KR100523857B1 - Elbow Pipe for Pneumatic Conveying System - Google Patents

Abstract

The present invention is an elbow pipe for the pneumatic conveying system bent portion that can be usefully used in the bent portion of the pneumatic conveying system piping structure in the pneumatic conveying system piping structure using the air pressure as a driving force to transfer the logistics in a short distance, specifically, friction of the transported logistics An elbow pipe which can prevent abrasion caused by the oil, comprising: an upstream straight portion 10 configured on an upstream side; A downstream straight line portion 20 forming a predetermined angle with respect to the upstream straight line portion 10; And by connecting the upstream straight line portion 10 and the downstream straight line portion 20, the rotary chamber 34 to reduce the flow rate of the fluid and the vortex chamber 38 to form a vortex is provided by the logistics transported by The present invention relates to an elbow pipe for a pneumatic conveying system bent part, which is composed of a rotating part 30 having a structure capable of preventing abrasion of an inner wall.

Description

Elbow Pipe for Pneumatic Transfer System {Elbow Pipe for Pneumatic Conveying System}

The present invention relates to an elbow pipe (Elbow Pipe) for a pneumatic transfer system that can be usefully used in the bent portion that changes the flow direction in the pneumatic conveying system (Pneumatic Conveying System) piping structure using a pneumatic pressure as a driving force will be.

In general, a pneumatic conveying system transfers raw materials to a manufacturing line in a large chemical manufacturing process, transfers powders such as sand, stone powder, and cement from each mortar manufacturing plant to each mortar manufacturing line, or feeds raw materials from a feed mill. It refers to a conveying system used for short-distance conveying powder or pellet-type logistics, which is difficult to convey unit by unit, such as conveying a manufactured feed or manufactured feed to a packaging process, and refers to a conveying system whose driving force is pneumatic. .

Such a pneumatic conveying system, as shown in Figure 1, by the silos (S) for loading the logistics to be transported, such as raw materials and the air pump (P) providing a pneumatic pressure that is the driving force required for transport and the pneumatic pressure of the transported logistics Consists of a feed pipe line (PL) for guiding the movement as an essential element.

Except for special cases, the double transfer piping line is constructed by extending several lines by connecting several transfer pipes, and considering not only the transfer itself, which is the original purpose of its function, but also the space utilization efficiency in using the available space. It is common to be.

In this way, when the pipe line is configured by connecting several pipes in consideration of the efficiency of space use, a bent part (▷) for inverting the pipe direction is involved in the pipe line, which is inevitably bent. According to the purpose and the required rigidity, it is common to configure by using welding or flange, it is common to configure using the elbow (Elbow) pipe bent to be formed according to the turning angle.

As such, the elbow pipe used in the bent portion is also called R-Bending, and is composed of flanges so that both ends thereof can be connected to the front and rear pipe structures, respectively, and a representative structure thereof is shown in FIG. 2.

As shown in FIG. 2, a general elbow pipe is used for the upstream straight line part 1 comprised in the upstream, the downstream straight line part 2 which forms an angle with respect to the upstream straight line part 1, and the degree of curvature. It consists of a curved portion 3 which is bent to fit the inner diameter.

Looking at the flow of air in the elbow-shaped pipe curved portion 3 as described above, in the upstream straight portion 1, the flow velocity of the central portion was high speed and the flow velocity was slow toward the inner wall side, Gradually, the flow velocity of the outer bent portion 4 becomes high speed, and the flow velocity of the inner bent portion 5 becomes low speed, so that a high speed region H is formed in the inner wall portion of the outer curved portion 4, and A low speed region L is formed in the inner wall portion, and when it enters the downstream straight portion 2, the same air flow as the upstream straight portion 1 is restored again.

Here, the air flow velocity of the outer curved portion 4, the high speed region H, is about 150-200% of the flow rate of the upstream straight portion 1 and the downstream straight portion 2, and about 200- of the low velocity region L flow rate. It is known to reach 300%.

Accordingly, the inner wall of the outer curved portion 4, in which the high speed region H is formed, is not only subjected to much greater frictional force between the air, which is fluid, and the transported logistics, but also a curve that obstructs the flow of the fluid. Due to the structural characteristics that are formed, even the impact of the collision of the transported logistics is caused, severe wear effect occurs.

This abrasion action does not occur uniformly over the entire inner wall of the outer curved portion 4, but as shown in FIG. 2, an erosion region is formed in a portion where wear occurs first, and this portion is twice as fast as other portions. Erosion at a speed further promotes abrasion and thus accelerates the action of abrasion.

In addition, the wear action of the inner wall of the curved portion 3, the outer curved portion 4 is further accelerated due to the heat generated by the friction, because the wear resistance of the inner wall is further lowered by the heat generated due to the characteristics of the wear resistance inversely proportional to the temperature.

As mentioned above, the wear effect of the inner wall shortens the general life of the pneumatic transfer system elbow pipe to about 20 days, requiring frequent maintenance or replacement, and the operation of the system must be stopped for such maintenance and replacement. This results in various economic losses.

In order to overcome these fundamental disadvantages of the pneumatic transfer system elbow pipe, various studies have been conducted to protect the elbow pipe by forming a cement mortar supporting wall at the back of the curved part, or the inner wall of the pipe with an alloy such as titanium. Attempts have been made to cement carbide or to increase durability by forming embossing on the inner wall of the pipe.

However, cement mortar support wall is only applicable to the pipe line installed on the ground, and it is difficult to apply to the pipe line over a certain height and occupies a large place in the construction, which not only increases the system installation cost but also mechanically supports the pipe behind the inner wall. Wear can not be prevented itself, and once the pipe is cracked by erosion, it has the disadvantage of mixing cement into the transfer system. It has a disadvantage of being expensive, and when embossing is formed on the inner wall of a pipe, the wear resistance is relatively good, but its construction is difficult, and thus the manufacturing cost increases, and it is applied to a petrochemical plant to apply soft resin, PE, EVA, etc. When transporting, they are partially deposited on the wall of the tube Being there is to the screen film remaining, so when the film is contaminated as impurities in the final product has the disadvantage that the product defect occurs.

Meanwhile, as another example of such an attempt, in Korean Utility Model Registration No. 20-266828, an elbow pipe formed by forming an opening in a curved portion of an elbow pipe and covering the opening with a reinforcing member using an appropriate coupling means to be bound. It has been disclosed, the reinforcing member to improve the wear resistance of the inner wall of the curved portion by coating the alloy iron, including chromium, nickel, manganese, and the like.

This design consists of a detachable reinforcement member that generates cracks or through-holes caused by the creation and expansion of abrasion grooves due to transport logistics, and can be easily replaced by using only the reinforcement member when the elbow pipe is broken. On the other hand, a new joint is generated between the reinforcing member and the elbow pipe, so that the wear or erosion of the pipe may be started from this portion, and the manufacturing cost is increased by coating an expensive alloy.

In addition, as another example of such an attempt, in Korean Patent Laid-Open No. 2001-0083179, the inner wall of the pipe is configured to protrude to the inside of the pipe along the direction of the pipe, so as to obtain a smooth feeding effect and reduced frictional force of the transport logistics. Elbow pipes for conveying devices have been disclosed.

However, this design also increases the cost due to the increased frictional force on the protrusions, and increases the cost by consuming more material than a general round pipe, and uses two half pipes cut in half using a coupling means. Combining construction has the disadvantage that the seams are generated and wear and erosion can also begin from here.

The present invention is to overcome the problems of the prior art, the object of the present invention is that the effect of preventing the wear and erosion of the inner wall is so large that the foreign matter is not mixed into the transport system due to cracking of the pipe, It is economical because the manufacturing cost is not too expensive, and it is deposited and coated and filmed on the wall of the pipe when it is applied to the petrochemical plant to transfer soft resin, PE, EVA, etc., so that the film is contaminated as an impurity in the final product. It relates to an elbow pipe for pneumatic conveying system bends that does not occur and has excellent wear resistance.

The present invention for this purpose is to connect the upstream straight line portion, the downstream straight line portion to form a predetermined angle with respect to the upstream straight line portion configured on the upstream side, and the upstream straight line portion and the downstream straight portion to form a predetermined angle, It is made to provide an elbow pipe for a pneumatic conveying system composed of a rotating chamber provided therein with a rotating chamber for reducing the flow velocity of the fluid and a swirl chamber for forming the vortex.

The present invention is a pneumatic conveying system (Pneumatic Conveying System) for transporting the logistics in a short distance by using the air pressure as a driving force elbow pipe for the pneumatic conveying system bent portion that can be usefully used in the bent portion that changes the flow direction in the pipe structure, The present invention relates to an elbow pipe for a pneumatic conveying system capable of preventing abrasion due to friction in logistics.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings, but the present invention is not limited thereto.

3 is a cross-sectional view showing the structure of the present invention, Figure 4 is an exploded perspective view of the present invention, Figure 5 is a cross-sectional view showing a fluid flow of the present invention.

As shown in FIG. 3, this invention is the upstream linear part 10 comprised in the upstream, the downstream linear part 20 which forms a fixed angle with respect to the upstream linear part 10, and the said upstream straight line. An elbow pipe for a pneumatic conveying system composed of a rotating portion 30 for connecting the portion 10 and the downstream straight portion 20 to form a predetermined angle, the rotating chamber for reducing the flow rate of the fluid to the rotating portion 30 The present invention relates to an elbow pipe for a pneumatic conveying system having a structure capable of preventing abrasion of an inner wall due to transported logistics by providing a vortex chamber 38 for forming a vortex and a 34.

The upstream straight portion 10 is a place where the logistics to be transferred from the first half of the pneumatic system, the flow rate is large in the center and the flow rate is reduced by friction toward the inner wall of the pipe, the end of the pneumatic conveying system upstream pipe A flange 11 is configured for connection to the.

The downstream straight line portion 20 is a place where the distribution of the angular change of direction by the function of the rotating portion 30 flows out to the second half of the pneumatic system, and the flow velocity is large at the center thereof, similar to the upstream straight portion 10. The flow velocity is reduced by friction toward the inner wall side of the tube, the end portion is provided with a flange 21 for connecting to the pipeline downstream of the pneumatic conveying system.

As shown in FIG. 4, the rotating part 30 is configured to divert the flow introduced from the upstream straight part 10 by a predetermined angle to flow out of the downstream straight part 20, and one side is an upstream straight part ( A first half pipe side wall 31 connected to 10) and the other side connected to a downstream straight portion 20; A second half pipe side wall 32 having one side connected to the upstream straight portion 10 and the other side connected to the third half pipe side wall 33; A third half pipe side wall 33 having one side connected to the downstream straight portion 20 and the other side connected to the second half pipe side wall 32; A triangular top cover 35 covering and sealing the top; A triangular lower cover 36 covering and sealing the lower portion; A cap 37 covering and sealing a gap formed at a portion where the second half pipe side wall 32 and the third half pipe side wall 33 are connected; The first half pipe side wall 31, the second half pipe side wall 32, the third half pipe side wall 33, the upper cover 35 and the lower cover 36 is an empty space formed inside the rotation Thread 34; And a vortex chamber 38 which is an empty space formed inside the cap 37.

The rotating part 30 configured as described above is configured by connecting a half-symmetric half structure cast integrally with the upstream straight line portion 10 and the downstream straight line portion 20 by welding, or the upstream straight portion ( 10) and a predetermined length pipe having the same diameter as the downstream straight portion 20 is cut in the vertical direction, and then used as the first, second and third half-pipe side walls 31, 32 and 33, respectively, The upper cover 35 and the lower cover 36 may be configured by welding or the like.

On the other hand, each component of the rotating unit 30 is configured as described above to form a rotating chamber 34 by being coupled through a welding or the like, the rotary chamber 34 is a semi-cylindrical space on each side portion This further has a triangular prism form.

In addition, the vortex chamber 38 is a structure for forming a vortex in the corner portion where the collision and friction energy is concentrated, the other wall corresponding to the center of the inlet of the upstream straight portion 10, that is, the cap 37 The combined portion consists of a hemispherical shaped protruding space.

It is due to the role of the rotary chamber 34 and the vortex chamber 38 to have abrasion resistance against the friction of the logistic to which the elbow pipe of the present invention is conveyed, referring to the specific mechanism with reference to FIG. .

First, when a fluid including a logistic that has been transported at a constant flow rate reaches the rotating chamber 34 and its passage cross section is momentarily widened, the flow rate suddenly decreases, thereby reducing its collision energy and friction energy.

However, even if the collision energy and the friction energy are reduced in this way, a phenomenon in which a large part of the energy is concentrated and concentrated on the inner wall of the apex part of the rotating chamber 34 still occurs, which is shown in FIG. 5. In the hemispherical space corresponding to the inside of the cap 37, that is, the strong vortex E is formed in a small circle in the vortex chamber 38, thereby preventing it.

Since the vortex formed in this way acts as a kind of air cushion, it prevents the collision energy and friction energy of the logistics flow mainstream (M) from converging to the corner portion, and the logistics flow gently to flow out to the downstream straight portion 20. This prevents wear and corrosion of the inner wall and thus damage of the elbow pipe.

By completing the present invention as described above, the upstream straight line portion configured on the upstream side, the downstream straight line portion at an angle with respect to the upstream straight line portion, and the upstream straight line portion and the downstream straight line portion are connected to form a predetermined angle. By doing so, it is possible to provide an elbow pipe for a pneumatic transfer system consisting of a rotating chamber for reducing the flow rate of the fluid and the vortex chamber forming the vortex therein.

By the completion of the present invention, the effect of preventing wear and erosion of the inner wall is so large that even if foreign matters are not mixed into the conveying system due to cracking of the pipe, the manufacturing cost is not too expensive and economical, When used to transfer soft resins, PE, EVA, etc., they are deposited, coated and filmed on the walls of the pipe to remain contaminated with impurities in the final product. The elbow pipe can be provided.

1 is a schematic view showing a general pneumatic conveying system,

2 is a cross-sectional view showing a typical elbow pipe,

3 is a cross-sectional view showing the structure of the present invention;

4 is an exploded perspective view of the present invention;

5 is a cross-sectional view showing a fluid flow of the present invention,

<Explanation of symbols for the main parts of the drawings>

10: upstream straight portion 20: downstream straight portion

11, 21: flange 30: rotating part

34: rotary chamber 35: top cover

36: lower cover 37: cap

38: vortex chamber

Claims (3)

delete Logistics to be conveyed from the upstream side of the pneumatic conveying system is introduced, the upstream straight line portion 10 having a flange 11 for connecting to the pneumatic conveying system upstream pipeline, and from the upstream side of the pneumatic conveying system Where the transported logistics flow out to the downstream side, and comprises a downstream straight portion 20 that forms a predetermined angle with the upstream straight portion, the flange 21 is formed at the end to connect to the downstream pipeline of the pneumatic conveying system. In the elbow pipe for a pneumatic conveying system constituted, One side is located upstream between the upstream straight portion 10 and the downstream straight portion 20 to form a rotating chamber 34 having a wider cross-sectional area than the upstream straight portion 10 to reduce the flow velocity of the fluid. A first half pipe side wall 31 connected to the side straight portion 10 and connected to the downstream straight portion 20 is provided, one side is connected to the upstream straight portion 10, and the other side is the third. A second half pipe side wall 32 is provided which is connected to the half pipe side wall 33, and the third half pipe is connected to the downstream straight portion 20 and the other side is connected to the second half pipe side wall 32. A side wall 33 is provided, and a triangular upper cover 35 is provided to cover and seal the upper portion, a triangular lower cover 36 is provided to cover and seal the lower portion, and the second half pipe side wall 32 is provided. A cap 37 is provided to cover and seal a spaced portion formed at a portion to which the third half pipe side wall 33 is connected, and the first half pipe side wall 31 is provided. 2 elbow pipe for a pneumatic transport system of a half pipe side wall 32, the third half pipe side wall 33, characterized by the upper cover 35 and lower cover 36 is rotating portion 30 is adapted to be connected. delete