KR102510058B1 - After using a short period, the hydrologic method and coating hydrologic method with phenalcamine epoxy paint - Google Patents

Abstract

The present invention relates to a method for manufacturing a sluice gate using a shot machine and then applying phenalkamine epoxy paint and a coated sluice gate, and more particularly, in the process of performing shot blasting using a shot machine, after blocking both sides of a shot tank supplied with a sluice gate, Shotblasting and coating the shotball strong, safe and fast; It is a polyamine-curable type 2 epoxy paint to which a curing agent containing phenalkamine is applied. It does not freeze even when coated at low temperatures, has strong adhesion, and is a quick-drying type without condensation. A method for manufacturing a sluice gate using phenalkamine epoxy paint relates to a coated sluice gate.
In the present invention, the sluice gate is put into the inclined seat of the inner and outer diameter shot machine by the transfer means, and the shot part having the spraying part at the end enters the longitudinal direction of the sluice gate by the moving unit to short-blast the sluice gate, A short blasting step of spraying a short ball into the water gate; Putting the sluice gate for which shot blasting has been completed by a shot machine into a preheating furnace and preheating it to 350 ~ 380 ° C; A sluice gate supply step of mounting caps for rotating the sluice gate to both ends of the short tank to which the preheated sluice gate is supplied; While being mounted on the sluice rotation cap and rotating the sluice on the basis of the central axis in the longitudinal direction, the FBE coating unit applies powder epoxy coating to the outer surface of the sluice, and the adhesive coating unit coats the adhesive on the outer surface of the epoxy-coated sluice, , External surface coating step of coating PE on the outer surface of the sluice coated with the PE coating unit adhesive; removing the cap for rotating the sluice gate and spraying water into the sluice gate to cool the sluice gate; A step in which the cooled sluice gate is seated on the inclined base of the inner diameter shot machine, a transfer boom is put into the sluice gate by the transfer unit, and shot blasting is performed by rotating and spraying the short ball by the impeller injection unit provided at the end. ; and epoxy coating the sluice after the short blasting is completed in a state in which the sluice gate is rotated by the rotating roller;
The step of performing the short blasting,
A loading step of loading the cooled sluice gate onto the inclined base, and an unloading step of unloading the sluice gate after shot blasting;
A shortball transfer belt is installed on one side of the transport boom that is connected to the bogie and moves back and forth to transport the shortball, and a shortball supply hole is formed in the shortball supply box where a number of rotary blades are installed to rotate the transferred shortball. A short ball supply step including a boom device for discharging and transferring;
The conveying boom device is penetrated and the separation guide supporting the conveying boom is installed so that the height can be adjusted, and the short ball cap at the inlet side to which the front end of the short tank to which the water gate is supplied is fixed is installed and the cap having a short ball discharge part to the lower side A cap step for inlet-side shot including a cap device for inlet-side shot having a shortball discharge unit installed in the body;
The short ball cap on the discharge side, to which the other end of the short tank supplied to the water gate is fixed, is installed, and the short ball discharge part is installed in the cap body having the short ball discharge part to the lower side. a discharge-side short cap step including a discharge-side short cap device to which the fixing rod of the sluice gate support is coupled;
The epoxy coating step,
While rotating the sluice gate where the shot blasting is completed, an epoxy spray transfer boom having an epoxy spray nozzle at the end is injected into the sluice by a boom transfer cart, mixed with the main body and main body having epoxy resin, and epoxy containing a hardener having phenalkamine Epoxy coating in a coating machine for coating a paint; characterized in that it comprises a.

Description

After using a short period, the hydrologic method and coating hydrologic method with phenalcamine epoxy paint}

The present invention relates to a method for manufacturing a sluice gate using a shot machine and then applying phenalkamine epoxy paint and a coated sluice gate, and more particularly, in the process of performing shot blasting using a shot machine, after blocking both sides of a shot tank supplied with a sluice gate, Shotblasting and coating the shotball strong, safe and fast; It is a polyamine-curable type 2 epoxy paint to which a curing agent containing phenalkamine is applied. It does not freeze even when coated at low temperatures, has strong adhesion, and is a quick-drying type without condensation. A method for manufacturing a sluice gate using phenalkamine epoxy paint relates to a coated sluice gate.

In general, sluice gates, which are installed in waterways, streams, and rivers through which water flows to prevent water movement, form respective coating layers on the inside and outside to prevent rust from occurring or damage to products from external shocks. At this time, the coating layer of the sluice gate The paint used is liquid resin or resin powder.

The most commonly used anticorrosive methods of painting the outer surface of the sluice gate are coating the outer surface of the sluice gate with polyethylene, coating with collal enamel or asphalt, and coating with a polymer compound recognized as a relatively new anticorrosive material. As a method, there is a method of coating an epoxy-based resin paint or a polyurethane-based resin paint.

In addition, since the bonding of the coating agent to the sluice has various variables such as the roughness of the bonding surface or the plastic deformation of the coating agent, it is difficult to explain the adhesion and durability of the coating agent simply by physical or chemical adhesion. In order to prevent corrosion and contamination, it has been treated with a film using an epoxy resin.

The polyurethane paint has poor adhesiveness and non-uniform reactivity, making it difficult to put it into practical use. At the same time, we are trying to find ways to do it.

A surface treatment step of removing scattered foreign substances by a shot blasting method for the coating of the sluice gate; a sluice gate heating step of supplying and rotating the surface-treated sluice gate to a sluice gate driving device and a driving guiding device and maintaining a temperature of 150 to 300° C. through gas supplied from a heating pipe; an outer diameter coating step of forming an epoxy coating layer, an adhesive resin layer, and a polyethylene layer by using a raw material supplied from an outer diameter coating device while rotating the heated sluice gate; a cooling step of cooling so that the coating layer of the water gate coated with the outer diameter does not escape; In the manufacturing method of the coated sluice formed through the coating step of coating the coating layer while rotating the sluice gate, the sluice heating step heats the central portion of the sluice gate to 150 to 250 ° C and the end portion to 180 to 300 ° C. Heating, and in the coating step, the epoxy powder is supplied and rotated at 120 to 230 rpm per minute, and the powder is coated for 7 to 17 minutes at a moving speed of 50 to 70 km/hr to form a thickness of 400 to 550 um, thereby coating the epoxy powder coating layer. Disclosed is a coated sluice gate using epoxy powder coating, characterized in that it is molded, and a manufacturing method thereof.

The coating sluice using the epoxy powder coating and its manufacturing method perform powder coating without the need for a powder spraying device, so the coating time of the sluice can be shortened and the coating operation can be facilitated. By coating, it is possible to prevent contamination of the surroundings and greatly reduce the space of production facilities.

However, in the prior art as described above, since the coating is performed while the polyethylene powder is not completely removed from the inner surface of the sluice gate while performing short blasting, the adhesion is not only reduced, but also the coating film on the polyethylene oil itself is formed after a certain period of time has elapsed. Since it is formed, there is a problem in that the life of the coating is shortened.

In addition, the roughness of the sluice subjected to the shot blasting process is 50 to 80 μm, and there is a problem in that the adhesion performance of the coating film is lowered because the coating material cannot penetrate deeply.

A typical epoxy paint is constituted by mixing an epoxy resin and a curing agent. Epoxy is a substance that has an epoxy active group (Epoxide group) in its chemical structure, and commercially applied epoxy resin, especially for paint, means a substance that has at least two epoxides.

There are various types of epoxy resins, and a curing agent is essentially mixed and used in epoxy paint. In other words, epoxy paint has excellent adhesion, excellent mechanical strength, excellent water resistance and chemical resistance, and has excellent dimensional stability due to little change due to curing. It takes a long time and has the characteristic of necessarily mixing a hardener.

The curing agent, commonly referred to as an epoxy curing agent, is also called an amine curing agent, and reacts with an epoxy resin to cure it into a mesh-type thermosetting resin. In terms of chemical concept, it refers to an amine compound with active hydrogen.

Although several types of epoxy paints are used, the reason why they appear as various types of products is because the curing agents used for each are different and the mixing ratio is different, and the physical properties of epoxy paints are actually influenced by the curing agent.

As a conventional epoxy curing agent, polyamine, amine adduct, polyamide, and the like are applied.

Polyamine forms a hard and dense coating film, but has disadvantages in that it is vulnerable to moisture at the beginning of painting due to its molecular structure and has a slow curing speed at low temperatures.

Amine adduct is a curing agent made by adding epoxy resin to aliphatic amine (DETA) to compensate for the disadvantages of polyamine. It is excellent, but has the disadvantage of high viscosity and slow curing at low temperatures.

Polyamide is made from the dehydration condensation reaction of fatty acid and TETA. It is the most widely used curing agent because of its excellent coating performance and low price. It has poor heat resistance and chemical resistance, and also has a disadvantage of slow low-temperature curing.

All of these conventionally used curing agents are characterized by slow curing speed at low temperatures.

In addition, such a conventional epoxy paint has a disadvantage that it is very vulnerable to moisture. In particular, as mentioned above, the conventional epoxy paint causes delay in the subsequent process and deterioration in the quality of the coating film due to slow curing, which is the biggest problem that occurs when painting the epoxy paint in winter.

That is, if the curing of the epoxy is delayed for a long time at low temperature, the main agent and the curing agent are entangled in an unreacted state, and this does not react over time. Therefore, the development of a new composition of epoxy paint that can improve and solve this problem has been required.

[Patent Document 1] Korean Patent Publication No. 2020-0045702 (published on May 6, 2020) [Patent Document 2] Korean Patent Registration No. 1054539 (registered on July 29, 2011) [Patent Document 3] Korean Patent Registration No. 0938648 (registered on January 18, 2010) [Patent Document 4] Korea Utility Model Registration No. 04433717 (2009. 03. 02. Registration)

Therefore, it was devised to solve these conventional drawbacks, and the problem of the present invention is to supply short balls to both sides of the sluice gate before coating the epoxy paint to which phenalkamine is applied in the process of coating the sluice gate to obtain a predetermined pressure. The purpose is to perform shot blasting on the inner diameter of the sluice gate.

Another problem of the present invention is, in the epoxy paint for coating the water gate, it is mixed with the main material having the epoxy paint and has excellent (salt) water resistance and abrasion resistance by applying phenalkamine, and it does not freeze even in sub-zero weather and is made of a quick-drying type aims to

Another problem of the present invention is to supply a short ball to the sluice gate to perform short blasting, then collect and reuse the short ball, remove the generated dust, and then short blasting, and then epoxy paint to which phenalkamine is applied. for the purpose of coating.

Another object of the present invention is to provide a method for manufacturing a sluice gate in which shot blasting of a sluice gate is performed quickly and accurately.

In the present invention, the sluice gate is put into the inclined seat of the inner and outer diameter shot machine by the transfer means, and the shot part having the spraying part at the end enters the longitudinal direction of the sluice gate by the moving unit to short-blast the sluice gate, Short blasting step of spraying short balls into the gate; Putting the sluice gate for which shot blasting has been completed by a shot machine into a preheating furnace and preheating it to 350 ~ 380 ° C; A sluice gate supply step of mounting caps for rotating the sluice gate to both ends of the short tank to which the preheated sluice gate is supplied; While being mounted on the sluice rotation cap and rotating the sluice on the basis of the central axis in the longitudinal direction, the FBE coating unit applies powder epoxy coating to the outer surface of the sluice, and the adhesive coating unit coats the adhesive on the outer surface of the epoxy-coated sluice, , External surface coating step of coating PE on the outer surface of the sluice coated with the PE coating unit adhesive; removing the cap for rotating the sluice gate and spraying water into the sluice gate to cool the sluice gate; A step in which the cooled sluice gate is seated on the inclined base of the inner diameter shot machine, a transfer boom is put into the sluice gate by the transfer unit, and shot blasting is performed by rotating and spraying the short ball by the impeller injection unit provided at the end. ; and epoxy coating the sluice after the short blasting is completed in a state in which the sluice gate is rotated by the rotating roller;
The step of performing the short blasting,
A loading step of loading the cooled sluice gate onto the inclined base, and an unloading step of unloading the sluice gate after shot blasting;
A shortball transfer belt is installed on one side of the transport boom that is connected to the bogie and moves back and forth to transport the shortball, and a shortball supply hole is formed in the shortball supply box where a number of rotary blades are installed to rotate the transferred shortball. A short ball supply step including a boom device for discharging and transferring;
The conveying boom device is penetrated, the separation guide supporting the conveying boom is installed to be height adjustable, and the short ball cap at the inlet side to which the front end of the short tank to which the water gate is supplied is fixed is installed and the cap having a short ball discharge part to the lower side A cap step for inlet-side shot including a cap device for inlet-side shot having a shortball discharge unit installed in the body;
The short ball cap on the discharge side, to which the other end of the short tank supplied to the water gate is fixed, is installed, and the short ball discharge part is installed on the cap body having the short ball discharge part to the lower side. a discharge-side short cap step including a discharge-side short cap device to which the fixing rod of the sluice gate support is coupled;
The epoxy coating step,
While rotating the sluice gate where the shot blasting is completed, an epoxy spray transfer boom having an epoxy spray nozzle at the end is put into the sluice by a boom transfer cart, mixed with the main body and main body having epoxy resin, and epoxy containing hardener having phenalkamine Epoxy coating in a coating machine for coating a paint; characterized in that it comprises a.

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In the present invention, in the process of coating the sluice, a short ball is supplied to the sluice for the purpose of cleaning before coating the epoxy paint to which phenalkamine is applied, and short blasting is performed on the sluice with strong pressure using a hydraulic device to coat the sluice immediately after cleaning. By making this happen, it is to provide an effect in which the coating of the epoxy paint to which phenalkamine is applied is accurately performed.

The present invention is an epoxy paint coated on a water gate, which is mixed with a subject having an epoxy paint and has excellent (salt) water resistance and chemical resistance as well as abrasion resistance by applying phenalkamine, and can be painted on various parts, and can be frozen even in sub-zero weather This is to provide an effect that allows the coating operation to be performed conveniently even in winter through the performance of the coating operation consisting of a quick-drying type without this.

In the present invention, after short blasting is performed by supplying short balls to the sluice gate, dust and contaminants generated during the work are removed, and the short balls are recovered and reused, and immediately after short blasting, epoxy paint to which phenalkamine is applied is coated. By doing so, it provides a coating effect that is not contaminated or corroded.

The present invention has the effect of providing a method for manufacturing a sluice gate in which shot blasting of a sluice gate is performed quickly and accurately.

Figure 1a is the chemical structure of bisphenol A of the present invention
Figure 1b is the chemical structure of bisphenol F of the present invention
Figure 2 is the chemical structural formula of the phenalkamine curing agent of the present invention
Figure 3 is a front view showing one embodiment of the water gate of the present invention
Figure 4 is a side cross-sectional view of the installation state for the water gate of the present invention
Figure 5 is a plan cross-sectional view of the installation state for the water gate of the present invention
6 is an enlarged cross-sectional view of a gate leaf for a sluice gate of the present invention
7 is an enlarged cross-sectional view of the main part of the water gate of the present invention
8 is a plan view showing a preferred embodiment of the water gate forming process of the present invention
9 is a front view showing the installation state of the water gate forming device of the present invention
10 is a front view of the installed state of the inner diameter shorting device of the present invention
11 is a plan view of the installation state for the inner diameter short device of the present invention
12 is a side view of the installed state of the inner diameter short device of the present invention
13 is a front view of the boom unit of the inner diameter shorting device of the present invention
14 is a front view of the main part of the boom unit of the inner diameter shorting device of the present invention
15 is a plan view of the main part of the boom unit of the inner diameter shorting device of the present invention
16 is a side view of the main part of the boom unit of the inner diameter shorting device of the present invention
17 is a front cross-sectional view of the main part of the boom unit of the inner diameter shorting device of the present invention
18 is a front view of the installation state of the right side of the boom unit of the present invention
19 is a front view of the cap device for shorting the inner diameter of the discharge side of the present invention
20 is a side view of the cap device for shorting the inner diameter of the discharge side of the present invention
21 is a side view of the operating state of the cap device for shorting the inner diameter of the discharge side of the present invention
22 is a side view of the main part of the cap device for shorting the inner diameter of the discharge side of the present invention
Figure 23 is a side view of the cap for replacement of the discharge side and the cap device for shorting the discharge side inner diameter of the present invention
24 is a front view of the main part of the inlet side of the present invention
Figure 25 is a side cross-sectional view of the main part of the cap for shorting the inner diameter of the discharge side and the inlet side of the present invention
26 is a block diagram showing the most preferred embodiment of the present invention.

The above objects, other objects, features and advantages of the present invention will be easily understood through the following preferred embodiments in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed content will be thorough and complete and the spirit of the present invention will be sufficiently conveyed to those skilled in the art.

In this specification, when an element is referred to as being on another element, it means that it may be directly formed on the other element or a third element may be interposed therebetween. Also, in the drawings, the thickness of components is exaggerated for effective description of technical content.

Embodiments described in this specification will be described with reference to cross-sectional views and/or plan views, which are ideal exemplary views of the present invention. In the drawings, the thicknesses of films and regions are exaggerated for effective explanation of technical content. Accordingly, the shape of the illustrated drawings may be modified due to manufacturing techniques and/or tolerances. Therefore, embodiments of the present invention are not limited to the specific shape shown, but also include changes in the shape generated according to the manufacturing process. For example, a region shown at right angles may be rounded or have a predetermined curvature. Accordingly, the regions illustrated in the drawings have attributes, and the shapes of the regions illustrated in the drawings are intended to illustrate a specific shape of a region of a device and are not intended to limit the scope of the invention. Although terms such as first and second are used to describe various elements in various embodiments of the present specification, these elements should not be limited by these terms. These terms are only used to distinguish one component from another. Embodiments described and illustrated herein also include complementary embodiments thereof.

Terminology used herein is for describing the embodiments and is not intended to limit the present invention. In this specification, singular forms also include plural forms unless specifically stated otherwise in a phrase. The terms 'comprises' and/or 'comprising' used in the specification do not exclude the presence or addition of one or more other elements.

In describing the specific embodiments below, several specific contents are prepared to more specifically describe the invention and aid understanding. However, readers who have knowledge in this field to the extent that they can understand the present invention can recognize that it can be used without these various specific details. In some cases, it is mentioned in advance that parts that are commonly known in describing the invention and are not greatly related to the invention are not described in order to prevent confusion for no particular reason in explaining the present invention.

Hereinafter, the composition of the epoxy paint to which phenalkamine according to the present invention is applied will be described.

Phenalkamine according to the present invention contains anacardic acid (Anacardicacid) in the shell of the edible seed cashew nut of the cashew tree, and an oily yellow liquid (CNSL: cardanol) is a major component of formaldehyde ( Formaldehyde) and general polyamine (Amine).

An epoxy paint to which phenalkamine is applied according to the present invention is constituted by including a subject having an epoxy resin and a curing agent having phenalkamine mixed with the subject.

In addition, the main agent and the curing agent included in the epoxy paint to which phenalkamine according to the present invention is applied are mixed in a volume ratio of 3 to 5: 0.5 to 1.5.

The epoxy resin included in the main subject is preferably composed of a bisphenol F type epoxy resin in the present invention. Figure 1a shows the chemical structure of bisphenol A, Figure 1b shows the chemical structure of bisphenol F.

A general epoxy resin is made by synthesizing epichlorohydrin and bisphenol, and bisphenol A and bisphenol F are among numerous bisphenols.

As shown in FIGS. 1A and 1B , only the functional group attached to the carbon atom (+ portion) at the center of the molecule is different, but the overall structure is the same. In FIGS. 1A and 1B , a polymeric material in which the -OH moiety at each molecular terminal is substituted with an Epoxide ring is generally referred to as an epoxy resin.

Theoretically, the structure of the molecule is similar to that of bisphenol A type and bisphenol F type epoxy resin in terms of water resistance, chemical resistance, and abrasion resistance, but bisphenol F type has excellent characteristics such as adhesiveness and impact resistance.

In addition, since the viscosity of bisphenol F type resin is drastically lower than that of bisphenol A type, the workability of F type paint is far superior when the paint is made, and the use of thinner is reduced due to the low viscosity, which is an advantage from the environmental point of view. have

The epoxy curing agent according to the present invention contains phenalkamine. These phenalkamines are quick-drying, have excellent low-temperature curing properties, and exhibit excellent performance in high humidity conditions.

That is, the greatest advantage of the phenalkamine curing agent according to the present invention is that it has excellent low-temperature curing performance. The biggest problem that occurs when painting epoxy paint in winter is the delay in the subsequent process and the deterioration of the quality of the coating film due to slow curing (if the curing of epoxy is delayed for a long time at low temperature, the subject and the hardener become entangled without reacting, It does not respond over time). By containing phenalkamine in the epoxy curing agent of the present invention, these phenomena can be improved.

In addition, the phenalkamine curing agent according to the present invention has the advantage of being resistant to moisture in the initial stage of painting. For the best performance, moisture must be removed before painting, but the unique hydrophobicity of waste nalcamine molecules minimizes the effect of contact with water molecules, making it possible to paint on materials with a little moisture remaining.

The phenalkamine curing agent according to the present invention is as shown in FIG. 3, and the hydroxyl group (Hydroxy group, -OH) acts as a catalyst for the curing reaction between epoxy and polyamine, so that it is a general polyamine/polyamide without a hydroxyl group even at room temperature as well as at low temperature. It exhibits a much faster curing performance than the curing agent, and also exhibits better adhesion performance than the polyamine/polyamide curing agent by forming a hydrogen bond with the hydroxyl group of the surface-treated steel surface.

Since the benzene ring contains the benzene ring, which is the basis of the composition of the epoxy resin, katanol has better compatibility with the epoxy resin than other polyamine/polyamide curing agents, so that the rate of uniform mixing with the epoxy resin is fast. Accordingly, the curing speed is fast, and chemical resistance and water resistance are excellent due to the chemically stable nature of the benzene ring.

Since the non-reactive aliphatic chain is basically hydrophobic, the aliphatic chain (-C15H27) exhibits excellent water resistance and thus has excellent rust prevention performance. In particular, its excellent low-temperature curing performance prevents painting defects due to curing delay In addition, it contributes to the increase of production efficiency by shortening the process time.

As shown in FIGS. 3 to 7, the integral water gate 10 according to the embodiment of the present invention has guide frames 11 installed at regular intervals on both sides of the integral water gate 10 having a rectangular shape as a whole. It is made in a "c" shape to face each other, so that the auxiliary beam 15 is connected to the lower side and the upper beam 16 is connected to the upper side, and the rectangular gate leaf is inside the guide frame 11 and the auxiliary beam 15. (20) is installed to adjust the opening width of the water gate as the height is adjusted.

A stopper 12 protrudes from both guide frames 11 where the gate leaf 20 moves downward and maintains a closed state, and a stop member 25 is provided at a portion where the stopper 12 meets the stopper. It is located and installed so that sealing is achieved by the bar rubber 21 installed on the opposite side.

The bar rubber 21 is fixed using rubber fixing bolts 22 at regular intervals from the front to the slope of the gate leaf 20 .

After being coupled with a connecting pin 24 at the upper center of the gate leaf 20, a rack bar 30 is installed in a vertical direction to connect the rack-type hoist 31 so as to penetrate, and the rack-type hoist 31 As the hoisting handle 32 is installed and raises and lowers the rack-type hoist 31 according to the rotation direction, the gate leaf 20 rises and falls vertically within the guide frame 11, opening and closing the water gate. This includes installing a choice of drive to make.

Shot blasting is performed by supplying the gate leaf 20 or all the components of the integral sluice gate 10 to the shot tank 200 supplied to the shot device 80, and the sluice coating device 100 ) through which an epoxy paint using phenalkamine is coated.

As shown in Figs. 20), a cap mounting means, an outer surface coating unit, a cap removal and cooling unit, a coating machine 110, and the like.

First, the water gate 10 is put into the inclined base 81 of the short device 80 by the transfer means 4 (S10),

The water gate 10 is seated on the inclined base 81 of the short device 80 to which the short tank 200 is supplied, and the boom device 90 for transporting to the front of the water gate 10 by the truck driving device 700 ) is supplied and the short ball is rotated and sprayed by the short ball supply device 900 provided at the end to perform short blasting (S20).

Then, a preheating step (S30) is performed so that the sluice gate 10 after the shot blasting is completed is preheated to facilitate coating.

In a state in which the preheated water gate 10 is rotated by the rotating roller, an epoxy spray transport boom having an epoxy resin spray nozzle containing phenalkamine curing agent at the end is introduced into the water gate 10 by the boom transport cart. The surface (referring to the entire outer surface) of the water gate 10 is coated with epoxy containing phenalkamine (S40).

After performing the step (S20) of performing the inner shot blasting,

A loading step (S100) of loading the sluice gate (10) onto the inclined base (81) and an unloading step (S110) of unloading the sluice gate (10) on which shot blasting is completed;

A shortball transfer belt is installed on one side of the transport boom that is connected to the bogie and moves back and forth to transport the shortball, and a shortball supply hole is formed in the shortball supply box where a number of rotary blades are installed to rotate the transferred shortball. A short ball supply step (S120) including a boom device for discharging and transferring;

The conveying boom unit is penetrated and the separation guide supporting the conveying boom is installed so that the height can be adjusted, and the short ball cap on the inlet side to which the front end of the short tank 200 to which the water gate is supplied is fixed is installed and the short ball is discharged to the lower side An inlet-side short cap step (S130) including an inlet-side short cap device in which a shortball discharge unit is installed in a cap body having a portion;

A short ball cap on the discharge side, to which one end of the short tank 200 to which the water gate 10 is supplied is fixed, is installed, and a center shifter is installed on the reinforcing rod inside the short ball discharge part installed in the cap body having the short ball discharge part to the lower side. A discharge-side short cap step (S140) including a discharge-side short cap device in which the fixing rod of the sluice gate support is coupled to the protruding installation stand (S140);

A step (S30) of coating the sluice in a coater that coats the sluice after the short blasting is completed with an epoxy paint containing a curing agent having phenalkamine mixed with the subject and the subject having an epoxy resin (S30). It is to provide a manufacturing method for doing.

Hereinafter, FIG. 10 according to an embodiment of the present invention shows a front view of a shorting device 80 according to an embodiment of the present invention. And Figure 11 shows a plan view of the short device 80 according to an embodiment of the present invention. 12 shows a side view of a short device 80 according to an embodiment of the present invention.

As shown in FIGS. 10 to 12, the shorting device 80 includes a base 81, a loading device 82, an unloading device 83, cap devices 800 and 850 for shorting on the inlet side and the discharge side, It can be seen that it can be configured to include dust collectors 840 and 870, a short ball discharge transfer unit 88, a short ball supply unit 881, and the like.

The loading device 82 loads the cooled water gate 10 to the inner base 81 of the short tank 200, and the unloading device 83 unloads the water gate 10 after shot blasting. is composed of The cap detachable means attaches the inlet-side short cap 805 to the discharge-side end of the water gate 10 by the cap transfer unit 84 and installs the inlet-side inner diameter short cap 855 to the inlet-side end.

The inlet and outlet shot cap devices 800 and 850 are installed on both sides of the base 81, and the water gate 10 is stored in the short tank 200 for shot blasting. 805, 855), and the short ball discharge transfer part 88 is installed below the base 81 and the short ball discharge part 808, 858, and the surface of the water gate 10 is shot blasted. To collect and supply to the shortball storage unit 880 to be stored.

The conveying boom unit 90 has a short ball supply device 900 installed at one end so that the short ball is supplied with a constant rotational force.

Dust collectors 840 and 870 are connected to the inlet and outlet cap devices 800 and 850, respectively, and a shortball storage unit 880 is installed in the inlet cap device 850 for short balls. The supply unit 881 and the short ball recovery unit 881 are installed.

Hereinafter, according to an embodiment of the present invention, Figure 13 is a front view of the transfer boom unit 90 of the short device of the present invention, and Figure 14 is a main part of the transfer boom unit 90 of the short device of the present invention Figure 15 is a plan view of the main part of the transfer boom unit 90 of the short device of the present invention, Figure 16 is a side view of the main part of the transfer boom unit 90 of the short device of the present invention, Figure 17 is a front cross-sectional view of the main part of the transfer boom unit 90 of the short device of the present invention, Figure 18 is a front view of the installation state of the right side of the transfer boom unit 90 of the present invention.

The conveying boom device 90 has a shortball conveying belt 92 installed biased in one direction so as to have a length equal to the overall length on the upper side of the conveying boom 91, and shortball discharged through the shortball supply unit 881 The balls are transported and supplied in a belt shape, and a shortball supply hopper 901 is installed at the tip of the shortball conveyance belt 92 inclined downward toward the lower direction, so that the shortballs to be transported are collected in the center and the shortball supply device (900) to be discharged.

A frame 902 is installed in a "c" shape at the front end of the transfer boom 91, so a short ball supply cylinder 905 is installed in the center, and a rotating belt 904 through a hydraulic pump 903 on one side To rotate at high speed, the shortball supply hopper 901 is connected to the shortball supply cylinder 905 so that shortballs are supplied, and at the same time, shortball supply holes 906 are formed at regular intervals to shortball the tank at a rotational speed. (200) is supplied to the sluice gate 10 supplied to the inside for short blasting, and the short ball supply cylinder 905 has rotary blades 907 installed at regular intervals to supply short balls while rotating to the short tank 200 ) is to short blast the surface of the water gate (10) from the inside.

The rotary blades 907 are installed at regular intervals in the shortball supply box 905 to rotate at high speed, and are formed in an "I" shape on a plane so that the shortball is supplied by rotational force in the outer diameter direction.

The bogie 710 to which the front end of the boom support device 90 for transfer is connected is installed with a bogie driving device 700 and coupled to the cap transfer unit 84 on the lower side to enable reciprocating transfer, and the upper side of the bogie 710 has a hydraulic The device 920 is installed to supply hydraulic pressure to the hydraulic pump 903 to rotate and supply the short ball with hydraulic pressure to perform short blasting.

According to a preferred embodiment of the present invention, FIG. 19 is a front view of the discharge side short cap device 800 of the present invention, FIG. 20 is a side view of the discharge side inner diameter shot cap device 800 of the present invention, and FIG. 21 is the present invention. 22 is a side view of the main part of the cap device 800 for shorting the inner diameter of the discharge side of the present invention, Figure 23 is a side view of the inlet side and the discharge side of the present invention A side view of the replacement cap of the short cap device (800, 850), Figure 24 is a front view of the main part of the inlet side of the present invention, Figure 25 is a short cap (805) of the discharge side and the inlet side of the present invention , 855) shows a side cross-sectional view of the main part.

The inlet and outlet short caps 805 and 855 made of rubber material are formed in a circular shape to face each other in the inlet and outlet short cap devices 800 and 850 installed at regular intervals, so that they face each other. 806, 856) are fixed with fixing bolts (807, 857) so that the front end of the short tank 200 is in contact with and separated from the outside, and is reciprocated from the lower side through the hydraulic cylinder 780, and the cap moving part ( 84) to guide the round-trip movement.

In the part where the fixing rings 806 and 856 are installed, the size of the short tank 200 decreases and the central part moves downward, and the closing member 890 having a hole inside is exchanged according to the size. with that,

In the closing member 890, the fixing rings 806 and 856, which are formed to be larger than the size of the short tank 200, are located and cover the remaining portion to protect the open portion of the cap body 801 and 851, , It is to install it so that both ends are blocked from the outside by replacing it according to the size of the short tank 200.

In the discharge-side short cap device 800, a shortball discharge unit 808 installed in a hopper shape on the lower side of the cap body 801 is installed and located on the upper side of the shortball transfer unit 88 to supply shortballs, , After the reinforcing bars 802 are installed in the horizontal and vertical directions, the center shifter 803 is installed to be movable in the vertical direction, and the mounting table 804 protrudes in the direction of the short cap 805 on the discharge side.

The sluice gate stand 810 with a fixing 811 coupled to and separated from the mounting 804 is installed in a criss-cross pattern to support the short cap 805 so that the front end of the short tank 200 supplied with the sluice gate 10 It is supported and fixed, and a center moving shaft 809 is installed above the center of the center moving table 803 so that the height can be adjusted at the reinforcing table 802.

The center moving shaft 809 is installed to adjust the height through the height adjustment chain 820 of the height adjustment cylinder 821 installed vertically on the outside, and the dust collector 840 through the dust discharge unit 810 on the upper side. ) to discharge and treat the dust generated from the cap body 801 to the outside.

In the inlet-side short cap device 850, a shortball discharge unit 858 installed in a hopper shape is installed on the lower side of the cap body 851 and is located on the upper side of the shortball transfer unit 88 to supply shortballs, , so that the transfer boom 91 penetrates, and the boom guide 700 through which the transfer boom 91 penetrates is installed.

The boom guide 700 has a boom guide 703 installed on the lower side to support movement from the lower side of the transfer boom 91, and a boom guide height adjustment screw 702 installed from the center to the upper side to adjust the position according to the required position. It is installed so that the height can be adjusted.

A dust discharge unit 860 is installed on the upper side of the inlet side short cap device 850 to discharge dust to the outside by connecting to an external dust collector 870, and the short ball supply device 900 has a short ball A storage unit 880 is installed so that the shortball supply unit 881 for supplying shortballs to the upper side of the shortball transfer belt 92 is connected, and the shortball discharged from the lower shortball transfer unit 88 is moved upward. A shortball recovery unit 882 is installed to transport and store the shortball in the shortball storage unit 880 so that it can be reused.

Although the use of the short tank 200 in a circular shape has been described, its size can be freely adjusted, and it can be formed in a square or polygonal shape, and according to the short tank 200, the inlet and outlet short ball cap devices ( 800, 850) also includes having a corresponding shape.

The mixing ratio of the main agent having an epoxy resin and the curing agent containing phenalkamine according to an embodiment of the present invention in which the water gate 10 is shot blasted inside the shot tank 200 using the shot device 80 and then coated thereon It is composed of 4: 1, and more specifically, it is preferable that the main agent and the curing agent are mixed in a volume ratio of 3 to 5: 0.5 to 1.5.

In addition, the subject matter according to the embodiment of the present invention is composed of a bisphenol F type epoxy resin, a urea resin, a pigment, and a solvent.

The specific composition ratio includes 15 to 30% by weight of a bisphenol F-type epoxy resin, 1 to 5% by weight of a urea resin, 45 to 80% by weight of a pigment, and 11 to 35% by weight of a solvent based on the total weight of the main body.

In addition, the pigment according to an embodiment of the present invention comprises 10 to 15% by weight of titanium dioxide as a color pigment and 0.02 to 0.1% by weight of a black pigment, and 20 to 40% by weight of talc as a filler pigment. And it can be seen that it is composed of 15 to 30% by weight of silica powder.

In addition, 10 to 30% by weight of xylene and 1 to 5% by weight of propylene glycol methyl ether are included as solvents.

In addition, it can be seen that the epoxy curing agent according to an embodiment of the present invention includes 80 to 89% by weight of phenalkamine, 10 to 15% by weight of xylene as a solvent, and 1 to 5% by weight of a hardening accelerator.

In the present invention, when performing the coating operation of the sluice gate (10), finishing members are installed according to the size of the shot tank (200) to both ends of the shot tank (200) for the purpose of cleaning before coating the epoxy paint to which phenalkamine is applied. After installing the cap using (890), a short ball is supplied, and the water gate (10) inside the short tank (200) is shot blasted with strong pressure using the hydraulic device (920) and the hydraulic pump (903) to clean it. By allowing the coating of the polyamine two-component epoxy resin paint to which the curing agent containing phenalkamine is applied immediately through preheating in one state, the effect of accurate coating of the epoxy paint to which phenalkamine is applied, and (salt) water resistance and chemical resistance Of course, it has excellent abrasion resistance, and it is possible to perform coating on various surfaces, and it is possible to paint at low temperatures such as in winter, so it provides the effect of enabling work without seasonal influence.

According to the epoxy paint to which phenalkamine is applied according to an embodiment of the present invention, since the phenalkamine curing agent is applied, the hydrophobicity unique to the phenalkamine molecule minimizes the effect of contact with water molecules to enable painting, Excellent sluice coating effect through quick-drying through excellent low-temperature curing performance, coating is performed immediately after cleaning the inner diameter of the sluice, so it has excellent adhesion, salt water resistance, rust prevention and excellent water resistance, and curing and drying at low temperature It is to provide long fibers that are thick-coated and can be painted after simple surface treatment.

According to the shot tank according to an embodiment of the present invention, the process for installing the cap is quickly and conveniently performed on both sides according to the size, and after performing shot blasting by supplying the shot ball, dust and contaminants generated during the work process The silver is removed, the shotball is recovered and reused, and the sluice is coated with phenalkamine-applied epoxy paint immediately after short blasting to provide various advantages by coating the gate in a state that is not contaminated or corroded.

According to the short tank according to the embodiment of the present invention, the cap is quickly detached and attached according to the size, and the separation from the outside is accurate to prevent contamination, and according to the size of the short tank, the exchange and number of caps for installation are It is advantageous to provide a sluice gate and its coating device in which both ends of the gate are firmly fixed and supported, and the inner diameter of the sluice is shot blasted quickly and accurately.

10: water gate 11: guide frame
12: stop jaw 15: auxiliary beam
16: upper beam 20: gate leaf
21: bar rubber 22: rubber fixing bolt
25: stop member 30: rack bar
31: rack type winch 31: winch handle
40: transfer means 50: preheating furnace
80: inner diameter short device 81: base
82: loading device 83: unloading device
84: cap transfer unit 88: short ball transfer unit
90: transfer boom unit 91: transfer boom unit
700: separation guide 701: guide guide shaft
702: separation height adjustment screw 703: separation guide
710: bogie 780: hydraulic cylinder
800: Cap device for shorting the inner diameter of the discharge side 801, 851: Cap body
802: reinforcement bar 803: center shift bar
804: Mounting stand 805: Cap for inlet inner diameter short
806, 856: fixing ring 807, 857: fixing bolt
808, 858: short ball discharge unit 809: center moving axis
810: water gate stand 811: fixture
820: height adjustment chain 830: dust discharge unit
840, 870: dust collector 850: cap device for inlet side internal short
860: dust discharge unit 880: short ball storage unit
881: short ball supply unit 882: short ball recovery unit
890: finishing member 900: short ball supply device
901: short ball supply hopper 902: frame
903: hydraulic pump 904: rotating belt
905: short ball supply groove 906: short ball supply hole
907: rotary blade 920: hydraulic system

Claims (9)

The sluice gate is put into the inclined seat of the inner and outer diameter shot machine by the transport means, and the shot part having the spraying part at the end enters the longitudinal direction of the sluice gate by the moving unit to short-blast the sluice gate, Shot blasting step of ball injection; Putting the sluice gate for which shot blasting has been completed by a shot machine into a preheating furnace and preheating it to 350 ~ 380 ° C; A sluice gate supply step of mounting caps for rotating the sluice gate to both ends of the short tank to which the preheated sluice gate is supplied; While being mounted on the sluice rotation cap and rotating the sluice on the basis of the central axis in the longitudinal direction, the FBE coating unit applies powder epoxy coating to the outer surface of the sluice, and the adhesive coating unit coats the adhesive on the outer surface of the epoxy-coated sluice, , External surface coating step of coating PE on the outer surface of the sluice coated with the PE coating unit adhesive; removing the cap for rotating the sluice gate and spraying water into the sluice gate to cool the sluice gate; A step in which the cooled sluice gate is seated on the inclined base of the inner diameter shot machine, a transfer boom is put into the sluice gate by the transfer unit, and shot blasting is performed by rotating and spraying the short ball by the impeller injection unit provided at the end. ; and epoxy coating the sluice after the short blasting is completed in a state in which the sluice gate is rotated by the rotating roller;
The step of performing the short blasting,
A loading step of loading the cooled sluice gate onto the inclined base, and an unloading step of unloading the sluice gate after shot blasting;
A shortball transfer belt is installed on one side of the transport boom that is connected to the bogie and moves back and forth to transport the shortball, and a shortball supply hole is formed in the shortball supply box where a number of rotary blades are installed to rotate the transferred shortball. A short ball supply step including a boom device for discharging and transferring;
The conveying boom unit is penetrated and the separation guide supporting the conveying boom is installed so that the height can be adjusted, and the short ball cap on the inlet side to which the front end of the short tank 200 to which the water gate is supplied is fixed is installed and the short ball is discharged to the lower side An inlet-side short cap step including an inlet-side short cap device in which a shortball discharge unit is installed in a cap body having a portion;
A short ball cap on the discharge side to which the other end of the short tank 200 to which the water gate is supplied is fixed is installed, and a center shifter is installed on the reinforcing bar inside the short ball discharge part installed in the cap body having a short ball discharge part to the lower side, A discharge-side short cap step including a discharge-side short cap device in which a fixing rod of a sluice gate support is coupled to a protruding mount;
The epoxy coating step,
While rotating the sluice gate where the shot blasting is completed, an epoxy spray transfer boom having an epoxy spray nozzle at the end is put into the sluice by a boom transfer cart, mixed with the main body and main body having epoxy resin, and epoxy containing hardener having phenalkamine Epoxy coating in a coating machine for coating the paint; A method for manufacturing a sluice gate by applying phenalkamine epoxy paint after using a shot machine, characterized in that it comprises a.
According to claim 1,
In the shortball supply step, the shortball transfer belt is installed on one side of the transfer boom connected to the bogie, and the shortball is supplied from the shortball supply hopper installed at the tip of the shortball transfer belt. The supply tube is connected to the hydraulic pump through a rotating belt, and after short ball supply holes are formed at regular intervals in the short ball supply tube, the rotary blade is connected and rotates to supply short balls to short blasting the sluice in the short tank. A method for manufacturing a sluice gate by applying phenalkamine epoxy paint after using a short machine, characterized in that it comprises a ball supply device.
According to claim 1,
In the discharge-side short cap device of the discharge-side short cap step, the discharge-side short cap to which one end of the short tank supplied with the sluice gate is fixed is fixed to the cap body with a fixing bolt through a fixing ring, and the cap body The height of the reinforcing rod installed inside is adjusted, and the center shifting shaft is installed on the upper side, and the center shifter having the mounting base formed in the front, and the sluice holder having the fixing base fixed in the shape of a cross to the center shifter, A method of manufacturing a sluice gate by applying a phenalkamine epoxy paint after using a shot group comprising fixing to the inside of a cap.
According to claim 1,
In the inlet short cap device of the inlet short cap step, the inlet short cap to which one end of the short tank supplied with the sluice gate is fixed is fixed to the cap body with a fixing bolt through a fixing ring, and the cap body The boom bar guide installed inside is installed so that the height of the reinforcing bar is adjusted in the guide guide groove, and after the boom bar height adjustment screw is installed on the upper side, a separation guide is formed on the lower side to support the transport boom bar, and a short ball on the cap body A method of manufacturing a sluice gate by applying a phenalkamine epoxy paint after using a short machine comprising installing a discharge means.
According to claim 1,
The inlet and outlet short cap devices of the inlet and outlet short cap stages have holes for fixing sluice gates and install caps for inlet and outlet shorts to be installed according to the size of the short tank to which the sluice gate is supplied. A method for manufacturing a sluice gate by applying phenalkamine epoxy paint after using a short machine, characterized in that it forms a fixing ring and includes a finishing member fixed with a fixing bolt.
According to claim 4,
The shortball discharge means has a shortball supply unit installed in the shortball storage unit to supply shortball to the shortball transfer belt, and the shortball recovery unit connected to the shortball storage unit is connected to the shortball transfer unit to supply the shortball to the shortball transfer belt. A method of manufacturing a sluice gate by applying phenalkamine epoxy paint after using a shot machine comprising installing to recover the shot balls collected through the ball discharge unit.
According to claim 1,
In the cap device for the inlet and outlet shots of the inlet and outlet shot cap steps, the dust discharge part is connected to the cap body on the upper side, and the dust discharge part is connected to the collector. A method for manufacturing a water gate using Min Epoxy paint.
According to claim 1,
In the step of coating the water gate, the epoxy paint coated using the coater includes a subject having an epoxy resin; And a curing agent mixed with the main agent and having phenalkamine;
The main agent and the curing agent are mixed in a volume ratio of 3 to 5: 0.5 to 1.5,
The subject is
Based on the total weight of the main subject, 15 to 30% by weight of a bisphenol F-type epoxy resin, 1 to 5% by weight of a urea resin, 10 to 15% by weight of titanium dioxide as a color pigment and 0.02 to 0.1% by weight of a black pigment, talc as a filler suggesting pigment 20 to 40% by weight and 15 to 30% by weight of silica powder, and 10 to 30% by weight of xylene and 1 to 5% by weight of propylene glycol methyl ether as solvents,
The curing agent,
Based on the total weight of the curing agent, 80 to 89% by weight of phenalkamine, 10 to 15% by weight of xylene as a solvent, and 1 to 5% by weight of a hardening accelerator are used, and then phenalkamine epoxy paint is applied. How to make a floodgate.
Guide frames 11 installed at regular intervals on both sides are installed to face each other, the lower side of the auxiliary beam 15 and the upper side of the upper beam 16 are connected, and the inside of the guide frame 11 and the auxiliary beam 15 A square gate leaf 20 is installed to adjust the height;
A stopper 12 protrudes from the guide frame 11, and a stop member 25 is located where it meets the stopper, installed on the opposite side, and fixed by a rubber fixing bolt 22 on the slope from the front of the gate leaf 20. It includes sealing with a fixed bar rubber 21;
After being coupled with a connecting pin 24 on the upper center of the gate leaf 20, a rack bar 30 is installed in the vertical direction to penetrate the rack-type hoist 31, and the rack-type hoist 31 has a winching handle ( 32) is installed and consists of a water gate 10 in which the gate leaf 20 vertically rises and falls within the guide frame 11 according to the rotation direction;
The sluice gate 10 is put into the inclined seat of the inner and outer diameter shot machine by the transfer means, and the shot part having the spraying part at the end enters the longitudinal direction of the sluice gate by the moving unit to short-blast the sluice gate, spraying a short ball into the gate; Putting the sluice gate for which shot blasting has been completed by a shot machine into a preheating furnace and preheating it to 350 ~ 380 ° C; A cap for rotating the sluice gate is installed at both ends of the short tank to which the preheated sluice gate is supplied; While being mounted on the sluice rotation cap and rotating the sluice on the basis of the central axis in the longitudinal direction, the FBE coating unit applies powder epoxy coating to the outer surface of the sluice, and the adhesive coating unit coats the adhesive on the outer surface of the epoxy-coated sluice, , the PE coating unit coats the outer surface of the adhesive-coated sluice with PE; After removing the cap for rotating the sluice gate and cooling the sluice gate by spraying water into the inside, the cooled sluice gate is seated on the inclined base of the inner diameter short, and a boom for transferring to the sluice gate is inserted by the transfer unit, Short blasting is performed by rotating and spraying short balls by the impeller injection unit provided at the end; A sluice to which phenalkamine epoxy paint is applied after using a shot machine, characterized in that the sluice after shot blasting is epoxy coated while being rotated by a rotating roller.

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