KR20150137750A - Vacuum Furnace - Google Patents

Abstract

An embodiment of the present invention relates to a vacuum furnace for coating a base material. Provided is a vacuum furnace including a rotor for rotating the base material to uniformly coat the surface of the base material with a coating material. According to an embodiment of the present invention, the durability, abrasion resistance and corrosion resistance of the base material are improved and the balancing of the base material is improved by conducting brazing coating using a coating material with excellent durability, abrasion resistance and corrosion resistance and rotating the base material during brazing coating to uniformly coat the surface of the base material with the coating material. Particularly, partial abrasion is prevented by uniformly coating a base material with a three-dimensional complex shape such as impellers and propellers with a coating component and improving the uniformity of coating thickness, and abnormal noise and vibration caused by imbalance can be prevented in advance by maintaining the balance of an impeller and a propeller. Also, maintenance costs can be reduced by extending the life of the base material and reliability and marketability can be improved by ensuring the quality of a product.

Description

Vacuum furnace with rotating body {Vacuum Furnace}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a vacuum furnace equipped with a rotating body, and more particularly, to a vacuum furnace equipped with a rotating body for rotating a base material to achieve uniform coating of a base material during brazing coating.

Currently, a flue gas desulfurization system (FGD system) is installed to remove sulfur oxides which are environmental pollutants of domestic coal fired power plant flue gas.

This desulfurization facility includes four stirrer propellers per boiler. Where the propeller agitates the slurry to prevent the solids from being separated and settled. However, bubbles are generated by tip vortex cavitation phenomenon around the wing, which is a combination of rapid flow rate and corrosiveness of sulfur oxides, resulting in rapid wear.

The wear of the propeller lowers the stirring performance and the desulfurization efficiency, causes abnormal noise and vibration due to unbalance of the propeller, and shortens the service life. In addition, the worn propeller causes economic loss due to curing and maintenance, and damage due to deterioration of efficiency.

Therefore, there is a desperate need for a technique of ensuring the wear resistance and durability of the propeller so as to prevent wear or corrosion or separation even if the propeller is rotated at a high speed in a chemical reaction tank for a long time.

In Korean Patent No. 10-0772726 filed previously, a partial elastic rubber layer is laminated on a propeller blade (wing portion) to prepare for corrosion resistance, and a rubber material and a metal propeller are bonded at a high pressure of 140 to 150 占 폚, However, Korean Patent Registration No. 10-0878431 discloses a technique for improving wear resistance and durability. In addition, Korean Patent No. 10-0878431 discloses a technique for increasing the adhesive strength of a propeller, a screw, and a vibration caused by a peeling phenomenon In order to reduce noise, there is proposed a technique of end treatment for attaching different kinds of wing materials to wing tips. Korean Patent Registration No. 10-0816552 discloses a technique for producing high-temperature and high-concentration acid in extreme corrosive environments An organic-inorganic composite paint composition useful as a coating agent for protecting facilities is proposed.

As described above, various researches have been carried out to improve wear resistance, durability and corrosion resistance of power plant facilities. However, it is difficult to find a technique that effectively satisfies wear resistance, durability and corrosion resistance at the same time. In addition, The coating technique has a low bonding force of 10,000 psi, which causes peeling due to fatigue fracture.

Brazing coating is a technique of coating a sheet to be coated on a base material through a brazing process and melting a sheet made of a material having a melting point lower than that of the base material, It is a bonding technology that forms a strong bonding force due to the wettability to penetrate and mutual diffusion with the base metal.

Such a brazing coating is carried out in a vacuum furnace under an inert environment of about 450 DEG C to 1,200 DEG C or less depending on the operating environment and the brazing coating. At this time, the brazing coating penetrates between the base materials and diffuses into the base material to form a strong bond between the main materials, and a uniform microcrystalline particle film is formed on the surface of the base material, thereby improving the wear resistance and erosion resistance. In addition, it has a strong bonding force as compared with a coating method such as spraying, can be applied to a complicated shape, and has an advantage that it can be coated in a large amount.

However, since the base material injected into the vacuum furnace is brazed in a fixed state, the coating material may not be homogeneously coated according to the shape or the complicated shape, and when the homogeneous coating is not formed, There is a problem that abrasion may easily occur or corrosion may occur.

Korea registered patent: 10 - 1283095 (Notification date 2013. 07. 05)

Korean Registered Patent: 10 - 0772726 (Published on Nov. 11, 2007)

SUMMARY OF THE INVENTION The present invention has been made to solve the conventional problems,

It is an object of the present invention to provide a rotary body for rotating a base material in a vacuum furnace to improve uniformity of the base material by durability and wear resistance and corrosion resistance of the base material by rotating the base material during brazing, The vacuum chamber being provided with a rotating body for holding the vacuum chamber.

According to another aspect of the present invention, there is provided a vacuum furnace for coating a base material, the vacuum furnace including a rotating body for rotating the base material so that a coating material is homogeneously coated on the surface of the base material, do.

The rotary body has a shaft for passing through the one side of the vacuum furnace and fixing the base material to be introduced into the vacuum furnace, a sealing part provided on the outer circumferential surface of the shaft for sealing between the shaft and the vacuum furnace, And a driving unit provided on the shaft to provide rotational force to the shaft.

Here, the sealing portion is formed of a magnetic seal and a magnetic seal that induces a magnetic force by a magnetic fluid and a magnet to form an O-ring film.

And a control unit for controlling the rotational speed (RPM) of the driving unit according to the centrifugal force during the rotation of the base material, the viscosity of the coating material, and the gravity.

Here, the controller may control the rotation speed of the driving unit to 0.1 to 100 RPM when brazing the base material.

Also, the controller controls the rotation speed of the driving unit to 0.5 to 50 RPM when the viscosity of the coating material is 5,600 to 5,800 g / cm / s.

The base material is characterized by being a fan type such as an impeller and a propeller.

Wherein the coating material is made of a metal or an oil or an inorganic material.

The coating material may be a WC coating material which is obtained by rolling a mixture of tungsten carbide and a solvent at a predetermined ratio and rolling to a predetermined thickness and density, and a brazing coating material obtained by rolling a nickel alloy material to a predetermined thickness and density on the WC coating material .

According to an embodiment of the present invention, a brazing coating is performed using a coating material having excellent durability, abrasion resistance, and corrosion resistance, and a uniform coating of a coating material is performed on the surface of the base material by rotating the base material during brazing, Durability, wear resistance and corrosion resistance, and has an effect of improving balancing of the base material.

Particularly, it is possible to prevent the occurrence of partial abrasion by improving uniformity of the coating thickness and uniformity of the coating composition on the base material having a complicated three-dimensional shape such as an impeller and a propeller and to maintain the balance of the impeller and the propeller So that abnormal noise and vibration due to unbalance can be prevented.

Further, it is possible to reduce the maintenance cost due to the extension of the life of the base material, to secure the quality of the product, and to improve the reliability and merchantability.

1 is a plan view and a front view showing a vacuum furnace having a rotating body according to an embodiment of the present invention;
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a vacuum furnace.
3 is a flowchart showing a brazing coating process in a vacuum furnace equipped with a rotary body according to an embodiment of the present invention.
4 is a conceptual view for explaining the effect of centrifugal force and gravity on the coating in a vacuum furnace equipped with a rotating body according to an embodiment of the present invention.
FIGS. 5 to 13 illustrate experiments simulated to derive optimum rotational speeds taking into account the correlation between centrifugal force, gravity, and viscosity of the molten coating material as the base material rotates; FIG.
14 is a view showing a result of a coating layer homogeneity test of a brazed coated propeller in a vacuum furnace equipped with a rotating body according to an embodiment of the present invention.

These and other objects, features and other advantages of the present invention will become more apparent by describing in detail preferred embodiments of the present invention with reference to the accompanying drawings. Hereinafter, a vacuum furnace having a rotating body according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. For purposes of this specification, like reference numerals in the drawings denote like elements unless otherwise indicated.

FIG. 1 is a plan view and a front view showing a vacuum furnace having a rotating body according to an embodiment of the present invention. FIG. 2 is a plan view and a front view showing a vacuum furnace, FIG. 3 is a flowchart showing a brazing coating process in a vacuum furnace having a rotating body according to an embodiment of the present invention. FIG. 4 is a conceptual diagram for explaining the effect of centrifugal force and gravity on the coating in the vacuum furnace equipped with the rotating body according to an embodiment of the present invention.

1 and 2, an embodiment of the present invention is a vacuum furnace 100 for coating a base material, wherein a vacuum furnace is provided with a uniform coating (not shown) of the coating material 310 applied to the surface of the base material 300, And a rotating body (200) for rotating the base material (300) to be introduced into the vacuum furnace (100) so that the base material (300) is formed.

As shown in FIGS. 1 (a) and 1 (b), a vacuum furnace 100 includes a plurality of heating elements 110 in a longitudinal direction thereof and a heat exchanger 120 And a vacuum door 130 for opening and closing the vacuum furnace 100. The vacuum pump 130 is connected to the vacuum pump 130,

The rotating body 200 includes a shaft 210 passing through one side of the vacuum furnace 100 and fixing the base material 300 to be charged into the vacuum furnace 100 and a shaft 210 passing through the vacuum furnace 100 A sealing part 220 provided on an outer circumferential surface of the vacuum cleaner 210 to seal between the shaft 210 and the vacuum path 100 and a driving part 230 provided on the outer side of the vacuum path 100 and providing a rotating force to the shaft 210 ).

Here, the shaft penetrates one surface of the vacuum furnace, more specifically, one surface of the vacuum chamber, and fixes the base material to be introduced into the vacuum furnace. At this time, the shaft may be installed on all surfaces including the vacuum door depending on the shape and size of the base material, but it is preferable that the shaft is fixed to the rear side wall of the vacuum furnace 100 or the vacuum furnace 100 And is formed on the bottom surface.

A driving unit for providing a rotational force to the shaft is connected to the shaft for fixing the base material.

The driving unit 230 may include a speed reducer and a control unit 240 for controlling the rotational speed RPM of the driving unit is connected. The control unit 240 controls the rotational speed RPM of the driving unit according to the rotational centrifugal force of the base material, the viscosity of the coating material applied to the base material, and the gravitational force acting on the base material.

As shown in FIG. 2, a sealing portion is provided between the shaft and the vacuum path to enable the rotation of the shaft while maintaining the vacuum of the vacuum path.

The sealing portion may be provided so as to have almost no rotational friction with the shaft, and to completely hold the space between the shaft and the vacuum path so as to maintain the vacuum of the vacuum path.

 For example, the sealing part may be formed of a magnetic fluid and a magnetic seal that induces magnetic force by a magnet to form an O-ring film.

The magnetic fluid of the magnetic seal 220 is a compound fluid of iron-containing fluid. It is a fluid in which a magnetic powder is dispersed in a colloid shape in a liquid and then a surfactant is added so that precipitation or flocculation does not occur. The magnetic powder is a 0.02 ㎛ ultrafine particle powder and performs brown motion, and the magnetic particle concentration in the fluid is kept constant even when magnetic field, gravity, and centrifugal force are applied. Such a magnetic fluid induces a magnetic force between a stationary magnet and the shaft 210 to form a film such as an O-ring to prevent leakage of gas or invasion of dust.

On the other hand, a coating material 310 is applied to the base material 300 fixed to the shaft 210.

Here, the coating material 310 may be any material on which the coating is made, and may be made of a metal, an oil or an inorganic material, or a brazing material.

 3, the coating material 310 made of a brazing coating material is made of tungsten carbide (WC), nickel (Ni), and chromium (Cr) powder excellent in abrasion resistance and erosion resistance and a solvent agent , Binder, additive, etc. are mixed according to the purpose of use and mixed according to the environment of use, and then formed into a film material of a flexible sheet through a ball miller.

The coating material of the coating material is bonded to the base material at a low temperature (3), and the base material to which the coating material is adhered is put into a vacuum furnace to form the sintered brazing material (4).

The coating using the brazing coating material is a combination of a WC coating material rolled to a certain thickness and density at a certain ratio of tungsten carbide and a solvent and a brazing coating material rolled to a certain thickness and density on the WC coating material WC brazing coatings can be most suitable.

The WC brazing coating is formed by mixing a tungsten carbide (WC) and a solvent at a certain ratio or mixing Teflon and a dispersing material and then forming a flexible WC coating material through a ball milling process. A nickel alloy After passing the ash through a roller to form a flexible brazing coating material, a WC coating material is adhered to the base material, and a brazing material is adhered thereon to sinter and braze.

Here, the vacuum furnace for sintering and brazing provides an inert environment in the range of about 940 ° C to 1100 ° C, although the vacuum environment may vary depending on the material, size, shape, use environment, and type of coating material. That is, the brazing coating is melted in a vacuum furnace in an inert environment, and a wetting property penetrating into the base material and a capillary phenomenon cause a mutual diffusion action to form a strong bonding force between the main materials.

The brazing process of the base material using the vacuum furnace having the rotating body as described above will now be described.

Here, the base material 300 may be any product to be coated. In the present invention, the brazing coating using the propeller as the base material 300 will be described.

First, the surface of the propeller 300 is coated with the coating material 310 as described above, and then fixed to the shaft 210 passing through the side wall inside the vacuum furnace 100.

Then, power is applied to the driving unit 230 to rotate the shaft 210, and the rotation of the shaft 210 rotates the propeller 300 fixed to the shaft 210 at a constant speed.

Then, the propeller 300 is rotated at a constant speed in a vacuum furnace in an inert environment ranging from 940 ° C. to 1100 ° C. to perform sintering brazing. At this time, the brazing coating material 312 of the coating material penetrates into the WC coating material 311 and the propeller 300 as a base material by a diffusion action to make a strong bonding force between the two materials, and the brazing coating material 312 is coated on the WC coating And seeps into ash 311 to form an enhanced surface.

Meanwhile, since the propeller having the complicated three-dimensional shape has been made in a state in which the propeller is fixed without rotating, when the coating material adhered to the base material is melted in the brazing process, it flows downward under the influence of gravity, The coating material could be unevenly coated on the lower part of the propeller due to disintegration or coating of the coating material. When such a propeller is used, abrasion or corrosion occurs at weak portions of the coating, Abnormal noise and vibration could be caused.

However, since the propeller 300 rotates during the brazing process of the propeller 300 as shown in FIGS. 4 (a) and 4 (b), the centrifugal force due to the rotation causes gravity to be detailed, The material 310 is not detached from the surface of the propeller 300 or is not pushed downward, the homogeneous brazing of the coating components is achieved, and a uniform coating thickness is obtained.

At this time, the rotational speed of the propeller 300 should take into account the correlation between gravity and centrifugal force and the viscosity of the molten coating material.

In FIGS. 5 to 13, the following simulation was performed to determine the optimum propeller rotation speed considering the correlation between the centrifugal force, gravity and viscosity of the molten coating material as the propeller rotates.

1) Impeller modeling

As shown in FIG. 5, the shape of the impeller applied to the WC brazing coating, which is an object to be analyzed through computer simulation, is modeled in three dimensions.

Then, as shown in Fig. 6, the impeller test piece (a) and the coating layer (brazing filler) (b) adhered to the surface were modeled. Here, the impeller is modeled based on the drawing and the actual measurement, and the brazing filler (coating) layer is modeled by setting it to 1 mm.

Then, the parts modeled as shown in FIG. 7 (a) were assembled into a form such that a coating layer (brazing filler) was adhered to the actual impeller blades, and the lattice work was performed as shown in FIG. 7 (b) . Here, a hexahedral element was used for the lattice, and the lattice of the coating layer, which is a main object of the analysis, was made finer than the impeller. The total number of impeller elements was 3,145, and the number of coating layers was 28,020 in each of the three surfaces, which was 87,205.

2) Property and boundary conditions

The physical properties of the impeller were set to 193 GPa with an elastic modulus of 0.29 and a density of 8,000 kg / m ³ based on the actual material SUS304. In the case of the coating layer, the viscosity is an important property. The coating layer (brazing filler) is actually composed of a brazing filler of Ni base and a WC layer, but WC is not capable of bonding itself as a thermic material In addition, considering that the melting point is much higher than the brazing process temperature, WC is considered to have little effect on the actual viscosity. Therefore, considering that the material most contributing to viscosity in the alloy is Ni, the initial viscosity of Ni g / cm / s, and the density was set to 7,950 kg / m ³ . However, if the content of WC is more than 1: 1, the density should be set higher.

Fig. 8 is a graph showing the boundary conditions. The constraint condition is to fix the x, y, and z displacements and the x and y rotations about the reference point of the rotation axis, and rotate the rotation axis counterclockwise. Since the melting point of the coating layer (Brazing filler) is 940 ° C to 1,100 ° C, it is in a solid state until it is actually reached that temperature, and it is considered to be hardly affected by gravity and centrifugal force. Therefore, the change of the melted coating layer (brazing filler) was observed while controlling the rotation speed under the assumption that the ambient temperature was 1,050 ° C.

3) Computer simulation and analysis of results

The control variables, rotation speed 0.1 ~ 100RPM, were applied and computer simulation was performed for 20 minutes of brazing time.

FIG. 9 shows the amount of displacement of the coating layer of the impeller after the computer simulation for the case where the rotation speed is 1RPM. That is, it can be seen that the coating layer is moved by gravity and centrifugal force.

In FIG. 10, the strain was compared with the coating layer thickness in order to examine the degree of deformation. Here, the shape of the coating layer is classified into three types according to the change of rotation speed.

10 (a) shows a case where the molten coating layer moves a lot on the impeller surface due to the effect of gravity at a low RPM, and FIG. 10 (b) shows a case where the gravity and centrifugal force are balanced, FIG. 10 (c) shows a case where the RPM increases further and the centrifugal force is increased, so that the coating layer moves to the outer side of the wing much.

The amount of movement of the brazing filler was calculated according to the change of the impeller RPM in order to quantitatively determine the amount of movement of the brazing filler.

As shown in FIG. 11, the reference point of the impeller blade was set, and the reference point was defined as how much the reference point moved before and after the analysis was performed. The calculated value was calculated and displayed as a graph as shown in FIG. 12 based on the analysis result of each RPM , The direction of movement was not considered)

As shown in FIG. 12, it can be seen that the entire coating layer travels less in the range of 1 to 5 RPM, and it can be confirmed that the movement is the least in 3 RPM.

However, when the surface state of the coating layer of the result of 3RPM shown in (left) of FIG. 13 is seen, it is rugged like a wavy pattern because the coating layer is outwardly directed by the gravity and centrifugal force, It is judged that the difference has occurred, and there is also the influence of the natural frequency problem.

13, the movement distance of the reference point is slightly larger than 3RPM, but the surface condition is much better. Therefore, considering the uniformity of the surface condition, the RPM of this region was judged to be the most appropriate RPM for brazing.

In other words, it was found that 1.5 ~ 2 RPM condition was most suitable for the analysis of the transfer amount of the molten surface coating during impeller brazing.

4) Homogeneity test of coating layer of propeller

Fig. 14 shows the homogeneity test results of the coating layer of the propeller brazed with 1.5 to 2 RPM.

As shown in FIG. 14, the wings of the braze-coated propeller 300 were sequentially cut out from the outside to the inside, and the diffusion layer and the homogeneity of the coating layer were confirmed by a scanning electron microscope (SME) , A homogeneous coating could be confirmed by the uniform diffusion of the coating components.

As described above, the present invention provides a method of coating a base material using a coating material having excellent durability, abrasion resistance, and corrosion resistance, and coating the material on the surface of the base material by rotating the base material during brazing coating, And corrosion resistance, and improves the balance of the base metal.

Particularly, it is possible to prevent the occurrence of partial abrasion by improving uniformity of the coating thickness and uniformity of the coating composition on the base material having a complicated three-dimensional shape such as an impeller and a propeller and to maintain the balance of the impeller and the propeller Thus, abnormal noise and vibration due to the unbalance can be prevented in advance.

In addition, it is possible to reduce the maintenance cost due to the extension of the life of the base material, ensure the quality of the product, and improve the reliability and merchantability of the product.

In addition, when the brazing coated propeller according to the present invention is applied to a facility, reliability and operational quality of the equipment can be secured, stable operation of the equipment and stabilization of power supply and demand can be secured, It is possible to enhance competitiveness by increasing operation efficiency.

Although the preferred embodiments of the present invention have been described, the present invention is not limited to the specific embodiments described above. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the appended claims, And equivalents may be resorted to as falling within the scope of the invention.

100: Vacuum furnace 110: Heating element
120: heat exchanger 130: vacuum pump
140: vacuum door 200: rotating body
210: shaft 220: sealing part, magnetic seal
230: driving unit 240:
300: base material, propeller 310: coating material
311: WC coating material 312: Brazing coating material

Claims (9)

In a vacuum furnace for coating a base material,
Wherein the vacuum furnace includes a rotating body for rotating the base material so that a coating material is homogeneously coated on the surface of the base material. The method according to claim 1,
The rotating body includes a shaft for passing through the one side of the vacuum furnace and fixing the base material to be introduced into the vacuum furnace,
A sealing portion provided on an outer circumferential surface of the shaft to seal between the shaft and the vacuum passage,
And a driving unit provided on the outside of the vacuum furnace to provide rotational force to the shaft. 3. The method of claim 2,
Wherein the sealing part comprises a magnetic seal and a magnetic seal for inducing a magnetic force by a magnetic fluid and a magnet to form an O-ring film. 3. The method of claim 2,
Further comprising a control unit for controlling a rotation speed (RPM) of the driving unit according to a centrifugal force at the time of rotating the base material, a viscosity of the coating material, and gravity. 5. The method of claim 4,
Wherein the controller controls the rotational speed of the driving unit to 0.1 to 100 RPM during brazing coating of the base material. The method of claim 4, wherein
Wherein the control unit controls the rotation speed of the driving unit to 0.5 to 50 RPM when the viscosity of the coating material is 5,600 to 5,800 g / cm / s. The method according to claim 1,
Wherein the base material is a fan type such as an impeller, a propeller, and the like. The method according to claim 1,
Wherein the coating material is made of a metal or an inorganic or organic material. The method according to claim 1,
Wherein the coating material comprises a WC coating material obtained by mixing tungsten carbide and a solvent at a predetermined ratio and rolling at a predetermined thickness and density and a brazing coating material formed by rolling a nickel alloy material to a predetermined thickness and density on the WC coating material Wherein the vacuum chamber is provided with a rotating body.

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