KR100354502B1 - Venturi injector - Google Patents

Abstract

The present invention relates to a venturi injector having a tubular injector body having both ends open to form an inlet and an outlet of a fluid, and having an axis diameter formed between the inlet and the outlet with a narrower diameter than the inlet and the outlet. A working fluid supply unit formed through the side of the injector body corresponding to the shaft diameter area to supply a predetermined working fluid into the injector body; And a locking jaw formed in the shaft diameter area adjacent to the working fluid supply part such that the flow of fluid introduced through the inlet is varied to a position spaced apart from the working fluid supply part. This not only allows the working fluid to be more strongly introduced into the injector body through the working fluid supply unit, but also introduces the working fluid into the injector body through the working fluid supply unit even if the pressure (water pressure) pushing from the inlet to the outlet is not relatively high. A Venturi injector is provided to make this work.

Description

Venturi injector

The present invention relates to a venturi injector. A venturi injector is an apparatus for mixing different fluids while passing one fluid in the form of a reduction-enlarging nozzle. For example, when the ozone generated by the ozone generator (hereinafter referred to as "working fluid") is to be mixed with tap water (hereinafter referred to as "fluid"), a venturi injector is used. As shown in the figure, the tubular injector body 110 and the working fluid supply unit 120 is formed through the side of the injector body 110 to supply a predetermined working fluid into the injector body 110. The inlet 112 and the outlet 113 of the fluid is formed at both ends of the main body 110, and the shaft diameter portion 114 is formed between the inlet 112 and the outlet (113). One end of the working fluid supply unit 120 communicates with the outside of the injector body 110, and the other end thereof communicates with the inside of the shaft diameter part 114. At this time, the sections 114a to 114b that form the shaft portion 114 are formed relatively long. As a result, when the fluid flows into the injector body 110 through the inlet 112, the flow velocity is changed by the diameter difference. It is faster while passing through the shaft diameter portion 114. In this way, when the flow velocity of the fluid increases, the fluid with the higher velocity flows in the state of maintaining the same speed as the increased velocity as it passes through the section where the diameter increases, and at this time, a low pressure toward the vacuum state is achieved and Low pressures, such as vacuums, need to be filled in some way. Thus, the working fluid supply part 120 is formed in this area so that the working fluid flows into the injector body 110. However, in the conventional venturi injector, the fluid flowing along the inner wall of the shaft diameter part 114 is still Since the direction of flow velocity is not determined, it has the property of spreading to the outside of the tube. Therefore, the shaft diameter portion 114 which guides the fluid in a straight line toward the outlet port 113 is necessary to determine the direction of the flow velocity, and the length of the shaft diameter portion 114 must also be relatively long. Since the venturi injector has a relatively long length of the shaft diameter portion 114 (the length from reference numerals 114a to 114b), the fluid flowing through the inlet 112 passes through the shaft diameter portion 114, and its flow rate and hydraulic pressure are increased. As a result, the force to introduce the working fluid supply unit 120 into the injector body 110 decreases as the hydraulic pressure and the flow rate decrease. In addition, when the pressure (water pressure) of the fluid pushed from the inlet 112 is not relatively high, the force for introducing the working fluid into the injector body 110 is almost lost.

Accordingly, an object of the present invention is to not only allow the working fluid to flow more strongly into the injector body through the working fluid supply unit, but also to inject the main body through the working fluid supply unit even if the pressure (water pressure) pushing from the inlet side toward the outlet port is not relatively high. It is to provide a Venturi injector that allows the flow of working fluid into the well.

1 is a cross-sectional view of the venturi injector according to the present invention;

2 is a cross-sectional view of a conventional Venturi injector.

The object is, according to the present invention, both ends are open to form an inlet and outlet of the fluid, and provided with a tubular injector body having a shaft diameter formed between the inlet and the outlet having a narrower diameter than the inlet and outlet A venturi injector, comprising: a working fluid supply unit formed through a side of the injector body corresponding to the shaft diameter area to supply a predetermined working fluid into the injector body; It is achieved by a venturi injector, characterized in that it comprises a locking jaw formed in the shaft diameter area adjacent to the working fluid supply portion so that the flow of fluid introduced through the inlet is varied to a position spaced apart from the working fluid supply. Here, the locking step is preferably formed at a right angle to the front of the working fluid supply toward the inlet. Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is a venturi according to the present invention. Sectional view of the injector. As shown in this figure, the venturi injector according to the present invention, like the conventional injector, is formed through the tubular injector body 10 and the side of the injector body 10 to have a predetermined work in the injector body 10. And a working fluid supply part 20 for supplying a fluid. The working fluid supply part 20 has an end portion 20a of which is in communication with the outside of the injector body 10, and the other end 20b of the shaft diameter part 14 to be described later. The inlet 12 and the outlet 13 of the fluid are formed at both ends of the injector body 10, and the inlet 12 and the outlet 13 are between the inlet 12 and the outlet (13). The shaft diameter part 14 which has a narrower diameter is provided. The shaft diameter portion 14 is provided in such a form that the weaving is increased toward the outlet 13 again after the diameter is gradually reduced from the inlet 12, in the section of the conventional shaft diameter portion (reference numeral 114 of FIG. 2). It is formed narrower than the shaft. The shaft diameter portion 14 is formed with a locking projection 16 protruding toward the inside of the injector body (10). The locking jaw 16 is formed at a right angle to the front of the working fluid supply unit 20 toward the inlet 12. The locking jaw 16 is a position where the flow of fluid introduced through the inlet 12 is spaced apart from the other end 20b of the working fluid supply unit 20 in the shaft diameter portion 14 region (the center of the injector body 10). That is, the flow of the fluid flowing along the inclined surface 10a in the injector body 10 through the inlet 12 is changed by the latching jaw 16 that is vertical to inject the body 10. It flows along the central region of. Then, in the region adjacent to the other end 20b of the working fluid supply unit 20, the flow of the fluid does not occur and is almost in a vacuum state. Not only does it need to be lengthened, but even if the other end 20b of the working fluid supply part 20 into which the working fluid flows in the immediate vicinity of the locking step 16 is provided, the working fluid supply part 20 is due to the role of the locking step 16. Since the fluid does not spread to the outside of the pipe having the other end 20b of the working fluid, the working fluid may be easily introduced into the injector body 10 through the other end 20b of the working fluid supply unit 20. At this time, the position of the other end (20b) of the working fluid supply unit 20 is placed in the vicinity of the shaft diameter portion 14, but the fluid hits the locking jaw (16) in a curved portion where it is very close to the locking jaw (16) The inside of the injector body 10 is configured to become wider in diameter as soon as it passes the other end 20b of the working fluid supply unit 20 located in the shaft diameter portion 14 near the locking jaw 20. . Therefore, the injector of the present invention does not need to have a long section (the length from reference numerals 114a to 114b of FIG. 2) as in the conventional injector. In addition, the section of the shaft diameter portion 14 is short, so that the diameter is gradually widened without decreasing the flow velocity generated at the front end of the shaft diameter portion 14, at which time the other end (20b) of the working fluid supply unit 20 A low pressure state such as a vacuum state is formed in the shaft diameter portion 14, and this allows the working fluid to be easily introduced (intake). In addition, the injector according to the present invention is, for example, from the inlet 12 side For example, even if a pressure of less than 0.5 kgf / cm 2 is applied, the working fluid may be easily introduced into the injector body 10 through the working fluid supply unit 20. As described above, in the present invention, the injector By providing the locking jaw 16 in the shaft diameter portion 14 region of the main body 10, the working fluid can be easily introduced into the injector body 10 through the working fluid supplying part 20. In addition, it is possible to easily introduce the working fluid into the injector body 10 without maintaining the section of the shaft diameter compared to the prior art.

As described above, according to the present invention, not only the working fluid can be more strongly introduced into the injector body through the working fluid supply unit, but also through the working fluid supply unit even if the pressure (water pressure) pushing from the inlet to the outlet is not relatively high. A venturi injector is provided which allows for a good flow of working fluid into the injector body.

Claims (2)

In the venturi injector having a tubular injector body having both ends are opened to form the inlet and outlet of the fluid, the shaft diameter portion formed between the inlet and the outlet having a narrower diameter than the inlet and outlet, A working fluid supply unit formed through the side of the injector body corresponding to the shaft diameter area to supply a predetermined working fluid into the injector body; And a locking jaw formed in the shaft diameter area adjacent to the working fluid supply part such that the flow of the fluid introduced through the inlet is varied to a position spaced apart from the working fluid supply part. The method of claim 1, The catching jaw is venturi injector, characterized in that formed at a right angle to the front of the working fluid supply toward the inlet.