KR102557500B1 - Apparatus and method for anti-corrosion coating of a housing for a pump with a deformed inner tube - Google Patents

Abstract

According to the present invention, an anticorrosive material for preventing corrosion is coated on the inside of a cooling passage in which cooling water is stored formed in a housing of a pump. In addition, the anticorrosive material can be more easily coated and only the inside of the cooling passage is coated with the anticorrosive material, which is unnecessary. Consumption of anticorrosive materials can be reduced, electric shock accidents that can occur in the process of coating anticorrosive materials can be prevented, uniform coating can be performed, and coating according to the change in thermal expansion rate between the housing and the coating material It relates to an apparatus and method for anticorrosive coating of a housing for a pump having a deformed inner tube capable of preventing material from being peeled off from the housing.

Description

Apparatus and method for anti-corrosion coating of a housing for a pump with a deformed inner tube}

The present invention relates to an anticorrosion coating apparatus and method for a housing for a pump, wherein an anticorrosive material for preventing corrosion is coated on the inside of a cooling passage in which cooling water formed in a housing of a pump is stored, but the anticorrosive material can be coated more easily. In addition, it relates to an anticorrosive coating device and method for a pump housing that can reduce consumption of unnecessary anticorrosive materials by coating only the inside of the cooling passage with the anticorrosive material.

Furthermore, the present invention can prevent electric shock accidents that may occur in the process of coating the anticorrosive material, and not only can uniform coating be performed, but also the coating material is detached from the housing according to the change in the thermal expansion rate between the housing and the coating material. An anti-corrosion coating device and method for a pump housing having a heterogeneous inner tube capable of coating a heterogeneous inner tube flow path of a housing including a heterogeneous inner tube forming a heterogeneous inner flow path such as a curve or a curve.

A pump is a device that moves a fluid (liquid or gas) or slurry by mechanical action.

Such pumps include a reciprocating pump, a rotary pump, a centrifugal pump, and the like. A pump for vacuuming the inside of a chamber is used in a wafer deposition process in a semiconductor production process, and an example of this pump is a screw pump.

As shown in FIG. 1, the screw pump rotates a rotor 200 having spirally formed blades inside a housing 100 to push liquid from a suction side to a discharge side, and the spiral blades of the two rotors are closely related to each other. As it rotates in a state of contact, a large amount of frictional heat is generated during operation.

Accordingly, various technologies for cooling the heat of the screw pump have been developed, and examples thereof include Patent Documents 1 and 2.

Patent Document 1 is a screw-type pump in which a pair of screws rotate in engagement with each other to discharge pumped gas from an inlet to an outlet, a passage penetrating the inside of the screw, a casing formed outside the screw, and formed on the front of the casing. A front cover, a middle cover and a rear cover formed on the rear surface of the casing are formed, cooling gas or oil is circulated along the passage to cool the heat generated in the screw, and a first cooling water chamber is formed in the casing It is a screw-type pump with improved cooling performance that cools the heat generated as the screw and gas are compressed, and a second cooling water chamber is formed in the middle cover to cool the heat generated by the rotation of the shaft,

Patent Document 2 is provided with a drive screw member having a drive shaft and screw wings formed along the circumference of the drive shaft, and a driven shaft and screw wings formed along the circumference of the driven shaft, but installed side by side with the drive screw member. A driven screw member that rotates in engagement with the driving screw member, a casing having a screw installation space for accommodating the driving screw member and the driven screw member, and formed at the front end of the casing and gas is sucked into the driving screw member and the driven screw member. Includes a suction port supplied, an outlet installed at the rear end of the casing and discharging gas transported by the driving screw member and the driven screw member, and a cooling water flow path formed inside the wall of the casing through which cooling water for cooling the casing flows. In the casing, a cooling water intake hole installed at the bottom of the screw installation space and communicating the screw installation space and the cooling water flow path, and a check installed in the cooling water intake hole to allow fluid flow only from the cooling water flow path to the screw installation space. A valve, an on-off valve installed at the inlet to allow or block the inflow of gas through the inlet, and a controller to control the opening and closing operation of the on-off valve are installed, so that the screw moves from the inlet when the on-off valve is blocked by the control of the controller. It is a pump equipped with a cooling structure of screw blades in which the space between the blades advances under negative pressure and sucks the cooling water from the cooling water suction hole.

As described above, various technologies for cooling the pump have been developed, and these technologies cool the heat generated from the screw blades by circulating air or cooling water in the cooling passage formed in the housing. To do this, the cooling water is circulated through the cooling passage.

A pump housing having a cooling passage for circulating cooling water has a problem in that the cooling passage of the housing is corroded by the cooling water.

Examples of anticorrosive coating technology include Patent Documents 3 to 4, and Patent Document 3 uses a lobe of a dry pump for removing harmful substances as a base material, and in a method of coating Teflon on a lobe, which is a base material, A first inspection step to check the condition of the lobe; A degreasing step of removing impurities from the surface to be coated of the lobe, which is a base material; A sanding step of checking whether the coated surface of the lobe, which is a base material, is uniform while sanding; A surface treatment step of removing a protruding portion on the surface of a lobe, which is a base material, with sand paper and then performing air cleaning; A first coating step of coating Teflon on the surface of the lobe, which is a base material, using a spray to strengthen adhesion between the lobe, which is a base material, and Teflon; A first sintering step of heat-treating the lobe, which is a base material, using a drying furnace; A secondary coating step of coating Teflon to a uniform thickness on the surface of the lobe, which is a base material, to increase abrasion resistance and chemical resistance; A cooling step of gradually cooling the base material lobe in a drying furnace for heat treatment; And a second inspection step of checking the coating state and thickness tolerance of the lobe, which is a base material, and a Teflon coating method for a dry pump for removing harmful substances,

Patent Document 4 is a Teflon coating method, as a first step, a sanding process for smoothing the coated surface of a substrate, which is a coating target, as a second step, a loading process for fixing the substrate, and as a third step, Teflon coating on the substrate Executing a coating process, as a fourth process, a drying process for drying the Teflon-coated substrate, as a fifth process, a heat treatment process for performing heat treatment on the Teflon-coated substrate, and as a sixth process, inspecting the Teflon-coated substrate after heat treatment It is a Teflon coating method in which any one of PTFE (Polytetrafluoroethylene), PFA (Per Fluoro Alkoxy) and ETFE (EthyleneTetrafluoroEthylene) is used as a Teflon coating material.

As shown in FIGS. 1 and 2, the screw pump has a cooling passage 100c formed inside the housing 100 and an anticorrosive material coating layer 300 formed on the inner surface of the cooling passage. Although various technologies for coating have been developed, some of the conventional technologies commonly use precipitation methods. There is a problem that peeling occurs after drying.

In addition, among the coating methods, the electroplating method is used, but it is difficult to control electricity in the process of using electricity, and there is a problem that workers are injured due to overcurrent in case of malfunction, and in the case of the melting method, processing is difficult and thermal deformation occurs in the metal. there is

Republic of Korea Patent Publication No. 10-2009-0112884 (2009. 10. 29.) Republic of Korea Patent No. 10-1523895 (2015. 5. 28.) Republic of Korea Patent Registration No. 10-1604975 (2016. 3. 21.) Republic of Korea Patent Publication No. 10-2021-0116171 (2021. 9. 27.)

The present invention was developed to solve the above problems of the prior art, and is a housing for a pump having a heterogeneous inner tube that can more easily coat the passage of the housing with an anticorrosive material and reduce unnecessary consumption of the anticorrosive material. It is an object of the present invention to provide an anti-corrosion coating device and method.

In particular, the present invention can prevent electric shock accidents that may occur in the process of coating the anticorrosive material, and not only can uniform coating, but also the coating material is detached from the housing according to the change in the thermal expansion rate between the housing and the coating material. To provide an anti-corrosion coating device and method for a pump housing having a heterogeneous inner tube capable of coating a heterogeneous inner tube flow path of a housing including a heterogeneous inner tube forming a heterogeneous inner flow path such as a curve or a curve. The purpose.

In order to solve the above object, the anti-corrosion coating device for a pump housing having a heterogeneous inner tube according to the present invention is a device for coating an anticorrosive material on a cooling passage formed in a housing of a pump, in which corrosion or corrosion occurs from the housing in which the cooling passage is formed. A pretreatment device that separates and removes foreign substances; a heating device for heating the pretreated housing; and a painting device for coating the inner wall of the cooling passage by spraying the anticorrosive material while moving along the inside of the cooling passage of the heated housing.

The heating device is an electrostatic coating machine, and the connection pipe connected to the spray nozzle is preferably bent in an “L” shape or an “S” shape.

It is preferable that the heating device is an electrostatic coating machine, and the connection pipe connected to the spray nozzle is a release pipe capable of entering a complicated release inner pipe such as a bend or a curve along a flow path.

The coating method of the present invention is a coating method using the coating device configured as described above, and includes a pretreatment step of separating and removing corrosion or foreign substances from a housing in which a cooling channel is formed; A heating step of heating the pretreated housing; and a painting step of spraying and painting an anticorrosive material into the cooling passage of the heated housing, wherein in the painting step, the spray nozzle is moved along the cooling passage formed in the housing and a painting device is operated to form an anticorrosive coating on the inner wall of the cooling passage. The material is coated, but the injection nozzle is inserted into the inlet of the cooling passage to be located inside the cooling passage, and then the painting device is operated to spray the anticorrosive material through the injection nozzle and at the same time to retreat the injection nozzle toward the inlet. do.

When the cooling passage formed in the housing is opened in the painting step, it is preferable that the painting is performed after leaving only a hole into which the spray nozzle is inserted and opening the opposite open surface. If all other open surfaces are sealed except for the hole into which the spray nozzle is inserted, a reverse flow of air to be sprayed occurs, and the reverse flow of air has a side effect of making it impossible to obtain the same coating thickness by thickening some areas of the coating layer. Therefore, in order to form a coating layer having the same thickness, it is preferable to have a hole through which the blown air can escape.

The anti-corrosion coating device and method for a pump housing having a heterogeneous inner tube according to the present invention can not only more easily coat the anticorrosive material, but also reduce the consumption of unnecessary anticorrosive material by coating the anticorrosive material only on the inside of the cooling passage It works.

In particular, the present invention can prevent electric shock accidents that may occur in the process of coating the anticorrosive material, and not only can uniform coating, but also the coating material is detached from the housing according to the change in the thermal expansion rate between the housing and the coating material. It prevents this from happening, and has the effect of coating the flow path of the heterogeneous inner tube that forms the inner flow path of complex heterogeneity such as bends or curves.

1 is a cross-sectional view of an example of a conventional pump
Figure 2 is a longitudinal sectional view of an example of a conventional pump
Figure 3 is a block diagram of a coating device for preventing corrosion of the pump housing having a release inner tube according to the present invention
Figure 4 is a process diagram of a coating method for preventing corrosion of a pump housing having a release inner tube according to the present invention
5 is a perspective view of different examples of a nozzle and a pipe connector constituting a coating device for preventing corrosion of a pump housing having a deformed inner tube according to the present invention;

Since the present invention can be practiced by applying various changes, specific embodiments are illustrated in the drawings and will be described through detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, or substitutes included in the spirit and technical scope of the present invention.

Like reference numerals have been used for like elements throughout the description of each figure. In describing the present invention, if it is determined that a detailed description of related known technologies may obscure the gist of the present invention, the detailed description will be omitted.

The present invention can reduce the coating material used for anticorrosive coating of the cooling passage of the pump housing, as well as reduce the time required for coating.

An anticorrosive coating device for a pump housing according to the present invention is a device for coating an anticorrosive material on a cooling passage 100c formed in a housing 100 of a pump configured as shown in FIGS. 1 and 2 .

As shown in Figure 3, the anti-corrosion coating device for the pump housing of the present invention includes a pretreatment device 10 for separating and removing corrosion or foreign substances from the housing having a cooling passage; a heating device 20 for heating the pretreated housing; and a painting device 30 for spraying the anticorrosive material while moving along the inside of the cooling passage of the heated housing to paint the inner wall of the cooling passage.

The pretreatment device 10 is a means for removing foreign substances or corrosion from the housing, and since the oil component on the surface of the housing prevents the anticorrosive material from bonding to the surface of the housing, it must be removed before coating the anticorrosive material. It is necessary to do this, and a pretreatment device is used for this purpose, and the pretreatment device can be used by selecting any one of the pretreatment devices commonly used before metal coating.

The heating device 20 is a heat treatment means for preheating the housing to allow the sprayed anticorrosive material to permeate between the tissues as a gap is created between the tissues, and it is preferable to prevent the physical properties of the housing from changing by heating only the surface , it is preferable to use a high-temperature direct fire heating method for this purpose.

The temperature heated by the heating device may vary depending on the material of the housing.

The painting device 30 is a device for coating an anticorrosive material on the inside of a cooling passage of a housing whose tissue is loosened by application of heat, and a commonly used electrostatic coating device may be used.

In addition, the present invention improves the spray nozzle of the electrostatic coating machine, so that the spray nozzle can easily move into the bent cooling passage as shown in FIG. 2 and evenly apply the anticorrosive material to the inner surface 300 of the cooling passage. made it

That is, as shown in FIG. 5, the pipe connector 32 connected between the spray nozzle 31 and the electrostatic sprayer is bent in an “L” shape or an “S” shape, so that the spray nozzle is bent for cooling. It made it possible to move easily inside the flow path.

A more preferable tube connector 32 is a release tube capable of entering a complex release inner tube such as a bend or a curve along a flow path.

That is, as the connection pipe is formed of a release pipe having excellent flexibility, the injection nozzle can be easily moved along the inside of the curved cooling passage.

Various materials may be used as the anticorrosive material, but preferably, a powder coating material that is waterproof is used.

As described above, after the cooling passage is coated with the anticorrosive material, the anticorrosive material should be cured, and a drying device 40 may be further provided to cure the anticorrosive material more quickly.

The drying device 40 is a device for curing the anticorrosive material by applying heat to a housing having a cooling passage coated with the anticorrosive material, and the heating temperature may be changed according to the condition of the anticorrosive material or the drying room.

Hereinafter, a coating method using the coating apparatus of the present invention configured as described above will be described.

Anti-corrosion coating method of a housing for a pump according to the present invention includes a pretreatment step of separating and removing corrosion or foreign substances from a housing in which a cooling passage is formed; A heating step of heating the pretreated housing; and a painting step of spraying and painting an anticorrosive material into the cooling passage of the heated housing.

The pretreatment step, as described in the pretreatment device, is a step for removing foreign substances adhered to the surface of the housing on which the cooling passage is formed. Foreign substances are buried, and the pretreatment step is performed to remove these foreign substances.

The pre-treatment process can be performed by a normal treatment process used to remove oil, and in this process, oil and foreign substances can be removed at the same time, and unwanted protrusions or flaws on the surface can be treated through a grinding process. .

The heating step is a process for preheating the housing to be coated to soften the tissue to increase the instantaneous adhesiveness of the housing surface to facilitate the supply of the anticorrosive material between the tissues. Heat treatment is performed by heating the surface of the cooling passage to be coated with the material.

At this time, it is preferable to instantaneously supply high-temperature heat so that only the surface of the housing can be heat-treated, and the temperature or heating time of the applied heat can be variously adjusted in consideration of the material of the housing. By spraying the powder through the spray nozzle while the material is heated, a coating layer with a uniform thickness can be obtained, so that it is possible to perform economical coating without wasting anticorrosive materials.

The painting step is a process of spraying and applying an anticorrosive material to the inside of the cooling passage of the preheated housing, which is performed by an electrostatic coating machine and uses a spray nozzle connected to a connector pipe having a bent or curved shape as described above. Thus, painting can be done.

In the painting step, while moving the spray nozzle along the cooling passage formed in the housing, the painting device is operated to paint the inner wall of the cooling passage with an anticorrosive material, and the injection nozzle is inserted into the inlet of the cooling passage to be positioned inside the cooling passage After operating the coating device, it is preferable that the anticorrosive material is sprayed through the spray nozzle, and at the same time, the powder is sprayed while the spray nozzle is retracted toward the inlet. At this time, the spray nozzle is moved while being positioned at the center of the inner surface of the cooling passage so that the spray is not concentrated to one side, thereby forming a coating layer of the same thickness. In addition, in order to prevent the passage to be coated with complicated release properties such as bends or curves, the corners of the inner passage may not be coated, the anticorrosive material is sprayed directly to the corners through the connector with release properties to ensure a uniform coating layer. will be able to obtain

The cooling passage formed in the housing of the pump is formed in a circular shape as shown in FIG. The anticorrosive material may be applied to the inside of the cooling passage by spraying the anticorrosive material while the nozzle is inserted into the cooling passage.

During this process, the spray nozzle moves along the cooling passage, and during the movement, the spray nozzle comes into contact with the already applied anticorrosive material and can scrape off the anticorrosive material. this can happen

Therefore, as described above, the anticorrosive material is applied to the inside of the cooling passage by moving the injection nozzle to the innermost part of the cooling passage and then retracting the injection nozzle to spray the anticorrosive material.

In addition, when the cooling passage formed in the housing is opened in the painting step, painting may be performed after forming a hole into which the injection nozzle is inserted and an open surface on the opposite side so that the injected air can escape.

The housing of the pump is usually injected with one side open to facilitate molding, and if all other open surfaces are sealed except for the hole into which the spray nozzle is inserted, reverse flow of the sprayed air occurs, and the reverse flow of air occurs through the coating layer. There is a side effect of not being able to obtain the same coating thickness by thickening some areas of the . Therefore, in order to form a coating layer having the same thickness, it is preferable to have a hole through which the blown air can escape.

After the painting step is finished, a drying step may be further included. As described above, after the anticorrosive material is coated on the cooling passage, the anticorrosive material must be cured. In order to cure the anticorrosive material more quickly, a drying device 40 may be provided to add a drying step.

The drying step is a step of curing the anticorrosive material by applying heat to the housing having the cooling passage coated with the anticorrosive material using the drying device 40. .

10: preprocessor
20: heating device
30: painting device
31: injection nozzle 32: pipe connection
40: drying device
100: housing
100c: cooling oil 100w: radiation fin
200: rotor
300: inner surface

Claims (7)

In the anti-corrosion coating device for a pump housing having a heterogeneous inner tube for coating the cooling passage (100c) formed in the housing (100) of the pump housing with an anticorrosive material, pretreatment for separating and removing corrosion or foreign substances from the housing in which the cooling passage is formed. device 10; a heating device 20 for heating the pretreated housing; and a painting device 30 for spraying an anticorrosive material while moving along the inside of the cooling passage of the heated housing to paint the inner wall of the cooling passage, wherein the heating device is a heating furnace, and the spray nozzle 31 The pipe connector 32 connected to is bent in an “A” shape or an “S” shape, the coating device is an electrostatic coating machine, and the pipe connector 32 connected to the spray nozzle 31 has a complicated deformity such as a bend or a curve. Anti-corrosion coating device for a pump housing having a release inner tube, characterized in that the release tube of the shape that can enter along the flow path of the inner tube. delete delete The anti-corrosion coating device for a pump housing having a release inner tube according to claim 1, further comprising a drying device (40) in order to more quickly cure the pump housing having a release inner tube which has been painted. In the anti-corrosion coating method of the pump housing having a release inner tube using the anti-corrosion coating device of the pump housing having a release inner tube of claim 1 or 4,
A pretreatment step of separating and removing corrosion or foreign substances from the housing in which the cooling passage is formed;
A heating step of heating the pretreated housing; and
A painting step of spraying and painting an anticorrosive material into the cooling passage of the heated housing,
In the painting step, while moving the spray nozzle along the cooling passage formed in the housing, the painting device is operated to paint the inner wall of the cooling passage with an anticorrosive material, and the injection nozzle is inserted into the inlet of the cooling passage to be positioned inside the cooling passage Anticorrosion coating method for a pump housing having a deformed inner tube, characterized in that the anticorrosive material is sprayed through the spray nozzle by operating the post-painting device and at the same time the spray nozzle is retreated toward the inlet. According to claim 5,
When the cooling passage formed in the housing is opened in the painting step, the anticorrosive coating method of the housing for the pump having a heterogeneous inner tube, characterized in that the painting is performed after opening the open surface on the opposite side leaving only the hole into which the injection nozzle is inserted. According to claim 6,
After the painting step is finished, a drying step of adding a drying device 40 to dry the coated anticorrosive material more quickly method.