JP4318318B1 - Spray test mist nozzle with cover - Google Patents

Abstract

A nozzle capable of adjusting the amount of spray generated while maintaining the uniformity of spray distribution, easily aligning the center of a liquid nozzle and an air nozzle, preventing clogging of the air nozzle, and realizing a high yield. To provide.
In a spray nozzle used in a spray tester, a metal air nozzle, a hollow air nozzle holder for fixing and holding the air nozzle, a metal liquid nozzle, and the liquid nozzle are fixed. A hollow liquid nozzle holder for holding the nozzle, a nozzle holder for inserting and fixing the air nozzle holder and the liquid nozzle holder, and a nozzle cover for covering the air nozzle and the liquid nozzle. The nozzle cover has a cavity having an opening in the spraying direction of the spray liquid sprayed from the liquid nozzle, and is detachably attached to the nozzle holder.
[Selection] Figure 1

Description

  The present invention relates to a spray nozzle used in a spray tester and a method for manufacturing the same.

  The spray tester is provided with a spray nozzle in a test tank, sends compressed air to the spray nozzle, sucks up and sprays a corrosive liquid such as a 5% aqueous solution of NaCl, and the test piece installed in the tank is this Corrosion is accelerated by receiving spray particles. The spray nozzle is also called an atomizer, and consists of a liquid nozzle that sucks up the corrosive liquid, an air nozzle that supplies air, a nozzle support, etc. Bear.

  Conventionally, a spray nozzle used in a spray tester has a spray tower in which a spray nozzle having a glass liquid nozzle and an air nozzle is incorporated in a cylinder (for example, Non-Patent Document 1 and Patents). Reference 1).

  However, the nozzle described in Patent Document 1 has poor accuracy and lacks uniformity because glass processing is a manual operation. In particular, since the air nozzle is an L-shaped tube, it is extremely difficult to align the center of the liquid nozzle and the air nozzle and adjust the angle. Moreover, it is easy to break because of glass. Therefore, the yield of the nozzle was very poor with an acceptance rate of 50%.

  In addition, it is difficult to adjust the amount of generated spray, and the amount of generated spray cannot be changed after the nozzle is manufactured. To adjust the amount of collected spray, the spray amount adjuster of the spray tower of the spray tester is moved up and down. There is a need. However, if the height of the spray outlet opening in the upper part of the spray tower is raised or lowered, the directionality of the spray flow changes, and the spray distribution cannot be kept constant.

  Moreover, salt water adheres to an air nozzle, and when it dries, a crystal | crystallization will generate | occur | produce, a nozzle will be clogged and cracked. Further, the particle size distribution of the spray particles is as wide as about 10 to 50 μm and is non-uniform.

The applicant has tried various improvements, developed a nozzle in which each of the air nozzle and the liquid nozzle is fixed to a block-type nozzle holder, solved the problems specific to glasswork, and increased the yield. It succeeded in making diameter distribution into a narrow distribution of 5-40 micrometers centering on 10 micrometers (for example, refer patent document 2).
JIS Z 2371 (1955) Japanese Utility Model Publication No. 53-21989 (Fig. 5) Noto 3075448 (FIG. 3, paragraph 0040)

  The nozzle of the spray tester described in Patent Document 2 has a problem that it is difficult to align the center of the liquid nozzle and the air nozzle. Moreover, although the yield was improved, there was a problem that the pass rate remained at 80%. Further, there is a problem that salt water adheres to the air nozzle and is dried to produce crystals and the nozzle is clogged.

  Further, since the spray amount is adjusted only by the vertical movement of the liquid nozzle, there is a problem that adjustment is difficult. Furthermore, there is a problem that the amount of generated spray cannot be changed after the nozzle is manufactured. Therefore, in the spray tester described in Patent Document 2, adjustment of the spray sampling amount needs to be performed by moving the spray amount adjuster of the spray tower of the spray tester up and down. However, when the height of the spray outlet opening in the upper part of the spray tower is raised or lowered, there is a problem that the direction of the spray flow changes and the spray distribution cannot be kept constant.

  An object of the present invention is to solve the above-mentioned problems, and to provide a nozzle that can easily align the center of a liquid nozzle and an air nozzle, can prevent clogging of the air nozzle, and can realize a high yield. It is another object of the present invention to provide a nozzle that can adjust the amount of generated spray while maintaining the uniformity of spray distribution.

A first aspect of the present invention is a spray tester for corrosion resistance test in which liquid is sprayed in the form of a mist such that an extension line on the front end crosses an air nozzle that supplies air and a liquid nozzle that sucks up the liquid. In the spray nozzle installed in the spray tower used for the above, a metal air nozzle, a hollow air nozzle holder for fixing and holding the air nozzle, a metal liquid nozzle, and the liquid nozzle are fixed. A hollow liquid nozzle holder for holding the nozzle, a nozzle holder for inserting and fixing and holding the air nozzle holder and the liquid nozzle holder, a nozzle cover for covering the air nozzle and the liquid nozzle, The nozzle cover has a cylindrical cavity having openings in the spray direction of the spray liquid sprayed from the liquid nozzle and in the direction opposite to the spray direction, and is attached to and detached from the upper portion of the nozzle holder. Fine slidably mounted Ah is, the nozzle holder to provide a nozzle and having a scale for displaying the slide position of the nozzle cover according to the spray generation amount. The liquid nozzle and air nozzle are fixed to the liquid nozzle holder and air nozzle holder, respectively, and this is inserted into the nozzle holder, so that the center alignment of the liquid nozzle and air nozzle is easy and high yield is achieved. it can. In addition, since the nozzle cover that covers the air nozzle and the liquid nozzle is provided, the air nozzle can be prevented from being clogged.

The nozzle cover is slidably attached to the upper part of the nozzle holder, and the nozzle holder has a scale for displaying a slide position with the nozzle cover according to the amount of spray generated, so that even after the nozzle is created. Since the amount of spray generation can be changed by sliding the nozzle cover, it is not necessary to move the spray amount adjuster of the spray tower up and down to adjust the amount of spray generated, and the directionality of the spray flow is changed. There is no fear, and therefore, the amount of generated spray can be adjusted while maintaining the uniformity of the spray distribution.

  According to the nozzle of the present invention, since it is configured as described above, the center alignment of the liquid nozzle and the air nozzle is easy, the clogging of the air nozzle can be prevented, and a high yield can be realized. In addition, the amount of generated spray can be adjusted while maintaining the uniformity of the spray distribution.

  Hereinafter, although the nozzle of this invention is concretely demonstrated using an Example, this invention is not limited to these.

[Example 1]
FIG. 1 is a configuration diagram of a nozzle according to a first embodiment of the present invention. FIG. 2 is a front view of the nozzle according to the first embodiment of the present invention. The nozzle of Example 1 of the present invention is a spray test mist nozzle with a cover for spraying used in a spray tester for spraying a corrosive liquid such as salt water on a test piece arranged in a tank to test the corrosion resistance. A metal air nozzle A2, a hollow air nozzle holder 4 for fixing and holding the air nozzle A2, a metal liquid nozzle A3, and a hollow liquid nozzle holder for fixing and holding the liquid nozzle A3. 5, a nozzle holder A 1 for inserting and fixing and holding the air nozzle holder 4 and the liquid nozzle holder 5, and a nozzle cover 6 for covering the air nozzle A 2 and the liquid nozzle A 3. Has a cavity having an opening in the spraying direction of the spray liquid sprayed from the liquid nozzle A3.

  The liquid nozzle holder 5 has a cylindrical shape, and the hollow portion inside is a liquid flow path, and the lower part is connected to a pipe connected to the corrosive liquid reservoir of the sprayer body to guide the corrosive liquid to the liquid flow path. The liquid nozzle A3 connected to the upper part is ejected. The liquid nozzle A3 is fixed to the upper surface of the liquid nozzle holder 5 at a right angle.

  The air nozzle holder 4 has a cylindrical shape, and the hollow portion inside is an air flow path, and the lower part is connected to a pipe connected to the compressor of the sprayer main body to guide the compressed air to the air flow path. The air nozzle A2 is connected to the air nozzle A2. The air nozzle A2 is fixed to the side surface of the upper portion of the air nozzle holder 4 so as to be perpendicular to the circumferential direction, that is, in the radial direction.

  In this embodiment, first, the air nozzle A2 and the liquid nozzle A3 are manufactured using a titanium thin tube, and the diameter is inspected. Also, the air nozzle holder 4, the liquid nozzle holder 5, the nozzle holder A1, the nozzle cover 6 and the fixing screw A7 are manufactured from acrylic resin. All parts are cleaned before the assembly process.

  The assembly process includes a step of fixing the air nozzle A2 to the air nozzle holder 4, a step of fixing the liquid nozzle A3 to the liquid nozzle holder 5, a step of inserting and fixing the liquid nozzle holder 5 to the nozzle holder A1, and then air. The nozzle holder 4 is inserted into the nozzle holder A1, and the relative position between the air nozzle A2 and the liquid nozzle A3 is adjusted and fixed so as to be a desired spray amount and spray direction.

  In the step of inserting and fixing the liquid nozzle holder 5 into the nozzle holder A1, the liquid nozzle holder 5 is slidably inserted into the nozzle holder A1, the height is determined, and the fixing screw A7 is screwed. It is fixed to the nozzle holder A1 and bonded with an adhesive.

  In the step of inserting the air nozzle holder 4 into the nozzle holder A1 and adjusting and fixing the relationship position between the air nozzle A2 and the liquid nozzle A3 so as to be a desired spray amount and spray direction, first, the air nozzle holder 4 Is slidably inserted into the nozzle holder A1. Next, the height of the air nozzle A2 is adjusted by adjusting the height of the air nozzle holder 4 in the nozzle holder A1. Further, the direction of the air nozzle holder 4 in the nozzle holder A1 is adjusted, that is, the direction of the air nozzle A2 is adjusted by rotating in the circumferential direction. After the adjustment, the fixing screw B8 is screwed and fixed to the nozzle holder A1, and is adhered with an adhesive.

  The air ejection direction is adjusted by adjusting the height and direction of the air nozzle A2. By adjusting the air ejection direction, the relational position between the air nozzle A2 and the liquid nozzle A3 is adjusted.

In a spray tester equipped with a nozzle, the spray amount (ml / min) and the spray collection amount (ml / 80 cm ² / h) at each spray collection point in the tank from the spray tower and the test conditions are matched. It is necessary to adjust the spray direction. In the present embodiment, the adjustment of the spray amount and spray direction is not performed by moving the spray amount adjuster of the spray tower up and down, but the air nozzle holder 4 is inserted into 1 and inserted into the nozzle holder A1 and fixed. In accordance with the position of the liquid nozzle A3 fixed to the liquid nozzle holder 5, the position and orientation of the air nozzle holder 4 so that the relationship position between the air nozzle A2 and the liquid nozzle A3 is a desired spray amount and spray direction. It can be performed by adjusting and then fixing.

  The cavity of the nozzle cover 6 is a cylindrical cavity, and the center of the circle is at a height that becomes the tip of the air nozzle A2. By the air ejected from the air nozzle A2, the corrosive liquid ejected from the liquid nozzle A3 becomes a spray liquid sprayed in a mist form. The cavity of the nozzle cover 6 has an opening in the spray direction of the spray liquid. The spray liquid is rectified in the cavity.

  In the present embodiment, there is an opening in the direction opposite to the spraying direction of the spray liquid, and even when the tip of the air nozzle A2 is removed from the cavity by sliding the nozzle cover 6 in the spraying direction, Rectified in the cavity.

  In the present embodiment, the nozzle cover 6 is slidably connected to the upper portion of the nozzle holder A1, and the nozzle holder A1 has a scale 9 for displaying the slide position with the nozzle cover 6 according to the amount of spray generated. .

  FIG. 3 is a diagram illustrating a sliding state of the nozzle according to the first embodiment of the present invention. The nozzle cover 6 has a corresponding arrow mark, and the spray generation amount can be adjusted depending on which position of the scale 9 the arrow mark is aligned with. The upper part of the nozzle holder A1 has a groove for sliding the nozzle cover 6, and can be slid in the spraying direction.

  The nozzle of this example is used in a spray tester that tests by spraying a test solution with a corrosive liquid such as salt water. The nozzle is installed in the spray tower, sucks the corrosive liquid from the solution reservoir at the lower part of the spray tower, and sprays the corrosive liquid from the upper part of the spray tower to the entire test chamber. Examples of the test piece include metal materials such as automobiles and building materials, plating, coating films, plastics, and the like. Place a spray tower in the center of the test machine, arrange the test pieces in the test piece holder in the tank, spray the corrosive liquid from the spray tower to the entire tank under certain conditions, and once spray the wall in the tank The test is performed in such a way that fine mist falls on the test piece. Since the amount of sprayed liquid that falls on the test piece affects the degree of corrosion, the sprayed liquid is collected by the spray collecting containers provided at various locations in the tank, and the amount of spray collected is measured.

  In the spray test, the test may be performed by changing the amount of spray collected. Even in such a case, with the conventional nozzle, the amount of spray generated from the nozzle cannot be changed, and the spray collection amount is adjusted by moving the spray amount adjuster of the spray tower up and down. In this embodiment, the amount of spray collected from the nozzle can be adjusted by sliding the nozzle cover 6 over the nozzle holder A1.

  FIG. 4 is a configuration diagram of the nozzle of Comparative Example 1. Comparative Example 1 is a conventional glasswork nozzle. An air nozzle B11 and a liquid nozzle B12 are fixed to the nozzle holder B10 by a fixing screw D14 and a fixing screw C13, respectively.

  FIG. 5 is a configuration diagram of the nozzle of Comparative Example 2. Comparative Example 2 is a conventional nozzle in which each of the air nozzle C16 and the liquid nozzle C17 is fixed to a block-type nozzle holder C15. The liquid nozzle C17 is fixed to the nozzle holder C15 by a fixing screw E18.

  Table 1 shows the relationship between the amount of generated spray, the amount of salt water consumed, and the amount of collected spray in Comparative Example 2 and this example. In the table, the column “Conventional nozzle” shows the result in the comparative example 2, and the lower three columns show the result in the nozzle of this example. The row “No cover” is a state in which the nozzle cover 6 is removed from the nozzle holder A1, and the row “1” is the scale position in FIG. 1, that is, the arrow of the nozzle cover 6 is one of the scales 9 of the nozzle holder A1. The state at the leftmost position, the column “2” indicates the state at which the arrow of the nozzle cover 6 is the second position from the left of the scale 9 of the nozzle holder A1.

In Comparative Example 2, the upper opening of the spray tower must be adjusted in order to obtain a spray collection amount of 1.5 ml / 80 cm ² / h. However, since the direction of the spray flow changes as described above, it is very difficult to adjust only the amount of collected spray without changing the spray flow. When the flow of spray changes, the vertical drop of spray, which is the principle, may not be performed.

In this example, in the state of “1” in the table, the amount of spray collected is the most ideal 1 within the range of 1.5 ml / 80 cm ² /h±0.5 determined by the standard or the like. .5ml / 80cm ² / h next, in a state of "cover mounting No" in the table, was a 2.0ml / 80cm ² / h. When it is desired to perform a test with a reduced amount of collected spray, the state of “3”, that is, the nozzle cover 6 is set to the position where the arrow of the nozzle cover 6 is third from the left of the scale 9 of the nozzle holder A1. By making it slide in such a manner, the amount of spray collected can be 1.0 ml / 80 cm ² / h.

  Thus, according to the present Example, it can respond also to the test from which the amount of spray collection differs by mounting | wearing and calibrating a nozzle cover. Further, according to the present embodiment, there is no possibility of changing the directionality of the spray flow, and therefore, the amount of generated spray can be adjusted while maintaining the uniformity of the spray distribution. Further, in the present embodiment, since the scale is provided, the adjustment can be performed very easily.

  In this embodiment, there is no need for glasswork. In addition, since the height and orientation of the air nozzle holder with respect to the liquid nozzle holder can be adjusted during assembly, all the parts can be used as 100% products, and therefore a high yield can be realized.

  In this embodiment, since the nozzle cover that covers the air nozzle and the liquid nozzle is provided, the vicinity of the air nozzle and the tip of the liquid nozzle is in a high humidity state, and even if a corrosive liquid such as salt water adheres to the air nozzle, the air nozzle is dried. Therefore, clogging of the air nozzle caused by the generation of salt crystals at the tip can be prevented. Moreover, since the air nozzle and the liquid nozzle are not made of glass, there is no fear of breaking.

  Since the air nozzle A2 is a straight tube (straight tube) and is attached to the side surface of the air nozzle holder 4 at a right angle, the air nozzle A2 can be finely adjusted up and down and the angle. Therefore, an extremely accurate nozzle can be realized. In this embodiment, both the liquid nozzle holder and the air nozzle holder are inserted into the nozzle holder, and the center positions of the air nozzle A2 and the liquid nozzle A3 can be easily aligned.

  Since the spray liquid is rectified in the cavity, the spraying direction of the spray liquid can be aligned in a certain direction. Further, the spray spread can be corrected to make the nozzle spray distribution constant. Furthermore, the particle size distribution of the spray particles is in the range of 10-50 μm in the conventional one, but the present invention realizes distribution in a narrow range of 5-40 μm including finer particles centering on 10 μm. it can.

  Further, since the nozzle cover 6 covers the tip portions of the air nozzle A2 and the liquid nozzle A3, the tip portions of the air nozzle A2 and the liquid nozzle A3 can be prevented from being damaged and can be protected.

  In this embodiment, parts can be manufactured by cutting with a precision machine, so that the accuracy of parts can be improved and the number of assembly steps can be reduced. Moreover, since the component accuracy is high, the uniformity is increased, and the adjustment of the spray amount and the adjustment of the center alignment of the liquid nozzle and the air nozzle are facilitated.

  In the present embodiment, the air nozzle A2 and the liquid nozzle A3 are made of titanium. However, since the stainless steel and other metals can be selected and changed depending on the corrosion resistance of the solution, the cost can be reduced.

  The present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the invention.

It is a block diagram of the nozzle of Example 1 of this invention. It is a front view of the nozzle of Example 1 of this invention. It is a figure which shows the sliding state of the nozzle of Example 1 of this invention. 3 is a configuration diagram of a nozzle of Comparative Example 1. FIG. 10 is a configuration diagram of a nozzle of Comparative Example 2. FIG.

Explanation of symbols

1 Nozzle holder A
2 Air nozzle A
3 Liquid nozzle A
4 Air nozzle holder 5 Liquid nozzle holder 6 Nozzle cover 7 Fixing screw A
8 Fixing screw B
9 Scale 10 Nozzle holder B
11 Air nozzle B
12 Liquid nozzle B
13 Fixed screw C
14 Fixed screw D
15 Nozzle holder C
16 Air nozzle C
17 Liquid nozzle C
18 Fixed screw E

Claims (1)

Spray installed inside the spray tower used in a spray tester for corrosion resistance testing, in which liquid is sprayed in the form of a mist with the air nozzle that supplies air and the liquid nozzle that sucks up the liquid crossing each other's tip-side extension lines A metal air nozzle, a hollow air nozzle holder for fixing and holding the air nozzle, a metal liquid nozzle, and a hollow liquid nozzle holder for fixing and holding the liquid nozzle; A nozzle holder for inserting and fixing and holding the air nozzle holder and the liquid nozzle holder, and a nozzle cover for covering the air nozzle and the liquid nozzle, wherein the nozzle cover is sprayed from the liquid nozzle. has a cylindrical cavity having an opening in the opposite direction to the spraying direction of the spray liquid of the spray direction that is, removable and slidably attached to the upper portion of the nozzle holder Thea is, a nozzle in which the nozzle holder and having a scale for displaying the slide position of the nozzle cover according to the spray generation amount.