to claim 1 , wherein a guide rail ( 19 ) is fixedly arranged on the bottom plate ( 1 ), and the movable seat ( 3 ) is slidably installed. 5 . On the guide rail (19), a fixing plate (20) is fixedly arranged on the bottom plate (1), and a sliding column (21) is slidably arranged on the fixing plate (20), and the sliding column (21) moves toward One end of the seat (3) is fixedly connected to the movable seat (3), a second spring (22) is fixedly arranged between the fixed plate (20) and the movable seat (3), and the second spring (22) is sleeved Outside the sliding column (21), a baffle plate (23) is fixedly arranged at one end of the sliding column (21) facing away from the moving seat (3). 5 . The hybrid circuit component manufacturing device applied to the assembly of energy-saving equipment according to claim 1 , wherein two stabilizing plates ( 24 ) are provided on the bottom plate ( 1 ), and the two stabilizing plates ( 24) The positions are symmetrical, a top plate (25) is fixedly arranged at the top of the two stabilizing plates (24), a cylinder (26) is fixedly arranged on the top plate (25), and an output end of the cylinder (26) is provided with a telescopic shaft (27), the telescopic shaft (27) slides through the top plate (25), the end of the telescopic shaft (27) facing away from the cylinder (26) is fixedly provided with a pressure plate (28), and the pressure plate (28) faces away from the telescopic One end of the shaft (27) is provided with an anti-skid pattern (29), a mounting bracket (30) is fixed on the top plate (25), and the cylinder (26) is fixed on the top plate (25) through the mounting bracket (30). 6 . The hybrid circuit component manufacturing device applied to the assembly of energy-saving equipment according to claim 1 , wherein a support frame ( 31 ) is fixedly arranged on the bottom plate ( 1 ), and the support frame ( 31 ) is fixed on the support frame ( 31 ). 7 . A rotating shaft (32) is rotatably provided, the roller (2) is fixedly sleeved on the rotating shaft (32), and a through hole (33) is provided at the center of the eccentric wheel (6). ) is larger than the outer diameter of the rotating shaft (32), a second motor (34) is fixedly arranged on the bottom plate (1), and a transmission shaft (35) is arranged at the output end of the second motor (34). The end of the shaft (35) facing away from the second motor (34) is fixedly provided with a driving wheel (36), and a driven wheel (37) is fixedly sleeved on the circumferential outer wall of the rotating shaft (32). A belt (38) is provided on the transmission sleeve and the driven wheel (37). 7 . The hybrid circuit component manufacturing device applied to the assembly of energy-saving equipment according to claim 4 , wherein the top of the guide rail ( 19 ) is fixedly provided with stoppers ( 39 ) at positions close to both ends. 8 . 8 . The hybrid circuit component manufacturing device applied to the assembly of energy-saving equipment according to claim 1 , wherein the sliding seat ( 7 ) is provided with an arc-shaped structure at one end of the sliding seat ( 7 ) facing the eccentric wheel ( 6 ). 9 . The arc structure of the seat (7) is in contact with the circumferential outer wall of the eccentric wheel (6), and the contact form between the sliding seat (7) and the eccentric wheel (6) is line contact.

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