阅读说明：本技术 一种捆绑装置 (Binding device ) 是由 孙波 于 2019-09-30 设计创作，主要内容包括：本发明提供一种捆绑装置,包括一基体、一挤压机构、一钢丝绳和一旋转机构,所述钢丝绳呈U形地被设置于所述基体的管材通道内,所述旋转机构包括一旋转盘两齿轮,两传动杆和两电机,两所述齿轮以所述旋转盘上的开口通道为中心,分别对称地设置在所述旋转盘的两侧,两所述挤压块对称地设置在所述开口通道的两侧,一管材被夹置于两所述挤压块之间,管材被钻孔后,管材下落且被所述钢丝绳穿入,当所述钢丝绳穿入一定数量的管材后,两所述挤压块将所述钢丝绳的两端部夹压住,所述旋转机构驱使所述挤压块旋转,从而将所述钢丝绳的端部捆绑在一起,以完成管材的自动捆绑。(The invention provides a binding device, which comprises a base body, an extrusion mechanism, a steel wire rope and a rotating mechanism, the steel wire rope is arranged in a pipe passage of the base body in a U shape, the rotating mechanism comprises a rotating disc, two gears, two transmission rods and two motors, the two gears are symmetrically arranged on two sides of the rotating disc respectively by taking an opening passage on the rotating disc as a center, the two extrusion blocks are symmetrically arranged on two sides of the opening passage, a pipe is clamped between the two extrusion blocks, and after the pipe is drilled, the pipe falls and is penetrated by the steel wire rope, after the steel wire rope penetrates a certain number of pipes, the two extrusion blocks clamp and press the two end parts of the steel wire rope, the rotating mechanism drives the extrusion blocks to rotate, so that the ends of the steel wire ropes are bound together, and automatic binding of the pipes is completed.)

1. A binding device is characterized by comprising

A base having a tube passageway;

the extrusion mechanism comprises two extrusion blocks;

the steel wire rope is arranged in the pipe channel in a U shape; and

the rotating mechanism is rotatably arranged on the upper portion of the base body and comprises a rotating disc, two gears, two transmission rods and two motors, the rotating disc is provided with an opening channel, the two gears are symmetrically arranged on two sides of the rotating disc respectively by taking the opening channel as a center, the two gears are respectively in tooth connection with the rotating disc, each gear is respectively connected with the motors through the transmission rods, the two extrusion blocks are respectively in slidable connection with the rotating disc and symmetrically arranged on two sides of the opening channel, the steel wire rope extends to the opening channel from the pipe channel, and two end portions of the steel wire rope are located between the two extrusion blocks.

2. The pipe binding apparatus of claim 1, wherein the pressing mechanism further comprises two air cylinders, the two air cylinders are respectively connected to the corresponding pressing blocks, the two pressing blocks can press the arc-shaped side surfaces of the pipe ends to form two side planes, and the distance between the two side planes is slightly smaller than the diameter of the pipe channel.

3. The pipe binding apparatus of claim 1 or 2, wherein the open channel is coaxially communicated with the pipe channel, and a diameter size of the open channel is the same as a diameter size of the pipe channel.

4. The pipe binding apparatus of claim 3, wherein one of the extrusion blocks has a limiting table protrudingly extending in a middle portion thereof, the limiting table supporting an end portion of the pipe during drilling.

Technical Field

The invention relates to a binding device.

Background

When the pipe is machined and formed, in order to facilitate operation, before the pipe is subjected to a quenching process, one end of the pipe needs to be punched, the pipe is punched and bundled into a bundle, and after the quenching process is completed, the end part of the pipe with holes is cut, so that a finished pipe is obtained. In the existing production and processing, most of the binding of the pipes is still completed by manpower, namely, an operator is required to manually string the punched pipes by using steel wire ropes so as to complete the binding.

However, the worker needs to spend a lot of effort to bind the pipes manually, which causes low working efficiency of the worker, and in addition, when a bundle of pipes is bound by a large number, the binding effect cannot be guaranteed, the binding stability is influenced by the force application of the worker, and the pipe bundle with poor binding stability is easy to fall off during quenching, thereby causing a lot of troubles.

Disclosure of Invention

The present invention is directed to a pipe binding apparatus, which arranges pipes having drilled holes in order to facilitate the drilling, thereby reducing a time required for binding and thus improving a binding efficiency.

Another object of the present invention is to provide a binding apparatus, wherein the apparatus can simultaneously perform the perforation and binding of the pipe.

Another object of the present invention is to provide a binding device for binding pipes, which has a simple structure and is convenient to operate.

In order to achieve the above object, the present invention provides a binding apparatus comprising

A base body having a tube passageway,

an extrusion mechanism, which comprises two extrusion blocks,

a wire rope disposed in the tube passageway in a U-shape, an

The rotating mechanism is rotatably arranged on the upper portion of the base body and comprises a rotating disc, two gears, two transmission rods and two motors, wherein the rotating disc is provided with an opening channel, the two gears are symmetrically arranged on two sides of the rotating disc respectively by taking the opening channel as a center, the two gears are respectively in tooth connection with the rotating disc, each gear is respectively connected with the motors through the transmission rods, the two extrusion blocks are respectively in slidable connection with the rotating disc and symmetrically arranged on two sides of the opening channel, the steel wire rope extends to the opening channel from the pipe channel, and two end portions of the steel wire rope are located between the two extrusion blocks. The end part of a pipe is clamped between the two extrusion blocks, when the end part of the pipe is drilled, the two extrusion blocks move reversely to withdraw the clamping pressure of the pipe, the pipe falls, the steel wire rope below the drilled hole of the pipe penetrates into the pipe, when the steel wire rope penetrates into a certain number of pipes, the two extrusion blocks slide in the same direction to clamp and press the two end parts of the steel wire rope, the two motors rotate in the same direction to drive the two gears to rotate so as to drive the rotating disc to rotate, and in the rotating process of the rotating disc, the end parts of the steel wire rope are rotated and bound together.

Furthermore, the extrusion mechanism further comprises two air cylinders which are respectively connected with the corresponding extrusion blocks, the two extrusion blocks can extrude the arc-shaped side surfaces of the end parts of the pipes so as to extrude the arc-shaped side surfaces into two side planes, and the distance between the two side planes is slightly smaller than the diameter size of the pipe channel.

Further, the opening channel is coaxial and communicated with the tubing channel, and the diameter size of the opening channel is the same as that of the tubing channel.

Furthermore, one of them extrusion piece has a spacing platform, spacing platform protrudingly extends in the middle part of extrusion piece, during drilling, spacing platform can support the tip of tubular product.

Further, the transmission rod and the motor are respectively arranged in the base body.

Drawings

Fig. 1 is a schematic structural view of a simple limiting and punching device according to a preferred embodiment of the invention.

Fig. 2 is a top view of a simple limiting and punching device according to the above preferred embodiment of the present invention.

Fig. 3 is a front view of a simple limit punch device according to the above preferred embodiment of the present invention.

Fig. 4 is a sectional view of a simple limit punch device according to the above preferred embodiment of the present invention.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art.

As shown in fig. 1 to 4, according to a preferred embodiment of the present invention, there is provided a pipe binding apparatus, which includes a base body 10, an extruding mechanism 20, a wire rope 30 and a rotating mechanism 40, wherein the base body 10 has a pipe passage 101, and the wire rope 30 is disposed in the pipe passage 101 in a U-shape.

The rotating mechanism 40 is rotatably disposed on the upper portion of the base body 10, the rotating mechanism 40 includes a rotating disc 41, two gears 42, two transmission rods 43 and two motors 44, wherein the rotating disc 41 has an opening channel 410, the opening channel 410 is coaxially communicated with the tube channel 101, and the diameter of the opening channel 410 is the same as the diameter of the tube channel 101.

The two gears 42 are symmetrically disposed on two sides of the rotating disc 41 with the open channel 410 as the center, and the two gears 42 are respectively in tooth connection with the rotating disc 41. Specifically, each gear 42 is connected to the motor 44 via the transmission rod 43, and the two motors 44 rotate in the same direction to drive the rotating disc 41 to rotate through the two gears 42. It is worth mentioning that the transmission rod 43 and the motor 44 are respectively arranged in the base body 10 to reduce the occupied space.

The pressing mechanism 20 includes two pressing blocks 21, the two pressing blocks 21 are slidably connected to the rotating disc 41, and the two pressing blocks 21 are symmetrically disposed on two sides of the open channel 410. The pressing mechanism 20 further includes two air cylinders 22, the two air cylinders 22 are respectively connected to the corresponding pressing blocks 21, and the air cylinders 22 can push the pressing blocks 21 to slide towards or away from the rotating disc 41 in an air pressure transmission manner.

Specifically, one of the extrusion blocks 21 has a limiting table 211, and the limiting table 211 extends protrudingly to the middle of the extrusion block 21 to define a drilling area 212 and a punching area 213 for the tube binding apparatus, i.e. the space above the limiting table 211 is the drilling area 212, and the space below the limiting table 211 is the punching area 213.

In practice, an end of a pipe 2 is clamped between the two pressing blocks 21, the pipe 2 is first drilled in the drilling area 212 and then dropped to the drilling area 213, the wire rope 30 is automatically threaded into the pipe 2, and after the wire rope 30 is threaded into a certain number of pipes 2, the wire rope 30 is bound by the rotating mechanism 40. Specifically, first, the two pressing blocks 21 are slid to a distance not less than the diameter of the pipe, and the end of the pipe 2 is placed laterally between the two pressing blocks 21, wherein the limiting table 211 supports the end of the pipe 2 so that the axial direction of the pipe 2 is perpendicular to the open channel 410 and the end of the pipe is in the drilling area 212.

The two extrusion blocks 21 slide oppositely under the driving of the two cylinders 22, the two extrusion blocks 21 can extrude the arc-shaped side surfaces of the end parts of the pipes so as to extrude the arc-shaped side surfaces into two side planes, the distance between the two side planes is that the diameter of the pressed pipes is slightly smaller than the diameter of the opening channel 410 and the diameter of the pipe channel 101, the end parts of the pipes are pressed to be fixed between the two extrusion blocks 21, then, a drill bit is provided above the end parts of the pipes to punch the end parts of the pipes, and the drilled holes penetrate through the upper cambered surfaces and the lower cambered surfaces of the end parts of the pipes.

It is worth mentioning that the U-shaped steel cord 30 extends from the pipe passage 101 to the open passage 410, and the end of the steel cord 30 is located in the perforation zone 213, i.e. between the two squeeze blocks 21. One of the vertical portions of the wire rope 30 is coaxial with the drill bit, i.e. the vertical portion is coaxial with the bore of the tubular 2, which vertical portion is located below the bore.

When the pipe 2 is drilled, the two squeezing blocks 21 are moved in opposite directions by the two cylinders 22 to remove the clamping pressure on the pipe 2, and the pipe 2 falls, wherein the wire rope 30 below the pipe 2 just penetrates into the drilled hole, i.e. the wire rope 30 automatically penetrates into the pipe 2. After each of the pipes 2 is drilled, the steel cable 30 is threaded, when the number of the pipes 2 to be threaded reaches a certain number, the two extrusion blocks 21 slide towards each other under the driving of the two cylinders 22 until the ends of the two vertical portions of the steel cable 30 are clamped, then the two motors 44 rotate in the same direction to drive the rotating disc 41 to rotate through the rotation of the two gears 42, and during the rotation of the rotating disc 41, the ends of the two vertical portions of the U-shaped steel cable 30 are rotated to be bound together, that is, the steel cable 30 perforates and binds a certain number of the pipes 2 into a bundle.

It is worth mentioning that after the extrusion deformation of the extrusion mechanism 20, the transverse diameter of the end of the pipe 2 is reduced, so that the pipe 2 can enter the open channel 410 and the pipe channel 101, and the pipe 2 does not laterally shift, so that the drilling hole of the pipe 2 can always face the steel wire rope 30. After the pipe 2 is drilled, the pipe is automatically penetrated by the steel wire rope 30 in the falling process, the rotating mechanism 40 is used for binding the steel wire rope 30, compared with a manual binding mode, the binding time of workers can be saved, the binding effect is firmer, and the pipe can be effectively prevented from scattering in the pipe quenching process.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.