CN221736329U - Positioning assembly and high-to-low auxiliary source generation plate - Google Patents

Abstract

The utility model discloses a positioning assembly and a high-rotation low-auxiliary source generating plate, which comprises a mounting shell, wherein two groups of through grooves are symmetrically formed in the top of the mounting shell, linkage assemblies are respectively arranged in the two groups of through grooves, two groups of rotating seats are fixedly arranged in the inner bottom of the mounting shell and symmetrically arranged, the high-rotation low-auxiliary source generating plate to be drilled is clamped and positioned through the cooperation of the mounting shell, the linkage assemblies and a driving assembly, the shifting condition in the drilling process is avoided, the stability of drilling operation is improved, the drilling yield can be further improved, the limiting effect of the linkage assemblies is realized through the arrangement of the through grooves, the operation process is more stable, the clamping stability of the high-rotation low-auxiliary source generating plate is improved, and the supporting and positioning effects of the driving assembly are realized through the arrangement of the rotating seats.

Description

A positioning component and a high-to-low auxiliary source generation board

Technical Field

The utility model relates to the technical field of high-to-low auxiliary source generation plate processing, in particular to a positioning component and a high-to-low auxiliary source generation plate.

Background Art

A high-to-low auxiliary source generation board is an auxiliary source generation board used to convert high voltage or high current signals into low voltage or low current signals. This board is usually used in electronic devices to provide stable low voltage or low current signals to drive other circuits or components. The design and manufacture of the high-to-low auxiliary source generation board need to consider multiple factors, including input voltage, output voltage, current, accuracy, stability, noise and reliability. During the design and manufacturing process, it is necessary to select appropriate electronic components and circuit designs to ensure the performance and stability of the high-to-low auxiliary source generation board.

In the production process of the high-to-low auxiliary source generation board, drilling is a common step. The main purpose of drilling is to establish a conductive path on the high-to-low auxiliary source generation board so that electronic components can be connected to the other side of the high-to-low auxiliary source generation board through these holes. However, the existing high-to-low auxiliary source generation board lacks an effective positioning mechanism during drilling. During actual operation, the high-to-low auxiliary source generation board is prone to offset, resulting in a low drilling yield rate. Therefore, we need to propose a positioning component and a high-to-low auxiliary source generation board.

Utility Model Content

The purpose of the utility model is to provide a positioning component and a high-to-low auxiliary source generating plate, aiming to solve the problem that the high-to-low auxiliary source generating plate in the prior art lacks an effective positioning mechanism when drilling, and the high-to-low auxiliary source generating plate is prone to offset during actual operation, resulting in a low drilling yield rate.

In order to achieve the above purpose, the utility model provides the following technical solutions:

A positioning component comprises a mounting shell, wherein the top of the mounting shell is symmetrically provided with two groups of through grooves, linkage components are respectively arranged inside the two groups of through grooves, and two groups of rotating seats are fixedly installed on the inner bottom of the mounting shell, the two groups of rotating seats are symmetrically arranged, and driving components for providing power for the linkage components to clamp and position the products to be drilled are arranged on the side walls on the opposite sides of the two groups of rotating seats, and the linkage components are installed on the moving end of the driving components.

Preferably, the driving assembly includes a worm, both ends of which are rotatably mounted on the side walls of opposite sides of the two groups of rotating seats, one end of the worm passes through one of the groups of rotating seats and is connected to a driving motor, a worm wheel is meshed with the top of the worm, a bidirectional lead screw is fixedly inserted inside the worm wheel, both ends of the bidirectional lead screw are rotatably mounted on the inner walls of both sides of the mounting shell, two groups of driving blocks are symmetrically threaded on the outer wall of the bidirectional lead screw, and the two groups of linkage components are respectively arranged on the top of the two groups of driving blocks.

Preferably, the driving motor is fixedly mounted on a side wall of one group of rotating seats, and one end of the output shaft of the driving motor is fixedly connected to one end of the worm.

Preferably, the linkage assembly comprises a connecting block, the connecting block is fixedly mounted on the top of the driving block, and the connecting block is slidably connected to the inside of the through slot, and a clamping plate is fixedly connected to the top of the connecting block.

Preferably, a first linear slide is provided below the mounting shell, a first slider is slidably mounted on the first linear slide, and the mounting shell is fixedly mounted on the top of the first slider.

Preferably, two groups of reinforcing rods are fixedly connected to the side walls on both sides of the first sliding block, and the top ends of the two groups of reinforcing rods are fixedly connected to the bottom of the mounting shell.

Preferably, a positioning plate is provided below the first linear slide, and two groups of second linear slides are symmetrically fixedly installed on the top of the positioning plate, and second sliders are slidably installed on the top of the two groups of second linear slides, respectively, and a supporting plate is fixedly installed on the top of the two groups of second sliders, and the first linear slide is fixedly installed on the top of the supporting plate.

A high-to-low auxiliary source generation plate comprises a positioning assembly and a generation plate body. Both sides of the generation plate body are sleeved with padding blocks, and one side of two groups of the padding blocks are respectively in contact with one side wall of a clamping plate.

Compared with the prior art, the beneficial effects of the utility model are:

The utility model plays the role of clamping and positioning the high-to-low auxiliary source generating plate to be drilled by setting the coordinated use of the mounting shell, the linkage component and the driving component, thereby avoiding the situation of deviation during the drilling process, which is beneficial to improving the stability of the drilling operation and can further improve the drilling yield rate. By setting the through groove, it plays the role of limiting the linkage component, making it more stable during operation, which is beneficial to improving the clamping stability of the high-to-low auxiliary source generating plate. By setting the rotating seat, it plays the role of supporting and positioning the driving component.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a schematic diagram of the structure of the utility model;

FIG2 is a schematic structural diagram of a first linear slide and a mounting shell of the utility model;

FIG3 is a schematic diagram of the structure of the installation shell and the generating plate body of the utility model;

FIG. 4 is a schematic diagram of the structure of the linkage assembly and the drive assembly of the utility model.

In the figure: 1. mounting shell; 2. through slot; 3. linkage assembly; 301. connecting block; 302. clamping plate; 4. rotating seat; 5. driving assembly; 501. worm; 502. driving motor; 503. worm gear; 504. bidirectional lead screw; 505. driving block; 6. first linear slide; 7. first slider; 8. reinforcing rod; 9. positioning plate; 10. second linear slide; 11. second slider; 12. supporting plate; 13. generating plate body; 14. raising block.

DETAILED DESCRIPTION

The following will be combined with the drawings in the embodiments of the utility model to clearly and completely describe the technical solutions in the embodiments of the utility model. Obviously, the described embodiments are only part of the embodiments of the utility model, not all of the embodiments. Based on the embodiments in the utility model, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the utility model.

Please refer to Figures 1-4, the utility model provides a technical solution:

A positioning component comprises a mounting shell 1, wherein two groups of through grooves 2 are symmetrically opened on the top of the mounting shell 1, linkage components 3 are respectively arranged inside the two groups of through grooves 2, two groups of rotating seats 4 are fixedly installed on the inner bottom of the mounting shell 1, the two groups of rotating seats 4 are symmetrically arranged, and driving components 5 for providing power for the linkage components 3 to clamp and position the product to be drilled are arranged on the side walls on the opposite side of the two groups of rotating seats 4, and the linkage components 3 are installed on the moving end of the driving components 5. The utility model can clamp and position the high-to-low auxiliary source generation plate to be drilled, avoid the situation of offset during the drilling process, which is conducive to improving the stability of the drilling operation and can further improve the drilling yield rate;

The driving assembly 5 includes a worm 501, the two ends of which are rotatably mounted on the side walls of the two sets of rotating seats 4, one end of the worm 501 passes through one of the sets of rotating seats 4 and is connected to a driving motor 502, a worm wheel 503 is meshed on the top of the worm 501, a bidirectional screw rod 504 is fixedly inserted inside the worm wheel 503, the two ends of the bidirectional screw rod 504 are rotatably mounted on the inner walls of the two sides of the mounting shell 1, and two sets of driving blocks 505 are symmetrically threaded on the outer wall of the bidirectional screw rod 504, and the two sets of linkage The components 3 are respectively arranged on the top of the two groups of driving blocks 505, and the output shaft of the driving motor 502 drives the worm 501 to rotate, which can drive the worm wheel 503 to rotate, thereby driving the bidirectional screw rod 504 to rotate, and then driving the two groups of driving blocks 505 to reciprocate along the axial direction of the bidirectional screw rod 504, that is, to move away from or approach each other, and can drive the two groups of connecting blocks 301 and the two groups of clamping plates 302 to move closer to or away from each other, so as to achieve the effect of clamping and positioning the generating plate body 13 to be drilled;

The driving motor 502 is fixedly mounted on one side wall of one group of rotating seats 4, one end of the output shaft of the driving motor 502 is fixedly connected to one end of the worm 501, and the driving motor 502 is configured as a forward and reverse stepping motor;

The linkage assembly 3 includes a connection block 301, which is fixedly mounted on the top of the driving block 505, and the connection block 301 is slidably connected to the inside of the through slot 2, and a clamping plate 302 is fixedly connected to the top of the connection block 301. The through slot 2 is provided to limit the connection block 301 and the driving block 505.

A first linear slide 6 is provided below the mounting shell 1, a first slider 7 is slidably mounted on the first linear slide 6, and the mounting shell 1 is fixedly mounted on the top of the first slider 7. By starting the first linear slide 6, the mounting shell 1 can be reciprocated longitudinally through the first slider 7, so that the position of the clamped and positioned generation plate body 13 can be adjusted longitudinally;

Two sets of reinforcing rods 8 are fixedly connected to the side walls of the first sliding block 7, respectively. The top ends of the two sets of reinforcing rods 8 are fixedly connected to the bottom of the mounting shell 1. The reinforcing rods 8 are provided to provide auxiliary support for the mounting shell 1.

A positioning plate 9 is provided below the first linear slide 6, and two groups of second linear slides 10 are symmetrically fixedly installed on the top of the positioning plate 9, and second sliders 11 are slidably installed on the tops of the two groups of second linear slides 10, respectively, and a supporting plate 12 is fixedly installed on the tops of the two groups of second sliders 11. The first linear slide 6 is fixedly installed on the top of the supporting plate 12. By starting the two groups of second linear slides 10, the clamped and positioned generation plate body 13 can be driven by the two groups of second sliders 11 to perform lateral reciprocating motion, thereby adjusting the position, so as to realize drilling operations at different positions of the generation plate body 13, which is conducive to improving the flexibility of the device;

A high-to-low auxiliary source generation plate includes a positioning component and a generation plate body 13. Heightening blocks 14 are sleeved on both sides of the generation plate body 13. One side of the two groups of heightening blocks 14 are respectively abutted against one side wall of the clamping plate 302. By setting the heightening blocks 14, the generation plate body 13 to be drilled can be heightened to facilitate subsequent drilling operations.

Working principle: When the utility model is used, the staff places the generating plate body 13 to be drilled on the upper surface of the mounting shell 1, and the two sides of the generating plate body 13 are pre-set with the padding blocks 14, and the output shaft of the driving motor 502 drives the worm 501 to rotate, which can drive the worm wheel 503 to rotate, thereby driving the bidirectional screw rod 504 to rotate, and then drive the two sets of driving blocks 505 to reciprocate along the axial direction of the bidirectional screw rod 504, that is, to move away from or approach each other, which can drive the two sets of connecting blocks 301 and the two sets of clamping plates 302 to move closer to or away from each other, so as to achieve the clamping of the generating plate body 13 to be drilled. The positioning effect is maintained, and the deviation during the drilling process is avoided, which is beneficial to improve the stability of the drilling operation and can further improve the drilling yield rate. By starting the first linear slide 6, the mounting shell 1 can be moved back and forth longitudinally through the first slider 7, so that the longitudinal position of the clamped and positioned generation plate body 13 can be adjusted. By starting two groups of second linear slides 10, the clamped and positioned generation plate body 13 can be driven to move back and forth horizontally through the two groups of second sliders 11, so as to adjust the position, thereby realizing drilling operations at different positions of the generation plate body 13, which is beneficial to improve the flexibility of the device.

Although the embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and variations may be made to the embodiments without departing from the principles and spirit of the present invention, and that the scope of the present invention is defined by the appended claims and their equivalents.

Claims (8)

1. A positioning component, characterized in that it comprises: An installation shell (1), wherein two groups of through slots (2) are symmetrically provided on the top of the installation shell (1), and linkage components (3) are respectively provided inside the two groups of through slots (2); Two groups of rotating seats (4) are fixedly mounted on the inner bottom of the mounting shell (1), and the two groups of rotating seats (4) are symmetrically arranged; A driving assembly (5) is arranged on the two groups of rotating seats (4) to provide power for the linkage assembly (3) to clamp and position the product to be drilled, and the linkage assembly (3) is installed on the moving end of the driving assembly (5). 2. A positioning assembly according to claim 1, characterized in that: the driving assembly (5) includes a worm (501), the two ends of the worm (501) are respectively rotatably mounted on the side walls of the opposite sides of the two groups of rotating seats (4), one end of the worm (501) passes through one of the groups of rotating seats (4) and is connected to a driving motor (502), the top of the worm (501) is meshed with a worm wheel (503), the inside of the worm wheel (503) is fixedly plugged with a bidirectional lead screw (504), the two ends of the bidirectional lead screw (504) are respectively rotatably mounted on the inner walls of the two sides of the mounting shell (1), the outer wall of the bidirectional lead screw (504) is symmetrically threaded with two groups of driving blocks (505), and the two groups of linkage assemblies (3) are respectively arranged on the top of the two groups of driving blocks (505). 3. A positioning assembly according to claim 2, characterized in that: the drive motor (502) is fixedly installed on a side wall of one group of rotating seats (4), and one end of the output shaft of the drive motor (502) is fixedly connected to one end of the worm (501). 4. A positioning assembly according to claim 3, characterized in that: the linkage assembly (3) includes a connecting block (301), the connecting block (301) is fixedly installed on the top of the driving block (505), and the connecting block (301) is slidably connected to the inside of the through groove (2), and the top of the connecting block (301) is fixedly connected with a clamping plate (302). 5. A positioning assembly according to claim 1, characterized in that: a first linear slide (6) is arranged below the mounting shell (1), a first slider (7) is slidably mounted on the first linear slide (6), and the mounting shell (1) is fixedly mounted on the top of the first slider (7). 6. A positioning assembly according to claim 5, characterized in that two groups of reinforcing rods (8) are fixedly connected to the side walls of both sides of the first slider (7), and the top ends of the two groups of reinforcing rods (8) are fixedly connected to the bottom of the mounting shell (1). 7. A positioning assembly according to claim 6, characterized in that: a positioning plate (9) is arranged below the first linear slide (6), and two groups of second linear slides (10) are symmetrically fixedly installed on the top of the positioning plate (9), and second sliders (11) are slidably installed on the tops of the two groups of the second linear slides (10), and a supporting plate (12) is fixedly installed on the tops of the two groups of the second sliders (11), and the first linear slide (6) is fixedly installed on the top of the supporting plate (12). 8. A high-to-low auxiliary source generation plate, comprising the positioning assembly described in any one of claims 1-7, characterized in that it also includes a generation plate body (13), and both sides of the generation plate body (13) are provided with pad blocks (14), and one side of two groups of the pad blocks (14) are respectively abutted against one side wall of the clamping plate (302).