JPS5811057A - Melt-spraying device - Google Patents

Abstract

PURPOSE:To form a smooth melt-sprayed coating film, by catching what is called ''overspray mist''. CONSTITUTION:By a feeding means 2 consisting of plural hoses, etc., flame gas, a coating material pulverulent body, cooling air, etc. are supplied, also a melt- spraying nozzle 3 is connected to the means 2, and a ring-like cover 5 is attached to the nozzle 3 through a supporting rack 4. Also, the device is constituted so that while a coating material pulverulent body jetted from the nozzle 3 together with cooling air scatters, being heated and melted by melt-spraying flame jetted from the nozzle, pulverulent body particles which are scattered around the radial flame and are not heated enough by the melt-spraying flame are subjected to curving its advancing direction by the ring-like cover 5 and are scattered along the surface of the cover 5. Its cover 5 makes a hollow, has a slit 50 and an exhaust port 51, the exhaust port 51 is connected to a suction means, air of the inside and outside of the cover 5 is sucked through the slit 50 and the exhaust port 51 by the suction means, and the pulverulent body particles are caught through the slit 50.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a thermal spraying apparatus for thermally spraying thermosetting plastic powder such as epoxy resin to 1% plastic thermal spray coating.

Plastic thermal spray coating, which is a powder coating method, uses simple coating equipment, unlike powder coating methods that use heating furnaces, such as electrostatic coating and fluidized dipping.

, and an extremely thick membrane can be obtained.

It has characteristics such as being able to be painted on existing structures. The powder coatings used for this purpose include powders of thermoplastic resins, such as nylon, polyethylene, and vinyl chloride, and powders of thermosetting resins, such as epoxy resins, with forms and properties suitable for thermal spray coating. be.

Among these, epoxy resin has excellent mechanical properties, electrical properties, thermal properties, chemical properties, etc.

2 and has many features such as a high degree of freedom in curing reaction speed and shape. Therefore, in recent years, it has been increasingly used as an anticorrosion powder coating.

When this epoxy resin is blended in such a way that the curing reaction rate is particularly fast and applied to thermal spray coating, it can be carried out in a general powder coating process. It becomes possible to omit the so-called post-heating step in which the curing reaction is completely completed by heating at a predetermined temperature for a predetermined time. Therefore, there are no restrictions on the shape of the object to be coated, and existing structures can also be powder coated. Epoxy resins have therefore been widely used as type 1 cut linings and electrical insulation linings.

Thermal spray coating using epoxy resin powder without a "post-heating" process is, as mentioned above, an epoxy resin powder book?
The curing reaction is completed by heating at a predetermined temperature for a predetermined time, and in fact, the curing reaction must be completed only by preheating the object to be coated and the radiant heat of the spray flame. Therefore, the epoxy resin used as the material needs to be a composition with an extremely fast curing speed. The gelation time, which is one of the indicators of curing speed, is 1, for example, 2 minutes at a temperature of 110°C8.
0 seconds, 1 minute at 160°C, 20 seconds at 200°C, etc.

In thermal spray coating using powder of such a fast-curing composition, about 80% of the curing reaction has already occurred before the sprayed resin adheres to the surface of the object to be coated. Immediately after it adheres to the surface of the object to be coated, it gels almost instantaneously, and then the curing reaction is completed. Therefore, the period during which the resin remains in a fluid state on the surface of the object to be coated is short, and the range of conditions under which a smooth coating film can be obtained is extremely narrow. However, since the resin portion that is directly hit by the spray flame is sufficiently heated, it is possible to heat and melt the resin, which has increased in viscosity due to the progress of the curing reaction, until it becomes a smooth coating film.

On the other hand, it scatters around the spray flame. Overspray mist and so-called particles are also undergoing a curing reaction. However, since sufficient radiant heat cannot be obtained from these particles, even if they adhere to the object to be coated, they do not melt but gel, and then harden. Therefore, it is not only impossible to obtain a smooth coating film, but also causes coating film defects such as inclusion of air bubbles and pinholes.

An object of the present invention is to provide a thermal spraying device f that forms a smooth thermal spray coating film.
i'. Another object of the invention is to provide a thermal spraying apparatus which traps so-called overspray. A further object of the present invention is to provide a thermal spraying apparatus particularly suitable for thermal spray coating of thermosetting plastic powder such as epoxy resin.

Hereinafter, the present invention will be described in detail based on embodiments and with reference to the drawings. As shown in FIGS. 1 and 2.

The thermal spraying apparatus 1 of the present invention includes a supply means 2, a thermal spray nozzle 8, and an annular cover 5. The supply means 2 is made up of, for example, a plurality of hoses, and is connected to the rear end of the thermal spray nozzle 8 . These hoses can handle flaming gases like propane and oxygen gases, and paint powders.

Cooling air and the like are supplied to the thermal spray nozzles 8, respectively.

An annular cup (-5) is attached to the nozzle 8 via a support frame 4. One end 41 of this support frame 4 surrounds the vicinity of the tip of the thermal spray nozzle 8.The other end of this support frame 4 42 has an annular cover 5 fixed along its periphery.
This causes the Coanda effect. This cover 5
is preferably made of a hollow pipe or the like, and has a slot 50 opened therein. The cover 5 also has an exhaust port 51 and is connected to suction means such as a suction pump (not shown) through this.

The flame gases supplied to the nozzle 8 via the supply means 2 are mixed there, become a thermal spray flame 81, and are injected from the nozzle tip 80. The material powder is sent to the nozzle tip B along with the cooling air.
The thermal spray 82 is injected from O into the thermal spray flame al. The thermal spray 82 receives radiant heat from the thermal spray flame 81 and is heated. The material powder of the heated thermal spray spray 82 is melted and flies toward the object 6 to be coated outside the annular cover. The object to be coated 6 is preheated to a predetermined temperature.

The molten material powder adheres to the surface and forms a coating film 7 on the entire surface.

While the thermal spray spray V-82 flies toward the outside of the apparatus I, the overspray mist 8B is scattered around the thermal spray spray 82. The overspray bust 33 is bent in its traveling direction by the "Coanda effect" of the annular cover 5. The overspray whose traveling direction is bent is scattered radially from the tip of the device 1 parallel to the object 6 to be coated, and does not collide with the object 6 to be coated. especially.

When the air inside and outside the annular cover is constantly sucked by the suction means through the slit 50 and the exhaust port 51, the overspray mist scattered along the surface of the annular force bar is absorbed into the cover and/or along with the suction air. Or captured by suction means. Therefore, the overspray mist does not adhere to and accumulate on the surface of the annular cover 5, and the effect of changing the traveling direction of the overspray mist is increased.

Next, is there an experimental example of thermal spray coating of epoxy resin powder using the thermal spraying apparatus of the present invention? show.

Experimental example (1) Epoxy resin composition used as coating material powder:
Isophoronedia modified with 100 parts by weight of bisphenol A type epoxy resin (manufactured by Yuka Shell Epoxy Co., Ltd., trade name Epicoat 4P1002), isophorone diabane and an epoxy compound (Epicoat +828) made by Yuka Shell Epoxy Co., Ltd. in a ratio of 2=1 16 parts by weight of ξ-n adduct and 2-phenylibadacillin (manufactured by Veba-Chemie,
4 parts by weight of product name B-81) and filler titanium white (manufactured by Sakai Chemical Industry Co., Ltd.).

80 parts by weight of product name R-650), and a flow control agent (
1 part by weight of Modaflow Powder I (trade name, manufactured by Monsanto) was premixed using a Henshil mixer (manufactured by Mitsui Miike Seisakusho). Next, the mixture was melt-mixed and extruded using a co-kneader PR-46 (manufactured by Punu Corporation), and pulverized using a sample mill pulverizer (manufactured by Fuji Baudal Co., Ltd.). This was classified using a rotary tube classifier to obtain epoxy resin powder having a particle size of 250 μm or less. The gelation time of this powder is at a temperature of 15
It took 52 seconds at 0°C.

(2) Thermal spray coating conditions: This epoxy resin powder t.

Thickness Rm preheated to surface temperature 170℃, 300mm
Thermal spray coating was applied to the steel plate of the X70 brain. Propane gas is 0
The pressure was set at 4 atm, the oxygen gas at 06 atm, and the cooling air at L6 atm. The coating film thickness is approximately 0 after one round trip of the thermal spraying device of the present invention.
31B coating is formed on only half of the entire steel plate.

Next, the remaining half of this steel plate was made in the same way as the other half of the coated steel plate with overlapping areas. The above coating film is indicated as (hereinafter Sample No. II Control) when the annular cover is removed from the thermal spraying device 1, and as Sample No. 2 (hereinafter Sample No. 2; present invention) when the annular cover is attached. The following tests were conducted on these two types of coating films.

(31 Test for determining the properties of the coating film formed: (8.1) Acetone rubbing test This is a test to determine the curing state of the coating film formed by the epoxy resin powder coating. A cloth dipped in acetone is used to test the entire coating film. Wipe off several times.

Visually observe the dissolution state of the coating film. When it was not dissolved, it was judged as "○", and when it was dissolved, it was judged as "x".

(8.2) Impact resistance test Epoxy: r↑ This is a test to determine the full strength of the coating film formed by the fat powder paint. For painted steel plates.

Dupont impact tester? Use a striking core diameter of 1/2 inch.

Two tests were conducted under the conditions of a striking load of zxh and a falling distance of 50 cm. impact? Visually observe the condition of the paint film after application, and if there are no changes such as cracks or peeling in the paint film, mark it as [0], and if the paint film cracks or peels due to impact, mark it as "x". I judged it.

(8.8) Smoothing test This is a test to fully understand the smoothness of the coating film. The surface shape of the coating film in the overcoated area was measured using a universal surface shape measuring machine model 5E-8C (manufactured by Koita Research Institute).

The test results are shown in Table 1 and Figures 8 and (bl). In particular, Figure 3 shows that the shape of sample No. 1 changes over a range of about 1 m in the overcoated area. , Sample No. 2 shows a range of approximately 0.06 mm.

In addition to this, epoxy resin thermal spray coating without a post-heating process (
It can be seen that when the thermal spraying apparatus of the present invention is used, a completely cured and smooth coating film can be obtained.

Table 1: 1Nd A semi-illustrated partial cross-sectional side view showing an example of the thermal spraying apparatus of the present invention, FIG. 2 is a perspective view of the apparatus, and FIG. 8 fal
and lbl are charts showing the smoothness of the control coating film and the coating film produced by this apparatus, respectively.

l... Thermal spraying device, 2... Supply means, 3... Thermal spraying nozzle.

4... Support rack, 5... Annular cover, 6... Object to be coated, 7... Formed coating film, ai... Thermal spray flame, 32...
Thermal spray, 8B...overne spray, 5
0...Slit, 51...Exhaust port.

that's all Agent: Patent Attorney Hidetaka Yamamoto

Claims (1)

[Claims] 1(1) Supply means for supplying flame gas, paint powder, cooling air, etc. 121 A thermal spray nozzle connected to the supply means. (Bl) an annular cover attached to the nozzle via a support rack; A thermal spraying device configured such that powder particles that are scattered around the thermal spraying flame while flying and are not sufficiently heated by the thermal spraying flame are deflected in their traveling direction by the annular cover and are scattered along the surface of the cover. 2. The annular cover is hollow and has a slit and an exhaust port, and the exhaust port is connected to a suction means, and the suction means sucks air inside and outside the cover through the slit and the exhaust port. the powder particles into the sleeve)
2. A device as claimed in claim 1, adapted to be captured in the cover via the cover.