KR200222275Y1 - Structure of Displacement Pump for Airless Painting Device - Google Patents

Abstract

The present invention relates to a delivery pump structure of an airless coating device, in the airless coating device 100 in which the air motor 2 and the delivery pump 100 interlock to spray paint, the upper end is coupled to the air motor (2) And a housing 110 formed with a paint spraying hole 112 for injecting paint on the upper outer periphery of the upper outer periphery, and ceramics installed in the housing 110 but formed in a tubular shape to form a pressurized space therein. And a rod (130) coated with a ceramic (120) for inserting into the inner pressurized space of the sleeve (120) and operating up and down to increase internal pressure, and attached to a lower end of the rod (130) and having a ceramic surface. Coated with a piston 140 for pumping and spraying the sucked paint, a connecting portion 150 connected to an upper portion of the housing 110 to connect the air motor 2 generating pressure of the paint, and the housing ( Bottom of 110) It characterized in that it consists of a suction unit 160 for sucking the paint.

Therefore, since the paint of the delivery pump is directly contacted and pressurized with a ceramic coating, the wear resistance is increased and the solidification phenomenon caused by the reaction with the paint is significantly reduced, thereby providing an effect of extending the life.

Description

Structure of Displacement Pump for Airless Painting Device

The present invention relates to a delivery pump structure of an airless coating device, and more particularly, an airless coating device for prolonging service life by preventing abrasion and oxidation by coating a portion of the pump directly in contact with paint. Of the delivery pump structure.

In general, steel structures such as bridges and ships are coated with various anti-corrosive paints to prevent shortening the lifespan due to corrosion, so that moisture, acidic substances such as oxygen, and salts act on the steel to oxidize the steel. It was made.

In addition, the coating of such steel structures is short, and thus can not be maintained until the end of the life of the structure in a single construction, so that the paint works every time before a certain period for proper maintenance and management to prevent oxidation of the steel. It was.

In particular, painting and repair work involves considerable manpower and cost, and therefore it is preferable to use a paint with a long life if possible.

To this end, recently, a new anti-corrosive paint has been developed and used radically for painting steel structures, which can maintain a paint life of about 25 years by painting once.

This new rust-preventive paint has the characteristic of chemically reacting with the metal component of steel structures to form a reducing protective film.

As a coating apparatus used to coat the paint, there is a painting apparatus using an airless pump, which does not directly use high pressure air to inject the paint, but to a pump that is to spray the paint by inorganic spraying. The pump was used to operate the displacement pump rod to pressurize the paint and directly spray the paint.

These airless pumps have an advantage of reducing paint loss due to scattering due to high efficiency of painting and less spraying with air because they are not sprayed with air.

As shown in FIG. 1, the conventional painting apparatus using an airless pump has a negative pressure generated by interlocking a single rod (not shown) up and down by installing an upper air motor 2 and a lower delivery pump 100. The paint is sucked and sprayed by the excessive pressure.

Here, the parts directly contacting the paint of the delivery pump 100 were first processed by heat treatment, secondary processing by high frequency heat treatment and polishing, and finished with chrome plating.

However, in the conventional coating apparatus using an airless pump, parts such as chrome plated pistons and rods are abraded by paints and impurities, resulting in peeling of chromium plating, and the paints have high affinity with steel materials in the peeled parts of the parts. Due to the sticking phenomenon occurs.

In addition, such a solidification phenomenon has a problem that the life is shortened because foreign matters due to the solidification of the paint can not be maintained to maintain a constant pressure ratio, pulsation phenomenon occurs during the painting work, because inconsistent injection occurs to replace the parts.

The present invention was devised to solve the problems as described above, and its purpose is to improve the wear resistance by preventing the coating of the parts in contact with the paint of the delivery pump with a ceramic and to maintain a constant pressure continuously Not only can the work be done smoothly, but the life of the parts can be extended.

1 is a perspective view showing a general airless coating device.

Figure 2 is an exploded perspective view showing a delivery pump structure of the airless coating device of the present invention.

Figure 3 is an enlarged perspective view of some parts of the delivery pump of the airless coating device of the present invention.

* Description of the symbols for the main parts of the drawings *

1: Airless coating device 2: Air motor

100: delivery pump 110: housing

111: flange 112: paint injection hole

120: sleeve 130: rod

131: paint spray hole 132: ball

133: ball guide 140: piston

141: packing 150: connection

151: Packing 152: Nut

160: suction part 161: retaining ring

162: Ball 163: Ball Guide

164: main fastener 165: sub fastener

166: suction pipe

Accordingly, the delivery pump structure of the airless coating device of the present invention is an airless coating device in which an air motor and a delivery pump are interlocked to inject a paint, the upper end is coupled to the air motor to communicate with the spraying paint on the upper outer periphery A housing in which a paint spray port is formed, a sleeve coated in a tubular shape and formed in a tubular shape to form a pressure space therein, and inserted into an internal pressure space of the sleeve and operated up and down to increase internal pressure. Connecting a ceramic coated rod, a piston attached to the lower end of the rod and coating the surface with ceramic, for pumping and spraying the sucked paint, and connecting an air motor connected to the upper part of the housing to generate paint pressure. Consisting of a connecting part and a suction part for sucking paint on the lower part of the housing It features.

Hereinafter, a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

Figure 2 is an exploded perspective view showing the delivery pump structure of the airless coating device of the present invention, Figure 3 is an enlarged perspective view of some parts of the delivery pump of the airless coating device of the present invention.

As shown in Figures 2 and 3, the delivery pump structure of the airless coating device of the present invention is coupled to the upper end of the air motor to communicate with the housing 110 is formed with a paint spray port 112 for spraying paint on the upper outer periphery And a ceramic-coated sleeve 120 installed inside the housing 110 but formed in a tubular shape to form a pressurized space therein, and inserted into an inner pressurized space of the sleeve 120 and vertically operated. The rod 130 is coated with a ceramic to increase the internal pressure, the piston 140 is attached to the lower end of the rod and the surface is coated with a ceramic, but pumps the suction material, connected to the upper portion of the housing 110 It is composed of a connecting portion 150 for connecting the air motor (2) for generating the pressure of the paint, and the suction unit 160 for sucking the paint in the lower portion of the housing (110).

The housing 110 completely seals the upper and lower connecting portions to form a paint spray port 112 that communicates with the inside in one side on the upper side of the outer circumference, and forms a flange 111 at the top to be combined with the air motor 2. To help.

The sleeve 120 forms a pressurized space in a tubular shape to form a ceramic coating on the surface of the inner and outer circumferences and inserts and fixes the ceramics in the interior of the housing 110.

The rod 130 is formed by coating a ceramic on the surface of the rod 130 is inserted into the internal pressure space of the sleeve 120, but the upper end is connected to the air motor (2) to be doubled up and down.

In addition, the rod 130 should be able to maintain the inner circumference and a constant interval of the sleeve 120 in order to enable a double-acting movement up and down and to secure a pressurized space.

Further, the paint spraying hole 131 communicates with the lower side of the rod 130 to one side and inserts a backflow preventing ball 132 having a ball guide 133.

The piston 140 is coupled to the lower end of the paint spraying hole 131 of the rod 130 and formed by coating a ceramic on the surface, but vertically forms a passage communicating with the paint spraying hole 131.

Here, the piston 140 is provided with a plurality of packing for sealing 141.

The connection part 150 forms a flange 111 corresponding to the air motor 2 on the upper part of the housing and fastens the nut 152 having the packing 151 at the center of the upper surface of the housing 110.

The suction unit 160 corresponds to the piston 140 by inserting a stopper retaining ring 161 having a pin for determining a bottom dead center of the piston 140 at a lower portion of the housing 110. Insert the backflow prevention ball 162 having the ball guide 163 in the lower side of the 161, but the main fastener 164 is coupled to the lower inner circumference of the housing 110 to fix the position of the ball 162. .

Here, the main fastener 164 forms a passage for vertically sucking the paint and couples the sub fastener 165 which forms a passage communicating with the lower side of the passage of the main fastener 164.

Further, the sub fastener 165 is connected to the suction pipe 166 to suck the paint.

Referring to the operation of the present invention is as follows.

First, when the air motor 2 is operated in a state in which the suction pipe 166 is connected with the paint, the rod 130 moves up and down to generate suction force.

At this time, due to the suction generated paint is pushed up the ball 162 through the suction pipe 166, the sub fastener 165 and the main fastener 164, the paint of the passage of the piston 140 and the rod 130 It is introduced into the sleeve 120 through the injection hole 131.

In such a state, when the piston 140 is raised, the backflow preventing ball 132 blocks the paint spraying hole 131 to the paint spraying hole 131 of the rod 130 and the sleeve 120 as the piston 140 is raised. The paint located inside the is pressurized to be sprayed to the outside of the housing 110 through the paint spraying hole 112 so that the painting can be executed.

At the same time, a suction force is generated at the lower side of the piston 140 due to the rise of the piston 140. As a result, the backflow preventing ball 162 located between the main fastening hole 164 and the retaining ring 161 has a main fastening hole ( The passage of 165 is opened to suck the paint.

On the other hand, when the piston 140 is lowered, the backflow prevention ball 162 located between the main fastener 164 and the retaining ring 161 blocks the passage of the main fastener 164 by pressure and at the same time Open the backflow prevention ball 162 of the rod 130 to move the paint sucked in the lower side of the piston 140 into the sleeve 120 located above the piston 140 to compress and pressurize the paint as described above. To continue the painting work.

Therefore, by spraying only the paint in the double-acting motion of the rod 130 proceeds to the best paint work.

In particular, the present invention is because the surface of the sleeve 120 and the rod 130 and the piston 140 is coated with a ceramic can minimize the wear phenomenon due to the double-up and down double motion can significantly extend the life of the delivery pump.

Furthermore, since the wear of the sleeve 120, the rod 130, and the piston 140, which are the main components, is minimized, the operation of the equipment can be maintained in a good state for a long time.

As described above, according to the delivery pump structure of the airless coating device of the present invention, since the coating portion of the delivery pump is directly contacted and pressurized with ceramic, the wear resistance increases and the solidification phenomenon caused by the reaction with the paint is remarkably increased. It provides the effect of reducing the life span.

Claims (1)

In the airless coating device 100 in which the air motor 2 and the delivery pump 100 is interlocked to inject paint, A housing 110 having a top end coupled to the air motor 2 so as to communicate therewith and forming a paint spray port 112 for spraying paint on the upper outer periphery; A sleeve 120 installed inside the housing 110 but formed in a tubular shape to form a pressurized space therein; A ceramic coated rod 130 inserted into the inner pressurizing space of the sleeve 120 and operating up and down to increase internal pressure; A piston 140 attached to the lower end of the rod 130 and coating the surface with ceramic, for pumping and spraying the sucked paint; A connection part 150 connected to an upper portion of the housing 110 to connect an air motor 2 generating pressure of paint; Delivery pump structure of the airless coating device, characterized in that composed of a suction unit 160 for sucking the paint in the lower portion of the housing (110).