KR101047016B1 - Water nozzle of fireproof spray equipment - Google Patents

Abstract

The present invention relates to a refractory spraying facility used when constructing or repairing a refractory material in a blast furnace, ladle, tundish, etc., which is a casting facility of molten steel, and more particularly, water that is attached to a spraying facility and serves to knead refractory material and water. Relates to a nozzle.

The water nozzle of the present invention includes a pipe-shaped nozzle body, a flow path tube inserted into and fixed in the nozzle body and having a plurality of air injection holes formed therein so as to communicate with the water injection holes, and an outer diameter surface of the nozzle body. A water tank cover which is installed in the water passage to form a water passage so as to pass through the water injection hole on the outer circumference of the nozzle body, and an air tank which is installed on the outer diameter surface of the nozzle body to form the air passage so as to pass through the air injection hole on the outer circumference of the nozzle body. It has been provided with a cover.

spray. Refractories, water nozzles, water jets, air jets

Description

Water nozzle for refractories spray equipment

The present invention relates to a refractory spraying facility used when constructing or repairing a refractory material (refractory material) in a blast furnace, ladle, tundish, etc., which is a casting facility of molten steel, and more particularly, is installed in a spray facility to knead refractory material and water. It relates to a water nozzle for doing.

In general, in the spraying of a refractory material, water (liquid) must be added in order for the refractory material to exhibit adhesion and strength, and the water is sprayed to the refractory side through the water nozzle and kneaded with the refractory material.

In addition, the water nozzle in the spray equipment as described above acts as an important factor involved in the adhesion, adhesion state, dust generation amount of the refractory material during construction or repair of the refractory material.

1 and 2 are cross-sectional views showing an example of a water nozzle mounted in a conventional refractory spray equipment, the water nozzle is a nozzle body (1) of approximately pipe shape, and inserted into the nozzle body (1) and a plurality of water A flow path tube 2 having a thread hole 3, a cover 4 provided at an outer circumference of the nozzle body 1 to form a water passage 5 so as to communicate with the water injection hole 3, and the water It consists of the water injection hole 6 etc. which were provided in the cover 4 in order to inject | pour high pressure water into the channel | path 5.

The water injection hole 3 formed in the flow path tube 2 is formed to be inclined at a predetermined angle toward the conveying direction of the refractory material as shown in FIG. 1, and as shown in FIG. It is formed radially toward the surface, and usually about 8 to 16 are arranged at an isometric angle (shown as 8 in Fig. 2).

Therefore, when water is injected at high pressure through the water inlet 6, the injected water is injected into the central portion of the flow path tube 2 through the water passage 5 and the plurality of water injection holes 3, and at this time, the nozzle body 1 The material (refractory material) coming into the nozzle body (1) through the material conveying pipe (7) connected to) is mixed with water and then sprayed toward the object.

The reason why the water injection hole 3 formed in the flow path tube 2 is inclined at a predetermined angle with respect to the conveying direction of the refractory material is to allow the injected water to be kneaded well with the refractory material. The closer the inclination angle is to the horizontal direction, the sprayed water is sprayed in the direction parallel to the conveying direction of the refractory material, so that the water and the refractory material are not kneaded well. On the contrary, the water jetting hole 3 is formed in the vertical direction. If the water is sprayed in a direction that hinders the progress of the refractory material, even when the water and the refractory material is not kneaded well.

Since the conventional water nozzle is a structure in which water is sprayed linearly through a plurality of water spray holes formed in the flow path tube, a non-spraying zone (area not in contact with the water spraying holes) is generated, and the occurrence of such a non-spraying zone Due to this, the kneading property of the refractory material and water is lowered, and the adhesion property of the material is poor, so that a dense construct cannot be formed.

In addition, due to the low kneading property of the water and the refractory material, a lot of dust is generated, making it difficult to secure the visual field of the contractor, resulting in uneven construction, resulting in deterioration of the overall construction quality. There is a problem that the life is shortened.

It is an object of the present invention, unlike conventional water nozzles in which water is sprayed only linearly through a water jetting hole, water sprayed by spraying water and air together with some water jetting holes or all water jetting holes of a plurality of water jetting holes. It is to provide a water nozzle which can improve the kneading property of water and a fireproof material by making this atomization (small water droplets).

The water nozzle of the present invention for achieving the above object is a pipe-shaped nozzle body, a flow path tube is inserted and fixed in the nozzle body and a plurality of air injection holes are formed to communicate with the water injection holes And a water passage cover installed on an outer diameter surface of the nozzle body to form a water passage so as to pass through the water injection hole on the outer circumference of the nozzle body, and an air injection hole installed on the outer diameter surface of the nozzle body and on the outer circumference of the nozzle body. Characterized in that the air passage cover for forming an air passage so as to pass through.

The air jetting holes may be communicated to all the water jetting holes formed in the flow path tube so that water in a small particle state may be sprayed. Small particles of water can be sprayed, and only the water can be sprayed linearly in the remaining water spray holes.

In addition, it is preferable that the air jetting holes communicate with the water jetting holes corresponding to 30 to 70% of the total number of the water jetting holes, and that the water jetting holes communicated with the air jetting holes and the water jetting holes that are not in communication with each other are alternately disposed.

And the angle between the injection direction of the water injected from the water injection hole and the advancing direction of the material is preferably formed to 90 degrees to 150 degrees.

The water nozzle according to the present invention is different from the conventional water nozzle that kneads the water and the material that is transported by linearly spraying only water into the water jetting hole. By simultaneously spraying air, the atomized water particles are sprayed onto the material.

Therefore, the finely divided water particles easily penetrate into the material, and the kneading property of the material and water is greatly improved. As the kneading is performed well, the dust generation is reduced and the workman's vision is easily secured.

In addition, as the kneading property of the material and water is improved, a compact construction body can be obtained, and the adhesion of the material is improved, so that the service life is extended.

3 to 9 is a view showing an embodiment of the present invention, the water nozzle of the refractory spray equipment according to an embodiment of the present invention is a pipe-shaped nozzle body 10, and fixedly inserted into the nozzle body (10) And a plurality of water injection holes 21 and a plurality of air injection holes 22 formed through the water injection holes 21, and fixed to an outer diameter surface of the nozzle body 10. And a water passage cover 30 for forming a water passage 31 on the outer circumference of the nozzle body 10, and an air passage on the outer circumference of the nozzle body 10 and installed on the outer circumferential surface of the nozzle body 10. 41, an air passage cover 40 forming water, a water injection hole 32 for injecting water into the water passage cover 30, and an air injection hole 42 for injecting air into the air passage cover 40; It consists of).

One side of the nozzle body 10 is connected to the material transfer pipe 50, the material is introduced into the nozzle body 10 through the material transfer pipe (50).

The water passage cover 30 and the air passage cover 40 are respectively installed at a portion corresponding to half of the entire circumferential surface of the nozzle body 10, and they are supported through each other as shown in FIGS. 3 and 4. It is arrange | positioned in the state which does not.

Accordingly, the water passage 31 and the air passage 41 formed on the outer diameter surface of the nozzle body 10 form a partitioned area independently, and as shown in FIG. 5, the water passage 31 has a flow path tube 20. The air passage 41 is lost through the water injection hole 21 formed in the air injection hole 22 formed in the flow path tube 20.

The water injection hole 21 formed in the flow path tube 20 is radially formed toward the center from the outer diameter surface of the flow path tube 20, as shown in Figs. 8 and 9, the number is shown in the accompanying drawings Although illustrated as 12, but not limited to this may be formed in the range of 8 to 16.

In addition, the air injection hole 22 formed in the flow path tube 20 is formed such that one side thereof is lost through the air passage 32 formed on the outer diameter surface of the flow path tube 20 and the opposite side is formed through the water injection hole 21. It is.

Therefore, when the high pressure water and air are injected into the water inlet 32 formed in the water passage cover 30 and the air inlet 42 formed in the air passage cover 40, respectively, the water passes through the water passage cover 30 and the nozzle body. At high pressure through the water passage 31 and the water injection hole 21 formed in the flow path tube 20 formed between the (10) and at the same time the air at a high pressure through the air passage 41 and the air injection hole (22) In this case, the water injected into the water injection hole 21 meets the air injected into the air injection hole 22 and is atomized by high-pressure air and then sprayed toward the center of the flow path tube 20.

That is, the water injected into the water injection hole 21 is changed into a small droplet state while meeting the high-pressure air injected into the air injection hole 22 is injected toward the material.

Meanwhile, the air injection holes 22 formed in the flow path pipe 20 may be formed in the same number as the water injection holes 21 so as to communicate with all the water injection holes 21 formed in the flow path pipe 20. Some of the water injection holes 21 of the water injection hole 21 may be selectively communicated with.

As described above, when the air jetting holes 22 are selectively communicated with the water jetting holes 21 of the plurality of water jetting holes 21, some of the water jetting holes 21 are in communication with the air jetting holes 22. In the atomized small particles of water droplets are sprayed, only the high-pressure water is sprayed linearly in the remaining part of the water injection hole 21 that is not in communication with the air injection hole (22).

When the water nozzle of the present invention was installed in a spray facility and tested, even when a water nozzle in which the air injection holes 22 were communicated to all the water injection holes 21 formed in the flow path tube 20 was used, water was compared with the conventional water nozzle. Although the kneading of the material and the material is performed very well, when using a water nozzle in which some of the plurality of water injection holes 21 communicate with the air injection holes 22, further improved kneading effect can be obtained.

At this time, the water injection hole 21 in communication with the air injection hole 22 is preferably formed in a ratio of 30%-70% of the total number of water injection holes, if the ratio is 70% or more of the material and water On the other hand, the contact area is increased, but the kneading property is lowered due to the slowing down of the finely divided water particles, and the kneading property is lowered.

In addition, the water jetting hole 21 which is not in communication with the water jetting hole 21 communicating with the air jetting hole 22 is preferably arranged alternately with each other without being arranged side by side as much as possible.

For example, when 12 air spray holes 21 are formed in total and 6 water spray holes 21 are 50% of them, the air spray holes 22 communicate with each other. It is preferable to arrange every other water jetting hole 21 one by one, and in the case where the air jetting holes 22 are connected to eight or six water jetting holes 21 of the twelve water jetting holes 21, It is preferable to arrange | position appropriately based on the same arrangement.

As such, when the injection holes in which only water is sprayed linearly and the injection holes in which water and air are mixed and atomized water droplets are alternately arranged, kneading of water and materials is more favorable.

In addition, as a result of the experiment, the angle between the injection angle of water (θ in FIG. 8) with respect to the advancing direction of the material is preferably set to 90 degrees to 150 degrees.

If the angle is less than 90 degrees, the water input direction is introduced in the reverse direction of the material traveling direction, and the kneading property of the material and water is lowered. If it exceeds 150 degrees, the sprayed water is difficult to be introduced into the material. It is not preferable because it is lowered.

On the other hand, in the water nozzle according to the invention the pressure of the water injected through the water injection hole 21 and the pressure of the air injected through the air injection hole 22 is preferably set to 2-7Kg / ㎠.

The injection pressure of the water and air is 2Kg / ㎠ If it is less than or equal to the speed of the water to be injected is too slow to be introduced into the material, and if more than 7Kg / ㎠, the speed of the water to be injected is too fast, the material is scattered, as well as kneading property is lowered.

1 is a cross-sectional view showing a water nozzle of the conventional refractory spray equipment

Figure 2 is a longitudinal cross-sectional view of Figure 1 for explaining the water injection hole

3 is a front view of a water nozzle according to an embodiment of the present invention;

4 is a plan view of a water nozzle according to an embodiment of the present invention;

5 is a cross-sectional view taken along the line A-A of FIG.

6 is a cross-sectional view taken along the line B-B of FIG.

7 is a cross-sectional view taken along the line C-C of FIG.

8 is a cross-sectional view of the flow pipe applied to the present invention.

9 is a cross-sectional view taken along the line D-D of FIG. 8 for explaining a flow path.

<Description of the symbols for the main parts of the drawings>

  10: nozzle body 20: flow path tube

  21: water injection hole 22: air injection hole

  30: water passage cover 31: water passage

  40: air passage cover 41: air passage

Claims (6)

delete delete Pipe nozzle body, A plurality of water injection holes inserted into and fixed in the nozzle body and a plurality of water injection holes inserted into and fixed in the nozzle body to communicate with the water injection holes so as to generate atomization (small droplets) A flow path tube in which air injection holes are formed, A water passage cover installed at an outer diameter surface of the nozzle body to form a water passage so as to pass through the water injection hole around the outside of the nozzle body; It is provided on the outer surface of the nozzle body and has an air passage cover for forming an air passage so as to pass through the air injection hole in the outer circumference of the nozzle body, The water nozzle of the refractory spray facility, characterized in that the air injection hole is in communication with the water injection hole of some of the plurality of water injection holes formed in the flow path tube and the air injection hole is not connected to the remaining water injection holes. The method of claim 3, wherein The water nozzle of the refractory spray equipment, characterized in that the air injection hole in communication with the water injection hole corresponding to 30 to 70% of the total number of the water injection hole.  The method according to claim 3 or 4, The water nozzle of the refractory spray facility, characterized in that the water injection hole communicated with the air injection hole and the water injection hole not communicated with each other are arranged so as to alternate with each other. The method of claim 3, wherein The water nozzle of the refractory spray equipment, characterized in that the angle between the injection direction of the water injected from the water injection hole and the traveling direction of the material is 90 degrees to 150 degrees.

Images