CN220115828U - Traction mechanism of laminating embossing production line - Google Patents

Abstract

The utility model provides a traction mechanism for an embossing production line, which relates to the field of traction mechanisms and comprises: the feeding assembly, the right side of feeding assembly is provided with shearing assembly, and shearing assembly's right side is provided with flattening subassembly, and flattening assembly's right side is provided with embossing subassembly to embossing subassembly sets up to the pulling subassembly, pulling assembly's downside is provided with laminating subassembly, and laminating subassembly is including the guide bar, and the right-hand member welding of guide bar has the mounting panel to electric putter is installed to the outer end of mounting panel, pulling subassembly is including the motor, and the inboard of motor is installed the fixed plate, and the inboard end of motor is connected with the main shaft, and the outside of main shaft is connected with gear assembly, gear assembly's outside is provided with the external gear, and the rolling groove has been seted up on the surface of external gear. The utility model solves the problem that in the prior art, a winding component is easy to slip a rotating wheel or fold a silk ribbon stack.

Description

Traction mechanism of laminating embossing production line

Technical Field

The utility model relates to the technical field of traction mechanisms, in particular to a traction mechanism for an embossing production line.

Background

Need carry out the impressed watermark on the silk ribbon in present silk ribbon decoration, silk ribbon aesthetic property after the silk ribbon impressed watermark is better, can decorate different article, through retrieving, prior art (application number: CN 201910231131.3), described "a silk ribbon automatic embossing production line and embossing process thereof in this article, belong to silk ribbon manufacturing technical field, including material loading subassembly, shearing subassembly, flattening subassembly, embossing subassembly and rolling subassembly, shearing subassembly sets up the side at the material loading subassembly, flattening subassembly sets up on the shearing subassembly and flattening subassembly's feed end and shearing subassembly's discharge end butt joint, embossing subassembly sets up the side at the shearing subassembly, embossing subassembly's feed end and flattening subassembly's discharge end butt joint, rolling subassembly sets up the side at the embossing subassembly, rolling subassembly's feed end and embossing subassembly's discharge end butt joint. According to the utility model, the feeding assembly, the shearing assembly, the flattening assembly, the embossing assembly and the rolling assembly are matched and operated, so that the production cost can be reduced in the production process of silk ribbon embossing, the production efficiency is 8-10 times that of the conventional technology, two-thirds of labor on a production line can be saved, and the production line has remarkable economic benefit. "

However, when the winding component related to the embossing production line in the prior art is used for pulling and winding, when the tension of the silk ribbon is increased, the phenomenon of slipping easily occurs between the rotating wheels under the condition that the rotating speed of the motor is unchanged, and when the tension of the silk ribbon is reduced, the winding motor cannot be decelerated in real time, so that the silk ribbon is in a loose state due to small tension, and the phenomenon of folding and discounting of the silk ribbon stack is easily caused.

Disclosure of Invention

In order to overcome the defects existing in the prior art, the traction mechanism of the laminating embossing production line is provided at present, so that the problem that a driving motor cannot make real-time adjustment when the tension of a silk ribbon changes in a winding component related to the embossing production line in the prior art, and then a rotating wheel slips or the silk ribbon is stacked and folded is solved.

To achieve the above object, there is provided a traction mechanism for attaching an embossing line, comprising: the feeding assembly, the right side of feeding assembly is provided with shearing assembly, and shearing assembly's right side is provided with flattening subassembly, and flattening assembly's right side is provided with embossing subassembly to embossing subassembly sets up to the pulling subassembly, pulling assembly's downside is provided with laminating subassembly, and laminating subassembly is including the guide bar, and the right-hand member welding of guide bar has the mounting panel to electric putter is installed to the outer end of mounting panel, pulling subassembly is including the motor, and the inboard of motor is installed the fixed plate, and the inboard end of motor is connected with the main shaft, and the outside of main shaft is connected with gear assembly, gear assembly's outside is provided with the external gear, and the winding groove has been seted up on the surface of external gear, the inboard meshing of external gear has drive gear, and drive gear's inboard meshing has the master gear to drive gear's inboard is connected with the countershaft, and master gear and main shaft fixed connection, and tension sensor is installed in the outside of countershaft, tension sensor's outside electric connection has the controller.

Further, the guide rod is horizontally arranged, the left end of the guide rod is welded on the embossing assembly supporting frame, and the guide rod slides through the supporting frame at the lower end of the traction assembly.

Further, the guide rod is provided with two upper and lower parallel, and the telescopic link of electric putter is located between upper and lower guide rod to the left end of telescopic link and the support frame fixed connection of tractive subassembly.

Further, the fixed plate is provided with a pair of front and back parallels, and motor and controller are fixed respectively in the front and back ends of fixed plate to the controller sets up including singlechip and converter, converter and motor electric connection.

Further, the auxiliary shaft is fixedly connected with the fixing plate at the rear side, the auxiliary shaft is rotationally connected with the transmission gear, and the auxiliary shaft is arranged at the outer side of the main shaft and is annularly arranged by taking the main shaft as a circle center.

Further, the shaft sleeve is arranged in the fixing plate at the rear side of the main shaft, the rear end of the main shaft is rotationally inserted into the shaft sleeve, the fixing plate at the rear side is detachably connected with the support frame of the traction assembly, and the roller is arranged at the lower end of the support frame.

The utility model has the beneficial effects that the guide rod, the mounting plate and the electric push rod which are included in the attaching assembly are utilized, so that the distance between the pulling assembly and the embossing assembly can be conveniently adjusted, and the pulling tension of the pulling assembly can be conveniently adjusted in advance in an initial state; utilize motor, gear assembly, main shaft and the countershaft that the tractive subassembly includes to and install the tension sensor on the countershaft for when the tractive tension takes place to change, monitor the sensor signal through the controller in real time, and then be convenient for adjust the rotational speed of motor through the converter, when tension grow, the motor slowly slows down, and when tension reduces, the motor slowly accelerates, and through the meshing transmission between the gear, make difficult emergence skid and the phenomenon that the silk ribbon collapses.

Drawings

Fig. 1 is a schematic diagram of an overall embossing line structure according to an embodiment of the present utility model.

Fig. 2 is a schematic top view of a pulling assembly according to an embodiment of the present utility model.

Fig. 3 is a schematic diagram of a gear assembly according to an embodiment of the utility model.

Fig. 4 is a schematic diagram of an electrical control principle according to an embodiment of the present utility model.

In the figure: 1. a feeding assembly; 2. a shear assembly; 3. a flattening assembly; 4. an embossing assembly; 5. a pulling assembly; 51. a motor; 52. a main shaft; 53. a gear assembly; 531. an external gear; 532. a winding groove; 533. a transmission gear; 534. a main gear; 54. a secondary shaft; 55. a tension sensor; 56. a fixing plate; 57. a controller; 6. a fitting assembly; 61. a guide rod; 62. a mounting plate; 63. an electric push rod.

Detailed Description

Other advantages and effects of the present utility model will become apparent to those skilled in the art from the following disclosure, which describes the embodiments of the present utility model with reference to specific examples. The utility model may be practiced or carried out in other embodiments that depart from the specific details, and the details of the present description may be modified or varied from the spirit and scope of the present utility model.

Referring to fig. 1 to 4, the present utility model provides a traction mechanism for attaching an embossing line, comprising: a feeding assembly 1, a shearing assembly 2, a flattening assembly 3, an embossing assembly 4, a pulling assembly 5 and a fitting assembly 6.

Specifically, the right side of material loading subassembly 1 is provided with shearing subassembly 2, and the right side of shearing subassembly 2 is provided with flattening subassembly 3, the right side of flattening subassembly 3 is provided with embossing subassembly 4, and embossing subassembly 4 sets up to pulling subassembly 5, the downside of pulling subassembly 5 is provided with laminating subassembly 6, and laminating subassembly 6 is including guide bar 61, the right-hand member welding of guide bar 61 has mounting panel 62, and electric putter 63 is installed to the outer end of mounting panel 62, pulling subassembly 5 is including motor 51, and fixed plate 56 is installed to the inboard of motor 51, and the inboard end of motor 51 is connected with main shaft 52, the outside of main shaft 52 is connected with gear assembly 53, the outside of gear assembly 53 is provided with external gear 531, and the rolling groove 532 has been seted up on the surface of external gear 531, the inboard meshing of external gear 531 has drive gear 533, and the inboard meshing of drive gear 533 has main gear 534, and the inboard of drive gear 533 is connected with countershaft 54, and main gear 534 and main shaft 52 fixed connection, and the outside of countershaft 54 installs tension sensor 55, the outside electric connection of tension sensor 55 has controller 57.

In this embodiment, the feeding assembly 1, the shearing assembly 2, the flattening assembly 3 and the embossing assembly 4 are all the same as the embossing line apparatus in the background art reference document.

As a preferred embodiment, the ribbon is conveniently wound by winding slot 532.

As a preferred embodiment, the gear assembly 53 is configured to resemble a planetary gear connection structure, so that the transmission effect is better, and the slipping phenomenon is not easy to occur.

As a preferred embodiment, tension sensors 55 are provided on the surfaces of the three secondary shafts 54 to provide real-time monitoring as the external gear 531 is subjected to ribbon tension changes.

The guide rod 61 is horizontally arranged, the left end of the guide rod 61 is welded on the support frame of the embossing assembly 4, and the guide rod 61 slides through the support frame of the lower end of the traction assembly 5; the guide rods 61 are arranged in an up-down parallel manner, the telescopic rods of the electric push rods 63 are arranged between the up-down guide rods 61, and the left ends of the telescopic rods are fixedly connected with the supporting frame of the traction assembly 5.

As a preferred embodiment, the guide rod 61, the mounting plate 62 and the electric push rod 63 are utilized, so that the distance between the pulling assembly 5 and the embossing assembly 4 can be conveniently adjusted, the pulling tension of the pulling assembly 5 can be conveniently and pre-adjusted in an initial state, and the distance between the pulling assembly 5 and the embossing assembly 4 can be conveniently and flexibly adjusted.

The fixing plate 56 is provided with a pair of front and rear parallel, the motor 51 and the controller 57 are respectively fixed at the front and rear ends of the fixing plate 56, and the controller 57 is provided with a singlechip and a frequency converter, and the frequency converter is electrically connected with the motor 51.

As a preferred embodiment, the singlechip is convenient for receiving the detection signal of the tension sensor 55, and the frequency converter is convenient for adjusting the rotating speed of the motor 51 according to the tensile degree of the silk ribbon, so as to prevent slipping caused by tension overtightening and stacking and folding caused by tension overtightening.

The auxiliary shaft 54 is fixedly connected with the rear fixed plate 56, the auxiliary shaft 54 is rotatably connected with the transmission gear 533, and the auxiliary shaft 54 is arranged outside the main shaft 52 and is annularly arranged with the main shaft 52 as a center.

As a preferred embodiment, the mounting and fixing of the tension sensor 55 is facilitated by the auxiliary shaft 54 being held stationary, and is detected in real time by the tension sensor 55 as the auxiliary shaft 54 is subjected to the action of the wire belt on the external gear 531 and then transmitted to the action of the external force through the transmission gear 533.

The fixed plate 56 at the rear side of the main shaft 52 is internally provided with a shaft sleeve, the rear end of the main shaft 52 is rotationally inserted into the shaft sleeve, the fixed plate 56 at the rear side is detachably connected with the support frame of the traction assembly 5, and the lower end of the support frame is provided with a roller.

As a preferred embodiment, the rear fixing plate 56 is detachably connected, so that the external gear 531 is easily taken out and replaced after the pulling and winding are completed.

When the device is used, the distance between the traction assembly and the embossing assembly is adjusted by the guide rod, the mounting plate and the electric push rod, then the production line electric equipment is started, the motor drives the external gear to rotate through the main shaft and the auxiliary shaft driving gear assembly to realize traction rolling, when the tension is increased, sensor signals are monitored in real time through the controller, the motor is slowly decelerated, traction force is reduced, when the tension is reduced, the motor is slowly accelerated, traction force is increased, and slipping and ribbon stacking and folding phenomena are not easy to occur.

The traction mechanism for the laminating embossing production line can effectively solve the problems that when the tension of the silk ribbon of a winding component related to the embossing production line in the prior art changes, a driving motor cannot make real-time adjustment, so that a rotating wheel slips or the silk ribbon is stacked and folded, the traction mechanism is adaptive to the tension change and is difficult to cause the phenomena that the transmission mechanism inside the component slips and the silk ribbon is stacked and folded.

Claims (6)

1. A traction mechanism for a laminated embossing line, comprising: the feeding assembly (1), the right side of feeding assembly (1) is provided with shearing subassembly (2), and the right side of shearing subassembly (2) is provided with flattening subassembly (3), and the right side of flattening subassembly (3) is provided with embossing subassembly (4) to embossing subassembly (4) set up to tractive subassembly (5), its characterized in that: the downside of pulling subassembly (5) is provided with laminating subassembly (6), and laminating subassembly (6) is including guide bar (61), and the right-hand member welding of guide bar (61) has mounting panel (62) to electric putter (63) are installed to the outer end of mounting panel (62), pulling subassembly (5) are including motor (51), and fixed plate (56) are installed to the inboard of motor (51), and the inboard end of motor (51) is connected with main shaft (52), and the outside of main shaft (52) is connected with gear assembly (53), the outside of gear assembly (53) is provided with external gear (531), and rolling groove (532) have been seted up on the surface of external gear (531), the inboard meshing of external gear (531) has drive gear (533), and the inboard meshing of drive gear (533) has main gear (534), and the inboard of drive gear (533) is connected with countershaft (54), and main gear (534) and main shaft (52) fixed connection, and the outside of countershaft (54) installs tension sensor (55), and the outside electric connection of tension sensor (55) has controller (57).

2. The traction mechanism of a laminating embossing line according to claim 1, wherein the guide rod (61) is horizontally arranged, the left end of the guide rod (61) is welded on the support frame of the embossing assembly (4), and the guide rod (61) slides through the support frame of the lower end of the traction assembly (5).

3. The traction mechanism of an embossing line according to claim 1, wherein two guide rods (61) are arranged in parallel up and down, a telescopic rod of an electric push rod (63) is arranged between the upper guide rod (61) and the lower guide rod (61), and the left end of the telescopic rod is fixedly connected with a supporting frame of a traction assembly (5).

4. The traction mechanism of an embossing line according to claim 1, wherein the fixing plate (56) is provided with a pair of front and rear parallel plates, the motor (51) and the controller (57) are respectively fixed at the front and rear ends of the fixing plate (56), and the controller (57) is provided with a singlechip and a frequency converter, and the frequency converter is electrically connected with the motor (51).

5. The traction mechanism of a laminating embossing line according to claim 1, wherein the auxiliary shaft (54) is fixedly connected with a rear fixed plate (56), the auxiliary shaft (54) is rotatably connected with the transmission gear (533), and the auxiliary shaft (54) is arranged outside the main shaft (52) and is annularly arranged with the main shaft (52) as a center of a circle.

6. The traction mechanism of the laminating embossing production line according to claim 1, wherein a shaft sleeve is arranged in a fixing plate (56) at the rear side of the main shaft (52), the rear end of the main shaft (52) is rotationally inserted into the shaft sleeve, the fixing plate (56) at the rear side is detachably connected with a supporting frame of the traction assembly (5), and a roller is arranged at the lower end of the supporting frame.