FI98832B - Method and apparatus for spraying a material - Google Patents

Description

98832

Method and apparatus for spraying material

The invention relates to a method for injecting a material, in which method the substance to be injected is introduced into a flame formed by means of a combustion gas and the particles of the material to be injected are injected into the desired object by means of the flame.

The invention further relates to a device for injecting a material, the device comprising means for conducting the combustion gas so that the combustion gas forms a flame and means for conducting the substance to be injected into the flame, whereby the flame is injected into the desired object.

It is known to inject solids into flame-15 spray equipment. In this method, the substance to be sprayed is fed to the flame sprayer as solid particles, which are sprayed into the desired target by a flame sprayer. However, as the particle size decreases, the flame spray equipment easily becomes dirty and clogged. Thus, for example, particles already smaller than 20 micrometers in size. * *: Spraying with flame spraying equipment is cumbersome and M · · * ·., Flame spraying equipment is easily clogged and expensive in structure. The solid to be further sprayed is • · "• · ....

during flame spraying in several different phases being • *; . ·. 25 si steam, partially molten substance and partially molten substance [II.], And when the substance cools, the result is uneven.

* U.S. Patent 3,883,336 discloses an apparatus in which silicon tetrachloride is introduced into a flame syringe as a mist by means of oxygen as a carrier gas. It is further disclosed in this publication that an aerosol is sprayed from the outside into the flame of a flame sprayer to make a glass. The equipment is poor in efficiency and has a low efficiency of ·· ♦ · *. the supply of chloride as steam by means of a carrier gas to the apparatus is slow, because if there is too much silicon tetrachloride relative to the carrier gas, it will be nucleated into larger droplets.

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98832 2 si, and therefore not sufficiently small particles can be sprayed.

The object of the present invention is to provide a method and an apparatus with which particles of the order of 5 nanometers can be produced simply and inexpensively.

The method according to the invention is characterized in that the substance to be injected is introduced into the flame in liquid form and is dripped by means of gas substantially in the vicinity of the flame, so that dripping and flame formation take place in the same device.

The device according to the invention is further characterized in that the device has means for introducing a liquid substance into the flame and means for conducting a gas to the liquid to be sprayed so that the gas sprays the sprayed liquid into droplets substantially in the vicinity of the flame.

The essential idea of the invention is that the substance to be sprayed by the flame sprayer is introduced into the flame of the device in liquid form; in such a way that it is sprayed into droplets. by the sun substantially in the vicinity of the flame. Still. the idea of a preferred embodiment is that the piercing • ......

The reaction takes place using a combustion gas which brings heat to the reaction.

• ·.

The advantage of the invention is that very small particles • · ...........

· * * Can be produced quickly, inexpensively and in one step. A further advantage of the preferred embodiment is that by using the combustion gas which brings the heat of the reaction to the sputtering, the flame-producing burner does not become too large.

The invention is explained in more detail in the accompanying drawing, in which * · * Fig. 1 schematically shows a • ...

Fig. 2 schematically shows a device according to the invention seen from the side and in cross-section, Fig. 3 shows schematically a front view of the nozzle part of the device according to Fig. 2, and Fig. 4 shows schematically a side view and a cross-section of another device according to the invention.

Figure 1 shows an assembly of a flame-10 spraying apparatus according to the invention. The flame syringe 1 forms a flame 8 for injecting the substance to be injected. The necessary gases are introduced into the flame syringe 1 via the gas channels 2, 3 and 4. Flame-forming combustion gases, the spray gas of the liquid to be injected 15 and any gas produced for controlling the reaction are introduced via the gas ducts 2, 3 and 4. The gas passages 2, 3 and 4 are, of course, the required number according to how many gases need to be fed to the flame syringe 1. The substance to be sprayed is fed in liquid form to the flame syringe 1 via the liquid channel 20 5. The liquid to be sprayed is transferred to the liquid channel 5 * *. by pumping it, for example with a syringe pump 6.

··· ·. The movement of the liquid to be injected along the liquid channel 5 ·· ·, ·, can also be realized, for example, by feeding the liquid by pressing ......

I from a reservoir or in some other way known per se.

··· .. ............

25 The flame at the right end of the syringe 1 shown in Fig. 1 is a • · l \ * nozzle 7 in which the combustion gases are ignited to engage the flame and in which the liquid to be injected is dripped by means of a spray gas, whereby the spraying takes place essentially. .... .......

in the vicinity of flame 8. The liquid to be sprayed can ··· ....... .........

, ϊ: 30 can be sprayed on a desired target, for example glass 9. Since the apparatus according to Figure 1 produces ♦ ···, very small, nanometer-sized 'Γ particles, when spraying particles on glass 9, for example, the particles penetrate the glass, changing the structure of the glass ··· 35 so that the color of the glass changes. The glass 9 can be either lettered or colored and is made of, for example, soda glass, semicrystalline glass, crystal glass or borosilicate glass or some other similar material.

Figure 2 shows the flame syringe 1 from the side 5 in a cross-sectional view. The numbering in Figure 2 corresponds to the numbering in Figure 1. The liquid to be sprayed is introduced into the flame syringe 1 via the liquid channel 5. From the liquid channel 5, the liquid passes into the liquid tube 5a in the middle of the flame syringe 1. Along the first gas channel 2, the gas piercing the liquid piers-10 is led to the first gas pipe 2a around the liquid pipe. Along the second gas duct 3, gas is led to a second gas pipe 3a around the first gas pipe 2a. Further, a third gas is led along the third gas duct 4 to the third gas pipe 4a around the second gas pipe 3a. The liquid pipe 5a and the first, second and third gas pipes 2a, 3a and 4a are thus nested pipes. In the nozzle 7, the spray gas coming from the first gas pipe 2a drips into the droplets of the liquid to be injected along the liquid pipe 5a.

For example, hydrogen and, for example, oxygen can be fed along the second gas channel 3 and further along the second gas pipe 3a, for example oxygen, whereby hydrogen and oxygen reacts to form a flame. The Ky-25 walled flame sprays the sprayed liquid into the desired target. The liquid to be sprayed can be any •. · · '· Aqueous or alcoholic solution of the desired ion, for example cobalt nitrate dissolved in alcohol or ··' ί ** water. As the sparging gas, it is preferable to use some exothermic, i.e., a combustion gas which brings heat to the reaction, such as a mixture of oxygen and acetylene or something similar. .. ......-. ·· *. gas. In order to accelerate the combustion reaction, it is advantageous, • · ..... .......

* e that the liquid to be injected is also exothermic, such as an alcoholic solution. To be fed along the first gas pipe 2 ···.

At the same time, a gas used to form a flame, such as hydrogen, can also be used as the spray gas. In this case, oxygen is supplied via the second gas channel 3, whereby hydrogen sprays the liquid to be injected and reacts with oxygen to form the flame of the flame syringe 1, i.e. a separate sparging gas is not required. In such a structure, the third gas channel 4 and the third gas pipe 4a, respectively, are not necessary. However, if desired, they can be used to improve the control of the reaction, for example by feeding a third gas channel 4 and further through a third gas-10 pipe 4a, for example argon, whereby argon prevents the effect of external oxygen on the reaction. It is, of course, clear that when a separate sputtering gas and in addition flame-forming gases such as hydrogen and oxygen are used, a gas can be fed outside the flame to control the reaction 15, for example using a fourth gas duct and a fourth gas pipe around the third gas pipe 3a. It should be noted that in Fig. 2 the structure of the flame syringe 1 is shown for the sake of clarity on a larger scale than the actual situation. In order to achieve effective dripping, it is advisable, for example, to maximize the velocity of the spray gas. Thus, the nozzle 7 ϊ% ·. the holes should be made small enough. Furthermore, the structure of the liquid pipe 5a and the first gas pipe 2a can be described as having two hollow nested needles.

•% ·.

* Figure 3 shows the nozzle 7 seen from the front. The numbering in Figure 3 corresponds to the numbering in Figures 1 and 2. Figure 3 shows the ··· ...... .... coming from the middle of the nozzle 7.

* 30 hole in the end of the liquid pipe 5a. It is surrounded by a ··· hole in the first gas pipe 2a. Repeat the gas pipe 3a ···· - -. * ··. the incoming gas is shown to be led through the nozzle 7 '··· ·. through openings 10. Correspondingly, the third gas pipeline ···· # ...

| 4a, the incoming gas is passed through the nozzle 7 through the openings * ··· '35 11. It is self-evident that the size and geometry of the holes 98832 6 and the openings of the nozzle 7 can vary as desired, but it is essential that the velocity of the liquid and the spray gas in the nozzle 7 be desired so that the liquid to be sprayed is dripped to a sufficient size. small particles and that, on the other hand, the velocity of the flame-forming gases is sufficient.

Figure 4 shows another side view of a flame syringe 1 'according to the invention and in cross-section. The numbering in Figure 4 corresponds to the numbering in Figures 1 to 3. The device according to Figure 4 has several liquid supply channels 5b to 5d. A different liquid can be fed along each liquid channel 5b to 5d. From the liquid channels 5b to 5d, the liquid is passed through the liquid pipes 5e to 5g to the nozzle 15 7. All the liquids to be sprayed are sprayed in the nozzle 7. Separate liquid channels 5b to 5d prevent the liquids to be sprayed from reacting with each other before the flame.

The drawing and the related explanation are only intended to illustrate the idea of the invention. The details of the invention may vary within the scope of the claims. Thus, the particles produced by the method and device according to the invention can, for example, be injected * - *. to many different materials such as metal or collected to achieve the desired effect.

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··· • * • · * · · .......

• «e. · · ·· • · ·· ··· »· · • ...

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* ··· ···, · ··· - - »···· • · ··· ......

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Claims (10)

A method of spraying a material, in which method the material to be sprayed is passed to a position (8) formed by combustion gas, and the spray material particles are sprayed by means (8) of the desired composition, characterized in that the spray material is conducted in liquid form to the position and transmitted in droplet form by means of the gas in the substantial vicinity of the position (8), so that the drop formation and formation of the position (8) takes place in the same device. 10 2. A process according to claim 1, characterized in that combustion gas is used as a gas which forms droplets of the liquid. 3. A method according to claim 2, characterized in that the gas forming the position (8) which provides for the spraying of the material is used as fuel gas which forms droplets of the liquid. Method according to any of the preceding patent claims, characterized in that an exothermic liquid is used as a spray material. * *. 20 5. A process according to any of the preceding claims, characterized in that a gas reducing in. The influence of external factors on the reaction is led outside the ft · · · F • · ........................ . .... '; with the help of the fuel gas formed the position. ··· ···· 6. Method according to any of the preceding claims, may be characterized by the spray material particle particles being sprayed into a glass material. 7. Device for spraying a material, which Γ '*. device has means for conducting combustion gas, such that t *: Y the combustion gas forms a position (8) and means for conducting the spray material to the position (8), whereby the spray material can be sprayed to the desired location by means of the position (8). ), characterized in that the device has means for conducting ·: · *: a liquid material for the position and means for conducting gas to the spray liquid, such that the gas sprays the spray liquid ··· ..... - 35. drops in the essential proximity of the position (8), wherein the drop formation takes place in the same device as the formation of the position (8). Device according to claim 7, characterized in that the device has at least one liquid channel (5, 5b - 5d) for conveying the spray liquid to the device and in addition there is at least one liquid pipe (5a, 5e - 5g) for conduction of liquid to the position and the device has a gas duct (2) for conduction of the gas which sprays the liquid into a gas pipe (2a) around the liquid pipe (5a, 5e - 5g) and that the liquid pipe (5a, 5e - 5g) and the gas pipe (2a) ) is arranged so that the gas from the gas pipe (2a) splashes the liquid coming from the liquid pipe (5a, 5e - 5g) into droplets. Device according to claim 7 or 8, characterized in that the device has means for conducting a protective gas around the position formed by the fuel gas. Device according to any one of claims 7-9, characterized in that the device has at least two liquid channels (5, 5b - 5d) for injecting spray liquid into the device. • · · · ·· • ·. ··· • · · .... • · ...... • · • .... ....... • • e .... · ... ....... ... • · ........ ... .... .... ..... ···· ....... .. '· · ··· .. . • · · ···. · ..... ··· ··· ..... • · · ·· .... ... * · # · * · * · • · · · '··. .......... ...... ... • .... • .... ..... · »· ......... ···· ··· ...... ............... · .- ... • *. # · ......... ... ..........- ··· ...... ............ »... .. .... · · ···· ....... .... · · ...... ··· ... • · ........ ·· · ..........