CN219778586U - Insulating film winding device for bus duct conducting strip - Google Patents

Abstract

The utility model discloses an insulating film winding device of bus duct conducting strips, which is characterized by comprising a rack and a mounting plate vertically arranged on the rack, wherein a secondary rotating gear ring and a primary rotating gear are rotatably arranged on the mounting plate, channels which are penetrated along the axial direction are formed in the secondary rotating gear ring and the mounting plate, and the secondary rotating gear ring is meshed with the primary rotating gear; the film winding mechanism is arranged on the end face of the secondary rotation gear ring, the feeding mechanisms are arranged on two sides of the mounting plate and comprise rollers and pressing rods which are arranged up and down, the rollers are rotationally connected with the frame, a transmission shaft is arranged on one side of the frame along the length direction, and the rollers and the main rotation gear are in transmission connection with the transmission shaft through a first bevel gear. The utility model has the advantages of convenient operation, capability of improving the winding efficiency of the insulating film, and the like.

Description

Insulating film winding device for bus duct conducting strip

Technical Field

The utility model relates to the technical field of bus duct production equipment, in particular to an insulating film winding device for bus duct conducting bars.

Background

With the continuous development of modern industrialization, the electric energy demand of various industries is rapidly increasing. In some large industrial enterprises or buildings, the erection and management of electrical circuits becomes critical. Currently, bus ducts are increasingly used for power supply and distribution switching as a device widely used in circuit installation. Inside the bus duct, the conductive strip is a very important component, which takes on the key task of electric energy diversion, so the insulation performance of the conductive strip is important. In addition, the requirements for insulation treatment are different due to different specifications of the conductive strips.

Conventionally, the insulating treatment of a conductive strip is generally to wind a plurality of insulating films on the surface thereof. However, some existing winding devices are provided with more motors as power components, each power component is connected with a corresponding component through a transmission structure, and the more motors can cause the increase of equipment cost.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model aims to solve the technical problems that: how to provide an insulation film winding device with a small number of motors.

In order to solve the technical problems, the utility model adopts the following technical scheme:

the insulating film winding device for the bus duct conducting strip is characterized by comprising a rack and a mounting plate vertically arranged on the rack, wherein a secondary rotating gear ring and a main rotating gear are rotatably arranged on the mounting plate, the secondary rotating gear ring and the mounting plate are provided with channels which are penetrated along the axial direction, and the secondary rotating gear ring is meshed with the main rotating gear; the film winding mechanism is arranged on the end face of the secondary rotation gear ring, the feeding mechanisms are arranged on two sides of the mounting plate and comprise rollers and pressing rods which are arranged up and down, the rollers are rotationally connected with the frame, a transmission shaft is arranged on one side of the frame along the length direction, and the rollers and the main rotation gear are in transmission connection with the transmission shaft through a first bevel gear.

Through the combination of the frame and the film winding mechanism, the film winding process is more stable and efficient. The combined transmission mode of the secondary rotating gear ring and the main rotating gear is adopted, and meanwhile, the combination of the roller and the pressing rod ensures the accurate guiding and the close fitting of the film winding material; the main rotating gear is connected with the transmission shaft through a bevel gear, and the roller is also connected with the transmission shaft through bevel gear transmission, so that synchronous motion can be realized, the film winding mechanism can wind the insulating film on the conducting strip from the rotation of the rotating gear ring, and the conducting strip is synchronously conveyed by the feeding mechanism, so that the film winding process is more stable and efficient.

Further, the film winding mechanism comprises a tape cylinder, a tape outlet is formed in the side wall of the tape cylinder, and the tape cylinder is axially and rotatably arranged on the end face of the secondary rotating gear ring.

The adhesive tape cylinder in the film winding mechanism is provided with the tape outlet, the insulating film is installed in the adhesive tape cylinder, the insulating film is wound through the tape outlet, and meanwhile, the adhesive tape cylinder is rotatably installed on the end face of the secondary rotating gear ring along the axial direction, so that the installation and adjustment of the adhesive tape cylinder are more convenient and flexible.

Still further, the slave rotating gear ring is provided with a tensioning device arranged along the axial direction, the tensioning device comprises a tensioning rod and a first pressing component capable of moving along the axial direction of the tensioning rod, and the end part of the tensioning rod is connected with the slave rotating gear ring.

The tensioning device is used for guaranteeing the tensioning and close fitting of the insulating film in the film winding process through the combination of the tensioning rod and the first pressing component.

Further, the tensioning rod is provided with a spiral pattern groove.

Through set up the spiral decorative pattern groove on the tensioning pole, when the tensioning pole was walked around to the insulating film, increase with the frictional force between the tensioning pole for first hold-down assembly can compress tightly the insulating film on the tensioning pole better, prevents to influence around membrane and tensioning effect because of the tensioning pole surface is too smooth.

Still further, the slave rotating ring gear has a fixed rod disposed in an axial direction, and the first pressing assembly is slidably mounted on the fixed rod.

The first pressing component is slidably arranged on the fixed rod, and the position of the first pressing component can be adjusted according to the requirement.

Still further, the feeding mechanism further comprises mounting seats mounted on two side edges of the frame, the mounting seats are provided with sliding grooves which are vertically arranged, the pressing rods are vertically and slidably mounted in the sliding grooves, and a second pressing assembly is further arranged in the sliding grooves; a guide clamp for clamping the conductive strip is arranged between the two mounting seats.

The feeding mechanism guarantees accurate guiding and tight clamping of the conductive strips through the combination of the mounting seat, the sliding groove, the pressing rod and the second pressing component, and the guiding clamp is used for fixing the positions of the conductive strips and preventing the conductive strips from shifting in the winding process.

Still further, the first compression component and the second compression component comprise mounting seats, mounting rods, springs and arc-shaped pressing blocks, one ends of the mounting rods are inserted into the mounting seats, the other ends of the mounting rods are fixedly connected with the arc-shaped pressing blocks, the springs are sleeved on the mounting rods and located between the mounting seats and the arc-shaped pressing blocks, and rolling shafts are rotatably arranged at the two ends of the arc-shaped pressing blocks along the arc-shaped surface, wherein the mounting seats of the first compression component are slidably arranged on the fixing rods; the mounting seat of the second pressing component is fixedly arranged in the chute.

The two ends of the arc-shaped pressing block along the arc-shaped surface are rotatably provided with rolling shafts, so that the pressing rod and the second pressing component can slide smoothly and stably.

Still further, the guide clamp includes the telescopic link and is located the clamping part of telescopic link one end, the other end and the mount pad of telescopic link are connected.

The guide clamp is combined with the clamping part through the telescopic rod, so that the clamping of the conductive strip is more accurate and adjustable. Meanwhile, the existence of the telescopic rod can adapt to conductive strip adjustment guide clamps with different sizes, so that the flexibility and the application range of the guide clamps are increased.

Further, the two ends in the frame are also provided with transmission components, the transmission components comprise a plurality of driving rollers which are sequentially arranged, the driving rollers are rotatably arranged in the frame and are in transmission connection with the transmission shaft through a second bevel gear, and the driving rollers are provided with a conveying belt.

The driving roller is connected with the bevel gear of the transmission shaft in a driving way, so that the transmission assembly can run more stably and reliably, and the wound conductive strip is transported by the conveyor belt.

In summary, the utility model has the advantages of convenient operation, improved winding efficiency of the insulating film, and the like.

Drawings

Fig. 1 is a schematic structural view of an insulation film winding device for bus duct conductive strips.

Fig. 2 is an enlarged view of a portion of the block of fig. 1.

Fig. 3 is a schematic view of a tensioner.

Fig. 4 is a schematic view of the tensioning lever and the second hold-down assembly.

FIG. 5 is a schematic diagram showing the connection of the main rotating gear to the rotating shaft

Detailed Description

The present utility model will be described in further detail with reference to examples.

The specific implementation method comprises the following steps: as shown in fig. 1 to 5, an insulating film winding device for bus duct conductive strips comprises a frame 1 and a mounting plate 11 vertically mounted on the frame 1, wherein a secondary rotating gear ring 12 and a primary rotating gear 13 are rotatably arranged on the mounting plate, channels penetrating along the axial direction are formed in the secondary rotating gear ring 12 and the mounting plate 11, and the secondary rotating gear ring 12 is meshed with the primary rotating gear 13; the film winding mechanism 2 is installed from the terminal surface of rotating ring gear 12, the both sides of mounting panel 11 are provided with feeding mechanism 3, feeding mechanism 3 is including being cylinder 31 and the hold-down bar 32 of arranging from top to bottom, and cylinder 31 is connected with frame 1 rotation, one side of frame 1 is provided with transmission shaft 14 along length direction, cylinder 31 and main rotation gear 13 all with be connected through first bevel gear 15 transmission between the transmission shaft 14. The film winding mechanism 2 comprises a tape cylinder 21, a tape outlet 22 is formed in the side wall of the tape cylinder 21, and the tape cylinder 21 is rotatably mounted on the end face of the secondary rotating gear ring 12 along the axial direction. The slave rotary gear ring 12 is provided with a tensioning device 4 arranged along the axial direction, the tensioning device 4 comprises a tensioning rod 41 and a first pressing component 42 which can move along the axial direction of the tensioning rod 41, and the end part of the tensioning rod 41 is connected with the slave rotary gear ring 12.

When the insulating film winding device for the bus duct conductive strip is used, the bus duct conductive strip to be wound is firstly placed in the guide clamp 35, and the clamping part 352 clamps the bus duct conductive strip to prevent the bus duct conductive strip from moving in the film winding process. Then, the feeding mechanism 3 is started, the drum 31 starts to rotate, and simultaneously the pressing rod 32 presses the bus duct conductive bar downward so as to be in close contact with the drum 31. At this time, the film winding mechanism 2 starts to operate, and the tape drum 13 rotates in the axial direction from the rotating ring gear 12, winding the insulating film around the bus bar. Simultaneously, overspeed device tensioner 4 plays the effect of tensioning insulating film, guarantees the inseparable degree of insulating film winding. After the film winding is completed, the feeding mechanism 3 and the film winding mechanism 2 are stopped, and the bus duct conductive strip wound with the insulating film is taken out from the guide clamp 35.

Through setting up from rotating the bevel gear transmission connection between ring gear 12, main rotation gear 13, cylinder 31 and the transmission shaft 14, be provided with first bevel gear 15 on the transmission shaft 14, install the bevel gear with first bevel gear 15 meshing on the cylinder 31, as shown in fig. 5, wherein main rotation gear 13 realizes the synchronous drive with transmission shaft 14 through two sets of bevel gears, main rotation gear 13 connects a pivot 131, be provided with conical gear 132 at the tip of pivot 131, and connect a connecting axle 133 through first set of bevel gear, wherein connecting axle 133 sets up on frame 1, the both ends of connecting axle 133 all have conical gear 132, connect through second set of bevel gear transmission between connecting axle 133 and the transmission shaft 14, wherein conical gear on the transmission shaft 14 is bevel gear 15, through meshing with the epaxial conical gear of connecting, the collaborative work between each part has been realized, stability and the work efficiency of device have been improved. Meanwhile, by arranging the film winding mechanism 2, the feeding mechanism 3 and the tensioning device 4, automatic film winding of bus duct conducting bars can be realized, and the production efficiency and the product quality are improved. In addition, the guide clamp 35, the first pressing component 42, the second pressing component 34 and other components are arranged, so that stability and accuracy of the bus duct conductive strip in the film winding process can be guaranteed, and errors and faults in the film winding process are avoided.

In practice, the tension rod 41 has a spiral groove thereon. The secondary rotating ring gear 12 is provided with a fixing rod 121 arranged along the axial direction, and the first pressing assembly 42 is slidably mounted on the fixing rod 121.

In implementation, the feeding mechanism 3 further includes mounting bases 33 mounted on two sides of the frame 1, the mounting bases 33 have vertically arranged sliding grooves, the pressing rods 32 are vertically slidably mounted in the sliding grooves, and a second pressing assembly 34 is further arranged in the sliding grooves; a guide clamp 35 for clamping the conductive strip is arranged between the two mounting seats 33. The first pressing component 42 and the second pressing component 34 each comprise a mounting seat 6, a mounting rod 61, a spring and an arc pressing block 62, one end of the mounting rod 61 is inserted into the mounting seat 6, the other end of the mounting rod 61 is fixedly connected with the arc pressing block 62, the spring (not shown in the figure) is sleeved on the mounting rod 61 and is positioned between the mounting seat 6 and the arc pressing block 62, and the two ends of the arc pressing block 6 along the arc surface are rotatably provided with rollers 63, wherein the mounting seat of the first pressing component 42 is slidably mounted on the fixing rod 121; the mounting seat of the second compressing assembly 34 is fixedly disposed in the chute, i.e. compressed by the spring compressing structure comprising the spring (not shown), the roller 63, the arc-shaped pressing block 62, etc. as described above. The guide jig 35 includes a telescopic rod 351 and a clamping portion 352 located at one end portion of the telescopic rod 351, and the other end portion of the telescopic rod 351 is connected to the mount 33.

In implementation, the two ends on the frame 1 are further provided with a transmission assembly 5, the transmission assembly 5 comprises a plurality of driving rollers 51 which are sequentially arranged, the driving rollers 51 are rotatably installed on the frame 1 and are in transmission connection with the transmission shaft 14 through a second bevel gear 16, and the driving rollers 51 are provided with a conveying belt 52. The transmission shaft 14 is provided with a second bevel gear which is engaged with the bevel gear at the end of the transmission roller 51.

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 (9)

1. The insulating film winding device for the bus duct conducting strip is characterized by comprising a rack and a mounting plate vertically arranged on the rack, wherein a secondary rotating gear ring and a main rotating gear are rotatably arranged on the mounting plate, the secondary rotating gear ring and the mounting plate are provided with channels which are penetrated along the axial direction, and the secondary rotating gear ring is meshed with the main rotating gear;

the film winding mechanism is arranged on the end face of the secondary rotation gear ring, the feeding mechanisms are arranged on two sides of the mounting plate and comprise rollers and pressing rods which are arranged up and down, the rollers are rotationally connected with the frame, a transmission shaft is arranged on one side of the frame along the length direction, and the rollers and the main rotation gear are in transmission connection with the transmission shaft through a first bevel gear.

2. The insulating film winding device for bus duct conductive strips according to claim 1, wherein the film winding mechanism comprises a tape cylinder, a tape outlet is formed in the side wall of the tape cylinder, and the tape cylinder is rotatably mounted on the end face of the secondary rotating gear ring along the axial direction.

3. The insulation film winding device for bus duct bars according to claim 2, wherein the slave rotary ring gear is provided with a tensioning device arranged in an axial direction, the tensioning device comprises a tensioning rod and a first pressing assembly capable of moving in the axial direction of the tensioning rod, and the end part of the tensioning rod is connected with the slave rotary ring gear.

4. The insulation film winding device for bus duct bars of claim 3, wherein the tension bar has a spiral pattern groove thereon.

5. The insulation film winding apparatus of a bus duct bar as set forth in claim 3, wherein said slave rotary ring gear has a fixing rod disposed in an axial direction, said first pressing member being slidably mounted on said fixing rod.

6. The insulation film winding device for bus duct conductive strips according to claim 5, wherein the feeding mechanism further comprises mounting seats mounted on two sides of the frame, the mounting seats are provided with vertically arranged sliding grooves, the pressing rods are vertically and slidably mounted in the sliding grooves, and a second pressing assembly is further arranged in the sliding grooves; a guide clamp for clamping the conductive strip is arranged between the two mounting seats.

7. The insulation film winding device for bus duct conductive strips according to claim 6, wherein the first compression component and the second compression component each comprise a mounting seat, a mounting rod, a spring and an arc-shaped pressing block, one end of the mounting rod is inserted into the mounting seat, the other end of the mounting rod is fixedly connected with the arc-shaped pressing block, the spring is sleeved on the mounting rod and is positioned between the mounting seat and the arc-shaped pressing block, and the arc-shaped pressing block is rotatably provided with a rolling shaft along two ends of an arc-shaped surface, wherein the mounting seat of the first compression component is slidably mounted on the fixing rod; the mounting seat of the second pressing component is fixedly arranged in the chute.

8. The insulation film winding device for bus duct bars according to claim 6, wherein the guide jig comprises a telescopic rod and a clamping portion at one end of the telescopic rod, and the other end of the telescopic rod is connected with the mounting base.

9. The insulation film winding device of the bus duct conductive strip according to claim 1, wherein the two ends of the frame are further provided with transmission assemblies, the transmission assemblies comprise a plurality of transmission rollers which are sequentially arranged, the transmission rollers are rotatably arranged on the frame and are in transmission connection with the transmission shaft through a second bevel gear, and the transmission rollers are provided with a transmission belt.