CN221885612U - Binding post feeding and assembling module and binding post - Google Patents

Abstract

The utility model provides a binding post feeding and assembling module and a binding post, wherein the binding post feeding and assembling module comprises: a machine frame; the feeding assembly is arranged on the machine frame and used for conveying the connecting terminals to be assembled; the assembling piece is arranged on the machine frame, and comprises an air cylinder and a push rod, wherein the air cylinder is positioned at one side of the conveying direction of the feeding assembly, and the push rod is connected to an output shaft of the air cylinder and penetrates through the feeding assembly; the push rod pushes the connecting terminal at one side of the conveying direction of the feeding assembly through the driving of the air cylinder. The problem of among the prior art assemble the in-process manual work be difficult for controlling assemble dynamics, very fragile binding post is solved.

Description

Binding post feeding and assembling module and binding post

Technical Field

The utility model relates to the field of automation equipment, in particular to a binding post feeding and assembling module and a binding post.

Background

Along with the rapid development of science and technology, automatic tools in various industries are continuously emerging, so that both hands of people are liberated, workers are liberated from heavy physical labor and dangerous working environments, and the production efficiency is effectively improved.

However, in the existing binding post assembly technology, each binding post is provided with a clamping connector and a clamping groove, and the clamping connector of one binding post is manually clamped in the clamping groove of the other binding post, so that the assembly of the binding post is realized, the assembly strength is not easy to control manually in the assembly process, whether the clamping connector is correct or not is difficult to observe by naked eyes, the binding post is extremely easy to damage, and the assembly efficiency is not favorable.

Accordingly, the prior art has drawbacks and disadvantages, and needs to be further improved and developed.

Disclosure of utility model

The utility model aims to provide a wiring terminal feeding and assembling module and a wiring terminal, which solve the problems that in the prior art, the assembling strength is not easy to control manually in the assembling process, and the wiring terminal is extremely easy to damage.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the utility model provides a module is assembled in binding post feeding, include:

A machine frame;

The feeding assembly is arranged on the machine frame and used for conveying the connecting terminals to be assembled;

The assembling piece is arranged on the machine frame, and comprises an air cylinder and a push rod, wherein the air cylinder is positioned on the side face of the feeding assembly in the conveying direction, and the push rod is connected to an output shaft of the air cylinder and penetrates through the feeding assembly;

The push rod pushes the connecting terminal through the side face of the feeding assembly in the conveying direction under the driving of the air cylinder.

Optionally, a through hole is formed in one side, opposite to the push rod, of the feeding component, and the through hole is formed in a feeding terminal of the feeding component;

The push rod is arranged in the through hole in a penetrating way to push the wiring terminal and is used for splicing the wiring terminal to be pushed on the pushed wiring terminal.

Optionally, the push rod is abutted with the bottom of the wiring terminal, and the width of the push rod is consistent with the width of the wiring terminal.

Optionally, the binding post feeding assembly module further comprises an in-place optical fiber sensor, wherein the in-place optical fiber sensor is arranged on the feeding component and is located above the push rod, and the in-place optical fiber sensor is used for detecting the moving position of the binding post.

Optionally, the feeding assembly includes:

The driving motor is arranged on the rack;

the feeding table is arranged on the machine frame;

the driving belt assembly is arranged on the feeding table and driven by the driving motor to move.

Optionally, a guide groove is arranged on the feeding table, the size of the guide groove is matched with the shape of the bottom of the wiring terminal, and the guide groove is used for guiding the wiring terminal to move in the conveying direction;

The guide groove is a T-shaped groove.

Optionally, the inlet of the guiding groove is further provided with an inclined opening, the width of the inclined opening is larger than the guiding width of the guiding groove, and the inclined opening is used for guiding the wiring terminal to be clamped into the guiding groove.

Optionally, the driving motor further comprises a driving shaft, and the driving shaft penetrates through the feeding table.

Optionally, the drive belt assembly comprises:

the tensioning rollers are arranged on the side face of the feeding table;

The transmission belt is sleeved on the driving shaft and the feeding table and is abutted against the tensioning rollers, and the transmission belt is driven by the driving motor to move.

Based on the same conception, the application also provides a wiring terminal which comprises a limit boss and a limit groove.

The binding post feeding and assembling module and the binding post provided by the utility model have the beneficial effects that: the material loading subassembly is with the binding post who waits to assemble from storage area or other places and carry to assemble the region, for follow-up assembly step provides the material, has reduced manual operation's demand, has improved production efficiency, need not to shut down or intermittent type, has guaranteed the continuity and the stability of production line. The assembly part is responsible for fixing and clamping the connecting terminals on the feeding assembly, so that connection is realized, production efficiency can be improved, assembly quality can be guaranteed, and manual operation requirements are reduced.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments or the description of the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural view of a feeding and assembling module for a connecting terminal according to an embodiment of the present application;

FIG. 2 is a schematic view of a terminal block feed assembly module according to another embodiment of the present application;

FIG. 3 is a schematic view of a terminal block feed assembly module according to another embodiment of the present application;

FIG. 4 is a schematic view of a terminal block feed assembly module according to another embodiment of the present application;

FIG. 5 is a schematic view of a terminal block feed assembly module according to another embodiment of the present application;

Fig. 6 is a schematic structural view of a connection terminal according to an embodiment of the present application;

FIG. 7 is a schematic view of a terminal according to another embodiment of the present application from another perspective;

Fig. 8 is a schematic structural view of another view of a terminal feeding assembly module according to an embodiment of the present application.

Wherein, each reference sign in the figure:

10. A machine frame; 20. a feeding assembly; 210. a driving motor; 220. a feeding table; 211. a guide groove; 2111. a first guide groove; 2112. a second guide groove; 212. a bevel opening; 230. a drive belt assembly; 231. tensioning rollers; 232. a transmission belt; 240. a through hole; 250. a drive shaft; 410. assembling pieces; 411. a cylinder; 412. a push rod; 50. an in-place optical fiber sensor; 60. a connection terminal; 610. a limit boss; 620. and a limit groove.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the utility model is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

It should be noted that when an element is referred to as being "fixed" or "disposed" on another element, it can be directly or indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly or indirectly connected to the other element. The directions or positions indicated by the terms "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. are directions or positions based on the drawings, and are merely for convenience of description and are not to be construed as limiting the present technical solution. The terms "first," "second," and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features. The meaning of "a plurality of" is two or more, unless specifically defined otherwise.

Example 1

As shown in fig. 1 and 2, the embodiment provides a binding post feeding and assembling module, which comprises a rack 10, a feeding assembly 20 and an assembling piece 410, wherein the feeding assembly 20 is arranged on the rack 10 and is used for conveying a binding post 60 to be assembled, the feeding assembly 20 can be conveyed by a conveyor belt, a conveying mechanism or other modes, and the binding post 60 is conveyed to an assembling position according to a set program and a set signal. The assembly 410 is disposed on the machine frame 10, the assembly 410 is configured to clamp the connection terminal 60 on the feeding assembly 20 to the connection terminal 60 on the discharging assembly, and the assembly 410 connects the connection terminal 60 on the feeding assembly 20 to the connection terminal 60 on the discharging assembly, such as a clamping slot, a bayonet, or other fixing devices, mainly through a clamping manner. The assembly 410 comprises an air cylinder 411 and a push rod 412, wherein the air cylinder 411 is positioned on the side surface of the feeding assembly 20 in the conveying direction, and the push rod 412 is connected to the output shaft of the air cylinder 411 and penetrates through the feeding assembly 20. The push rod 412 pushes the connection terminal 60 by driving of the cylinder 411 at the side of the feeding assembly 20 in the conveying direction.

The working principle of the embodiment is as follows: when a plurality of connecting terminals 60 are required to be assembled into a whole, firstly, the plurality of connecting terminals 60 to be assembled are conveyed to a region to be processed through the feeding assembly 20, the assembling piece 410 is arranged on the side face of the conveying direction, the connecting terminals 60 are pushed from the bottom of the connecting terminals 60, and the connecting terminals 60 which are being pushed are clamped on the connecting terminals 60 which are already pushed along the clamping interface.

The beneficial effect that the module was assembled in binding post feeding that this embodiment provided lies in at least: the material loading subassembly 20 will wait to assemble binding post 60 and carry the region of assembling from storage area or other places, for the follow-up step of assembling provides the material, has reduced manual operation's demand, has improved production efficiency, need not to shut down or intermittent type, has guaranteed the continuity and the stability of production line. The assembly 410 is responsible for fixing and clamping the connecting terminal 60 on the feeding assembly 20 to realize connection, so that the production efficiency can be improved, the assembly quality can be ensured, and the requirement of manual operation can be reduced.

As shown in fig. 4, a through hole 240 is provided on a side of the feeding assembly 20 opposite to the push rod 412 in this embodiment, and the through hole 240 is provided at a feeding terminal of the feeding assembly 20. The push rod 412 pushes the connection terminals 60 by penetrating the through holes 240, and is used to splice the connection terminals 60 to be pushed onto the connection terminals 60 that have been pushed, where the splicing may be a clip, a clip slot, or other connection mechanism between the connection terminals 60, so as to ensure that a plurality of connection terminals 60 can be tightly connected together. The through holes 240 provide a movement path for the push rod 412, so that the push rod 412 can pass through the through holes 240 and push the connection terminal 60, and the push rod 412 can effectively transmit thrust and movement to the connection terminal 60 by being arranged in the through holes 240 in a penetrating manner, thereby improving efficiency and accuracy.

As shown in fig. 1 and 2, the push rod 412 in the present embodiment abuts against the bottom of the connection terminal 60, and the width of the push rod 412 is identical to the width of the connection terminal 60. To ensure that pushrod 412 is able to effectively push terminal 60, the width of pushrod 412 corresponds to the width of terminal 60. This allows for an accurate fit and alignment between terminal 60 and pushrod 412, allowing pushrod 412 to smoothly contact the bottom of terminal 60. The consistent width of terminal 60 and the bottom of pushrod 412 provides greater contact area and stability, ensuring that pushrod 412 applies force uniformly during pushing. Ensure that pushrod 412 pushes terminal 60 smoothly and avoids unnecessary deflection or instability.

As shown in fig. 1 and 2, the automatic splicing device for connecting terminals in this embodiment further includes an in-place optical fiber sensor 50, where the in-place optical fiber sensor 50 is disposed on the feeding assembly 20 and above the push rod 412, and the in-place optical fiber sensor 50 is used for detecting the moving position of the connecting terminal 60. The in-place fiber optic sensor 50 is typically comprised of a light emitter and a receiver. The light emitter emits an infrared light beam and the receiver receives the infrared light beam. The light emitter and receiver are typically disposed above the loading assembly 20 and pushrod 412, respectively. The infrared beam from the illuminator is transmitted along the fiber to the receiver, which forms a virtual light gate between the two components. When the connection terminal 60 passes over the feeding assembly 20, if the connection terminal 60 is in a standby state, i.e. not pushed to the next splicing position, the connection terminal 60 can block the transmission of the light beam. At this point, the receiver detects the interruption of the light beam and signals it. Once the in-place fiber sensor 50 detects the beam disruption signal, the in-place fiber sensor 50 sends a control signal to the splice 410, which triggers the operation of the splice 410 to push the terminal 60 to the next splice position. This ensures that the terminals 60 are automatically assembled in a predetermined sequence and position. By detecting and controlling the optical fiber sensor, the precision and reliability of the assembly device can be improved.

As shown in fig. 1 and 2, the feeding assembly 20 in this embodiment includes a driving motor 210, a feeding table 220, and a driving belt assembly 230, the driving motor 210 is disposed on the machine frame 10, the feeding table 220 is disposed on the machine frame 10, and the driving belt assembly 230 is disposed on the feeding table 220 and is driven by the driving motor 210 to move. The belt assembly 230 is disposed on the loading table 220, and the belt 232 is driven to move by the power of the driving motor 210. The belt 232 is typically made of rubber, polyester, or the like, and has a certain elasticity and wear resistance. The drive motor 210 transmits power to the drive belt 232 via a transmission (e.g., gear, chain, etc.). The belt 232 starts to move by the driving motor 210 and moves along the movement direction of the loading table 220. By adjusting the rotation speed of the driving motor 210, the feeding speed and the feeding rhythm can be controlled to adapt to different production requirements. The whole process is realized by the power transmission of the motor and the driving of the driving belt 232.

As shown in fig. 1, 2, 5 and 8, the feeding table 220 in this embodiment is provided with a guide groove 211, the size of the guide groove 211 matches with the bottom shape of the connection terminal 60, and the guide groove 211 is used for guiding the connection terminal 60 to move in the conveying direction. The guide groove 211 serves to guide the movement of the connection terminal 60 in the conveying direction. The guide grooves 211 ensure that the terminal 60 maintains a stable position and orientation during transportation by matching the shape of the bottom of the terminal 60. When the connection terminal 60 is located on the feeding table 220, the guide groove 211 contacts the bottom of the connection terminal 60 with the inside of the guide groove 211. The guide groove 211 restricts the lateral movement of the connection terminal 60 in the conveying direction so as to move along the path of the guide groove 211. The moving process of the connection terminal 60 is more stable by the guide of the guide groove 211. The wire connection terminals 60 can be prevented from deviating from the rails or from being distorted during the transportation, thereby ensuring the stability and the assembly quality of the assembly device. The guide groove 211 is a T-shaped groove, the guide groove 211 is divided into a first guide groove 2111 and a second guide groove 2112, the connection terminal 60 moves in the transport direction through the second guide groove 2112, and when the connection terminal 60 reaches the assembly 410 and is located in the first guide groove 2111, the connection terminal is pushed by the assembly 410 and moves in the assembly direction in the first guide groove 2111. The cross section of push rod 412 is trapezoidal, and the shape of push rod 412 matches with the shape of through-hole 240, and trapezoidal groove and trapezoidal push rod 412 joint each other to prevent the motion curve of push rod from changing, have more stability.

As shown in fig. 1 and 2, the entrance of the guiding slot 211 in this embodiment is further provided with a bevel 212, and the bevel 212 has a width larger than the guiding width of the guiding slot 211 and is used for guiding the terminal 60 to be clamped into the guiding slot 211. The width of the bevel 212 guides the terminal 60 into the guide slot 211 when the terminal 60 is near the entrance of the guide slot 211. The angle and shape of the bevel 212 can be designed according to the geometry of the terminal 60 to ensure an effective guiding action. After the bevel 212 guides the terminal 60 into the guide slot 211, the guide width of the guide slot 211 ensures that the terminal 60 is accurately positioned and aligned within the guide slot 211. The guide slot 211 may be shaped and sized to match the terminal 60 to ensure that the terminal 60 is properly positioned and secured within the guide slot 211. By the guiding of the bevel 212 and the positioning of the guide groove 211, the connection terminal 60 can be stably inserted into the guide groove 211. This helps to ensure that the terminal 60 remains stable and reliable during assembly, reducing the risk of incorrect installation or mismatch.

As shown in fig. 1, 2 and 3, the driving motor 210 in the present embodiment further includes a driving shaft 250, and the driving shaft 250 is disposed on the feeding table 220 in a penetrating manner. The rotational force generated by the driving motor 210 is transmitted to the driving shaft 250. The driving shaft 250 converts the rotational force into a linear or rotational motion by contact with the belt, thereby pushing the belt to move. The belt acts as a transmission to convert the rotational motion of the drive shaft 250 into a translational motion of the belt. The belt acts as a transmission to transfer force and motion between two or more axles. The driving shaft 250 is closely coupled to the driving shaft 250 by abutting against the belt. When the driving shaft 250 rotates, power of the driving shaft 250 is transmitted to the belt by the frictional force, thereby driving the belt to move. By controlling the rotational speed and direction of the motor, the rotational movement of the drive shaft 250 can be controlled and thereby adjust the speed, direction and position of belt movement. This may be accomplished by a motor control system to meet the movement requirements of the loading station 220.

As shown in fig. 1, 2 and 3, the belt assembly 230 in the present embodiment includes a plurality of tensioning rollers 231 and a belt 232, the plurality of tensioning rollers 231 are disposed on the side of the loading table 220, the belt 232 is sleeved on the driving shaft 250 and the loading table 220 and abuts against the plurality of tensioning rollers 231, and the belt 232 is driven by the driving motor 210 to move. The arrangement of the plurality of tension rollers 231 can disperse the driving force to a plurality of points, thereby increasing the driving force and balancing load. When the driving force is transmitted to the driving belt 232, the plurality of tensioning rollers 231 can bear the force together, so that the load of a single transmission shaft is reduced, and the stability and reliability of the driving belt 232 are improved. The position and arrangement of the tension roller 231 also adjusts the tension of the belt 232. Adjusting the position of the tensioning roller 231 or applying a tensioning device may increase or decrease the tension of the drive belt 232 and ensure that the drive belt 232 maintains proper tension and tightness throughout the drive system.

Example two

As shown in fig. 6 and 7, based on the same concept, the present application also proposes a connection terminal 60, the connection terminal 60 including a limit boss 610 and a limit groove 620. The limit boss 610 and the limit groove 620 may be matched with each other, and one of the connection terminals 60 may be fastened to the limit groove 620 of the other connection terminal 60 by the limit boss 610, so as to directly fix the connection terminals 60. The limit boss 610 may be caught in the limit groove 620 by pushing the push rod 412, thereby achieving the fixed connection between the connection terminals 60. The connection between the connection terminals 60 is stabilized and reliable by the clamping action of the limit boss 610 and the limit groove 620. The design can prevent the wiring terminal 60 from loosening or falling off under the action of vibration, impact or other external forces, and ensure the durability and reliability of connection. And prevents unnecessary loosening and falling off.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (10)

1. The utility model provides a module is assembled in binding post feeding which characterized in that includes:

A machine frame;

the feeding assembly is arranged on the rack and used for conveying the connecting terminals to be assembled;

The assembling piece is arranged on the rack and comprises an air cylinder and a push rod, the air cylinder is positioned on the side face of the feeding assembly in the conveying direction, and the push rod is connected to an output shaft of the air cylinder and penetrates through the feeding assembly;

The push rod drives the connecting terminal to push the side face of the feeding assembly in the conveying direction through the air cylinder.

2. The terminal feed assembly module of claim 1, wherein a through hole is formed in a side of the feeding assembly opposite to the push rod, and the through hole is formed in a feeding terminal of the feeding assembly;

The push rod is arranged in the through hole in a penetrating way to push the wiring terminal and is used for splicing the wiring terminal to be pushed on the pushed wiring terminal.

3. The terminal feed assembly module of claim 1, wherein the push rod abuts a bottom of the terminal, and wherein a width of the push rod is consistent with a width of the terminal.

4. The terminal feed assembly module of claim 1, further comprising an in-place fiber sensor disposed on the loading assembly and above the push rod, the in-place fiber sensor being configured to detect a movement position of the terminal.

5. The terminal feed assembly module of claim 1, wherein the loading assembly comprises:

The driving motor is arranged on the machine frame;

the feeding table is arranged on the machine frame;

the driving belt assembly is arranged on the feeding table and is driven by the driving motor to move.

6. The terminal feeding and assembling module according to claim 5, wherein the feeding table is provided with a guide groove, the size of the guide groove is matched with the shape of the bottom of the terminal, and the guide groove is used for guiding the terminal to move in the conveying direction;

The guide groove is a T-shaped groove.

7. The terminal feed assembly module of claim 6, wherein the inlet of the guide slot is further provided with a bevel, the bevel having a width greater than the guide width of the guide slot and adapted to guide the terminal into the guide slot.

8. The terminal feed assembly module of claim 5, wherein the drive motor further comprises a drive shaft, the drive shaft being disposed through the loading table.

9. A terminal feed assembly module as set forth in claim 8 wherein said drive belt assembly includes:

The tensioning rollers are arranged on the side face of the feeding table;

The driving belt is sleeved on the driving shaft and the feeding table and is abutted against the tensioning rollers, and the driving belt is driven by the driving motor to move.

10. A terminal comprising a terminal according to any one of claims 1-4, 6-7;

The wiring terminal comprises a limiting boss and a limiting groove.