JPH0410386B2 - - Google Patents

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention can be used in a wide range of applications, such as cooling red-hot steel plates and roller conveyors that convey them, or spraying chemicals on crops in vegetable gardens and orchards. The present invention relates to a flat spray type gas-liquid mixing spray nozzle that has many uses.

[Conventional technology]

In this type of gas-liquid mixing spray nozzle, Fig. 8,
As shown in FIG. 9, a tapered curved inner circumferential surface 01a is formed on the inner bottom of the bottomed cylindrical nozzle body 01 in a concentric or almost concentric state with the nozzle axis P. A slit-shaped orifice 02 is formed on the bottom side of the main body 01 and extends in a direction perpendicular or substantially perpendicular to the nozzle axis P when viewed from the front.

In the case of this conventional nozzle, the liquid mixture flow-guided along the curved inner circumferential surface 01a of the nozzle body 01 collides at the center of the curved inner circumferential surface, so that the liquid mixture flows from the orifice 02 flatly. However, because of this configuration, the amount of flowing liquid per unit time at the center of the orifice 02 is inevitably large, as shown by the broken line b in the graph of Figure 7. However, there is a problem in that the liquid volume distribution is concentrated at the center in the width direction of the spray.

[Problem that the invention seeks to solve]

An object of the present invention is to make the flow distribution uniform by simple and inexpensive modification of the tip of the nozzle body.

[Means for solving problems]

A characteristic configuration of the gas-liquid mixture spray nozzle according to the present invention is that the curved inner circumferential surface is composed of a plurality of stages of curved inner circumferential surface portions whose diameter gradually becomes smaller toward the downstream side in the direction of spraying the mixed gas and liquid. Its functions and effects are as follows.

[Effect]

(b) Considering the flow state of the mixed gas and liquid within the nozzle body, the curved inner circumferential surface located at the outermost side among the plurality of curved inner circumferential surface portions that constitute the curved inner circumferential surface of this nozzle body The liquid mixture flowing along the part collides with the liquid mixture flowing toward the curved inner circumferential surface part one step inside the part, and
Receives a diffusion force diametrically outward relative to the nozzle axis direction. Further, this diffusion component force can also be freely changed to a value according to various conditions by appropriately setting the curvature of the curved inner circumferential surface portion. In other words, the density of the gas/liquid mixture in the longitudinal direction of the orifice can be freely controlled by such a plurality of stages of curved inner circumferential surface portions.

(b) Furthermore, the above object can be achieved by a series of processes on the inner bottom of the nozzle body, instead of separately providing a special gas mixture/liquid density control member.

〔Effect of the invention〕

Therefore, it is possible to make the liquid volume distribution uniform in the width direction of the spray by simply and inexpensively modifying the inner bottom of the nozzle body into a multi-stage curved inner circumferential surface portion as described above. I was able to do it.

〔Example〕

Embodiments of the present invention will be described below based on the drawings.

As shown in FIGS. 1 and 2, a bottomed cylindrical nozzle body 1 constitutes a gas-liquid mixing spray nozzle A used when cooling a cast steel plate by spraying water. A tapered curved inner circumferential surface 2 is formed on the inner bottom of the nozzle body 1 so as to be concentric or substantially concentric with the nozzle axis P, and on the bottom side of the nozzle body 1, the nozzle axis P is formed on the bottom side of the nozzle body 1. A slit-shaped orifice 3 is formed along a direction perpendicular or substantially perpendicular to the slit.

The curved inner circumferential surface 2 is composed of two stages of curved inner circumferential surface portions 2a and 2b whose diameters gradually become smaller toward the downstream side in the direction of spraying the mixed gas and liquid.

On the inner circumferential surface of the nozzle body 1 on the opening side, a female threaded portion 1a for connection to the injection pipe 4 of the gas-liquid mixing device B is formed.

Of the two stages of curved inner peripheral surface portions 2a and 2b that constitute the curved inner peripheral surface 2 of the nozzle body 1,
The liquid mixture flowing along the outermost curved inner circumferential surface portion 2b collides with the liquid mixture flowing toward the curved inner circumferential surface portion 2a located one step further inside, and the nozzle axis It receives a diametrically outward diffusion force with respect to the P direction. Further, this diffusion component force can also be freely changed by appropriately setting the curvature of the curved inner circumferential surface portions 2a, 2b. In other words, such two-stage curved inner peripheral surface portions 2a, 2b
Therefore, the density of the gas/liquid mixture in the longitudinal direction of the orifice 3 can be freely controlled.

Thereby, as shown by the solid line a in the graph of FIG. 7, it is possible to make the liquid volume distribution uniform in the width direction of the spray.

The gas-liquid mixing device B is constructed as follows.

As shown in FIG. 3, a liquid injection nozzle 5 that injects liquid toward the orifice 3 is coaxially fitted into the base of the injection pipe 4 to which the gas-liquid mixing spray nozzle A is screwed. The liquid injection nozzle 5 is screwed and fixed, and the outer peripheral part of the liquid injection flow path 5a of the liquid injection nozzle 5, that is, the part of the injection pipe 4 corresponding to the insertion part of the liquid injection nozzle 5 is formed between these two 4 and 5. A gas-liquid mixing space S ₂ in the injection pipe ₄ is formed in the annular space S 1 in which the gas is injected and supplied.
and the annular space S ₁ , the cross-sectional area of which is smaller than that of the annular space S ₁ , and the gas supplied into the annular space S ₁ is transferred to the liquid injection channel 5a. An annular flow path 7 is formed in an inclined position that allows injection to be guided toward the axial center or substantially toward the axial center on the side of the orifice 3 from the ejection port.

The injection pipe 4 includes a first pipe portion 4a forming the gas-liquid mixing space _S2 , and the liquid injection nozzle 5.
female screw for joining and the gas injection supply port 6
A second pipe portion 4b is formed.

A connecting fitting 9 for a gas supply device 8 such as an air compressor is fixed by welding to the peripheral edge portion of the gas injection supply port 6 of the second pipe portion 4b.

The liquid injection nozzle 5 is formed with a female thread 5b for connection to a liquid supply device 10 such as a pump, and a circumferential groove 5c for forming the annular space _S1 .

Next, another example will be described.

(B) Second Embodiment As shown in FIG. 4, the curved inner circumferential surface 2 of the nozzle body 1 is formed into a three-stage curved inner circumferential surface whose diameter gradually becomes smaller toward the downstream side in the spraying direction of the mixture liquid. It is composed of surface portions 2a, 2b, and 2c.

In addition, as long as the density of the mixed gas and liquid in the longitudinal direction of the orifice 3 can be controlled, the curved inner circumferential surface 2 may be formed from four or more stages of curved inner circumferential surface portions 2a, 2b, 2c... It may be configured and implemented.

(b) Third embodiment As shown in FIG. 5, the nozzle body 1
A tapered spray angle regulating surface 11 is formed in a portion located outward from both longitudinal edges of the orifice 3 to regulate the spray angle of the mixed gas and liquid that is atomized and ejected from the orifice 3 in a flat state. .

(C) Fourth Embodiment As shown in FIG. 6, the nozzle body 1 of the gas-liquid mixture spray nozzle A is connected to the first nozzle portion 1A having the orifice 3 in a flat state. It is composed of a second nozzle part 1B equipped with a spray angle regulating surface 11 that regulates the spray angle of the mixed gas liquid that is atomized and ejected, and
The second nozzle part 1B is configured to be able to be attached to the first nozzle part 1A in a manner that allows the attachment position to be changed freely in the nozzle axis direction.

In the case of this embodiment, since the orifice 3 and the spray angle regulating surface 11 can be formed separately, the orifice 3 or the spray angle regulating surface 11 can be machined on one side as in the third embodiment. There is no restriction on the processing of the spray angle regulating surface 11 or the orifice 3, and both of these 1
There is an advantage that 1 and 3 can be efficiently and easily processed into a desired shape.

Incidentally, the spray angle regulating surface 11 may be constructed and implemented as follows.

(A) Constructed with a curved restriction surface that points inward in the diametrical direction.

(b) Constructed with a curved restricting surface facing outward in the diametrical direction.

(c) Consists of a combination of a curved restriction surface facing outward in the diametrical direction and a curved restriction surface facing inward in the diametrical direction.

(E) Constructed into a stepped regulation surface.

(E) Construct a regulating surface that is parallel or nearly parallel to the nozzle axis p.

(d) Fifth embodiment In the above embodiment, when configuring the gas-liquid mixing device B, the liquid is supplied from the nozzle 5, and
Although the configuration has been described so as to inject and supply gas from the injection supply ports 6, it is also possible to implement the configuration in such a manner that gas is injected from the nozzle 5 and liquid is injected from the injection supply port 6, respectively. good.

[Brief explanation of drawings]

1 to 3 show an embodiment of a gas-liquid mixture spray nozzle according to the present invention, and FIG. 1 is a vertical side view,
FIG. 2 is a front view, and FIG. 3 is a longitudinal side view showing an example of use. Figures 4 to 6 are longitudinal side views showing different embodiments, Figure 7 is a graph showing the spray characteristics of the nozzle, and Figures 8 and 9 are longitudinal side views and front views of conventional nozzles. It is a diagram. DESCRIPTION OF SYMBOLS 1... Bottomed cylindrical nozzle body, 2... Curved inner peripheral surface, 2a, 2b, 2c... Curved inner peripheral surface portion, 3...
...Orifice, P...Nozzle axis.

Claims (1)

[Scope of Claims] 1. A tapered curved inner circumferential surface 2 is formed on the inner bottom of the bottomed cylindrical nozzle body 1 in a concentric or almost concentric state with the nozzle axis P, and the nozzle body 1
A gas-liquid mixing spray nozzle is formed with an orifice 3 extending in a direction perpendicular or almost perpendicular to the nozzle axis P when viewed from the front, on the bottom side of the nozzle. A gas-liquid mixing spray nozzle 2 comprising a plurality of stages of curved inner circumferential surface portions 2a and 2b whose diameter gradually becomes smaller toward the downstream side in the gas-liquid spraying direction. The gas-liquid mixing spray nozzle according to claim 1, wherein the peripheral surface portions 2a and 2b are two-staged. 3. The gas-liquid mixture spray nozzle according to claim 1, wherein the curved inner circumferential surface portions 2a, 2b, and 2c forming the curved inner circumferential surface 2 are arranged in three stages.