KR102593784B1 - A Diffuser for a Pressurized Air and an Apparatus for Measuring the Pressurized Air - Google Patents

Abstract

The present invention relates to a diffuser for compressed air and a compressed air measuring device using the same. The diffuser has an overall cylindrical shape and includes an induction body 11 having an inlet 12 and an outlet 13; A measuring outlet (14) formed on the side of the guiding body (11); A flow guiding body (15) formed inside the guiding body (11) to flow the compressed air flowing into the inlet (12) to the outlet (13); A rotating vortex unit (16) formed on the flow guiding body (15); and a discharge inducing unit 17 connecting the rotating vortex unit 16 and the outlet 13, and a portion of the compressed air passing through the rotating vortex unit 16 is guided to the measurement outlet 14.

Description

Diffuser for compressed air and compressed air measuring device thereby {A Diffuser for a Pressurized Air and an Apparatus for Measuring the Pressurized Air}

The present invention relates to a diffuser for compressed air and a compressed air measuring device using the same. Specifically, a diffuser for compressed air and a compressed air measuring device using the same for measuring the amount of components such as particles, moisture, or oil contained in compressed air. It's about.

Compressed air generated by devices such as compressors or pumps may contain foreign substances such as particles, moisture or oil, depending on the type of application in which compressed air is used, such as food or medical fields. The amount needs to be kept below an appropriate level. The amount of foreign substances or particles contained in compressed air needs to be measured in advance before being supplied, and a high pressure diffuser can be used for this purpose. In a known high-pressure diffuser, a fixed amount of gas passes through a flow control orifice where high-pressure gas is inserted at the top, the gas passing through the orifice flows in a straight direction and is guided to the measuring device, and the remaining air passes through the filter through the side. It has a structure that discharges to the outside. In a known high-pressure diffuser having such a structure, the fine hole in the flow control orifice through which high-pressure gas flows may be clogged or contaminated, making it difficult to accurately measure foreign matter. Additionally, since the gas that has passed through the orifice moves linearly and is guided to the measuring device, it has the disadvantage that flow rate control is difficult and a uniform gas flow is not formed. Patent registration number 10-2103022 discloses a diffuser for measuring air conditioner performance. Additionally, Patent Registration No. 10-2142248 discloses a device for measuring particles in compressed air. However, the prior art does not disclose a diffuser capable of accurately detecting particles or foreign substances by controlling flow rate and pressure.

The present invention is intended to solve the problems of the prior art and has the following purposes.

Prior art 1: Patent registration number 10-2103022 (Filter Solution Co., Ltd., announced on April 21, 2020) Diffuser for measuring air conditioner performance Prior art 2: Patent registration number 10-2142248 (H&G Tech Co., Ltd., announced on August 7, 2020) Compressed air particle measuring device

The purpose of the present invention is to provide a diffuser for compressed air that induces a uniform flow by controlling flow rate and pressure and allows precise measurement of foreign substances, including particles, contained in compressed air, and a compressed air measuring device using the same.

According to a preferred embodiment of the present invention, a diffuser for compressed air includes an induction body having an overall cylindrical shape and having an inlet and an outlet; Measuring outlet formed on the side of the guiding body; a flow guiding body formed inside the guiding body to flow the compressed air introduced into the inlet to the outlet; a rotating vortex unit formed in the flow guiding body; and a discharge guide path connecting the rotating vortex unit and the outlet, and a portion of the compressed air passing through the rotating vortex unit is guided to the measurement outlet.

According to a preferred embodiment of the present invention, the rotating vortex unit includes a cylindrical vortex body having a larger diameter than the outer diameter of the flow inducing body; an extended guide body extending in a cone shape from the vortex body; and a plurality of vortex forming paths extending along the vortex body and the extending guide body.

According to another suitable embodiment of the invention, it further comprises a measuring guide path formed between the inner surface of the guiding body and the outer surface of the flow guiding body.

According to another suitable embodiment of the invention, the compressed air measuring device comprises at least one inlet conduit; pressure regulating means formed in the flow path of at least one inlet conduit; Flow regulating means disposed in the flow path of at least one inlet conduit; A diffuser that diverts some of the compressed air to a measuring means as compressed air with controlled pressure and flow rate flows in; Filtration means for filtering compressed air discharged from the diffuser; and at least one measurement guide pipe that flows the compressed air branched from the diffuser to the measuring means, wherein the diffuser forms a vortex from the flowing compressed air and diverges a portion of the compressed air in the side direction.

According to another suitable embodiment of the invention, the at least one inlet conduit is a small volume inlet conduit having a gas pressure of 0.5 to 30 bar and a gas flow rate of 0 to 50 liters per minute (LPM) and a gas pressure of 0.5 to 30 bar and a gas flow rate of 0 to 50 liters per minute (LPM). It consists of a large capacity inlet conduit of 60 to 1,000 LPM (liter/minute).

The diffuser for compressed air and the compressed air measuring device according to the present invention are particles contained in high-pressure gas generated from a compression device such as a compressor or pump. Enables measurement of oil or moisture. The diffuser according to the present invention allows accurate measurement by precisely controlling the pressure and flow rate of gas in the measuring device. In addition, the diffuser according to the present invention allows setting the flow rate and pressure to suit the measuring device. In the diffuser according to the present invention, high-pressure gas is introduced through an inlet with a relatively large cross-sectional area formed at the top, and a fixed amount of gas is mixed in the mixing chamber by a rotating vortex means. Afterwards, the gas supplied to the measuring device can be stably guided to the side through the rotating vortex unit, and the remaining gas is discharged to the outside through the outlet and filter. The structure of the high-pressure gas inlet, the discharge structure of the rotating vortex unit, the structure of the outlet toward the measuring device, or the external outlet are formed to have a diameter of 1 mm or more to prevent clogging or inflow of foreign matter and improve measurement precision. The diffuser according to the present invention is mixed in a mixing chamber, and the pressure and flow rate of the flowing gas are easily adjusted and the gas is supplied stably by a rotating vortex unit. The measuring device according to the invention can be used, for example, for small volumes of compressed gas with a gas pressure of 0.5 to 30 bar and a gas flow rate of 0 to 50 LPM (liter/minute) or a gas pressure of 0.5 to 30 bar and a gas flow rate of 60 to 1000 LPM (liter/minute). ) is capable of measuring large volumes of compressed gas, but is not limited to this.

Figure 1 shows an embodiment of a diffuser for compressed air according to the present invention.
Figure 2 shows an example of a gas flow structure in a diffuser according to the present invention.
3 and 4 show an embodiment of an induction chamber that guides compressed air to the compressed air measuring device according to the present invention.
5 and 6 show an embodiment of the control structure of the measuring device according to the present invention.

Below, the present invention will be described in detail with reference to the embodiments shown in the attached drawings, but the examples are for a clear understanding of the present invention and the present invention is not limited thereto. In the description below, components having the same reference numerals in different drawings have similar functions, so unless necessary for understanding the invention, the description will not be repeated, and well-known components will be briefly described or omitted, but the present invention It should not be understood as being excluded from the embodiments.

Figure 1 shows an embodiment of a diffuser 10 for compressed air according to the present invention.

Referring to FIG. 1, the diffuser 10 for compressed air includes an induction body 11 that is generally cylindrical and has an inlet 12 and an outlet 13; A measuring outlet (14) formed on the side of the guiding body (11); A flow guiding body (15) formed inside the guiding body (11) to flow the compressed air flowing into the inlet (12) to the outlet (13); A rotating vortex unit (16) formed on the flow guiding body (15); and a discharge inducing unit 17 connecting the rotating vortex unit 16 and the outlet 13, and a portion of the compressed air passing through the rotating vortex unit 16 is guided to the measurement outlet 14.

The guiding body 11 may have an overall cylindrical shape and a flow path may be formed along the longitudinal direction. An inlet 12 is formed at one end of the induction body 11 so that compressed gas can flow in (IN), and an outlet 13 is formed at the other end of the induction body 11 so that compressed gas can be discharged (OUT) ). A measuring outlet 14 may be formed on the side of the guiding body 11, and a portion of the compressed air introduced along the inside of the guiding body 11 may be discharged along the measuring outlet 14 and guided to the measuring means. there is. A flow guiding body 15 may be formed inside the guiding body 11, and the flow guiding body 11 may be connected to the inlet 12 and extend along the longitudinal direction of the guiding body 11. The flow guiding body 11 may be shaped as an overall hollow cylinder to form a gas flow path. A measurement guide path 151 may be formed between the inner circumferential surface of the guide body 11 and the outer circumferential surface of the flow guide body 15. The measurement guide path 151 has the shape of the circumferential surface of the cylinder and may be connected to the measurement outlet 14 to allow air flow. The measurement guide path 151 may be formed along the circumferential surface of the flow guide body 15 and may be formed in a structure extending upward from the measurement outlet 14. A rotating vortex unit 16 may be formed in the lower part of the flow guide body 15, and compressed air guided to the measurement outlet 14 by the rotating vortex unit 16 may be created in the form of a vortex. Referring to the right side of Figure 1, the rotating vortex unit 16 includes a cylindrical vortex body 161 having a larger diameter than the outer diameter of the flow inducing body 15; An extended inducing body 162 extending in a cone shape from the vortex body 161; And it may be composed of a plurality of vortex forming paths 163 extending along the vortex body 161 and the extended inducing body 162. The compressed air flowing in the flow inducing body 15 flows along the through hole formed in the central part of the rotating vortex unit 16 and flows to the cone-shaped discharge inducing unit 17 with a gradually decreasing cross-sectional area to a constant inner diameter. It may flow along an extending flow tube 18. One end of the flow pipe 18 may be connected to the end of the cone-shaped discharge guiding unit 17, and the other end of the flow pipe 18 may be connected to the discharge guiding portion 19 having a cone shape with a gradually increasing cross-sectional area. can be connected And the discharge guiding part 19 has the shape of a hollow cylinder and can be connected to the outlet 13 formed at the lower end of the guiding body 11. By the diffuser 10 having this structure, the compressed air flowing in through the inlet 12 can be moved to a designated place through the outlet 13 and at the same time be guided to the measuring means through the measuring outlet 14 ( M). The diffuser 10 is coupled to various parts of the compressed air flow path and flows a portion of the supplied compressed air to a measuring means, enabling real-time measurement of particles, moisture, or oil components contained in the compressed air.

Figure 2 shows an example of a gas flow structure in a diffuser according to the present invention.

Referring to FIG. 2, the inlet fitting 22 is coupled to the inlet 12 so that the conduit leading the compressed air and the diffuser can be connected to each other to enable air flow. Additionally, the filter module 21 may be coupled to the bottom of the induction body 11 by the connector 24. In addition, a measuring fitting 23 may be coupled to the measuring outlet 14 formed on the side of the guiding body 11, and a measuring induction pipe that guides a portion of the compressed air as a measuring means may be coupled to the measuring fitting 23. Compressed air may be introduced into the interior of the guiding body 11 through the inlet 12 through an inlet pipe connected to the inlet fitting 22. Compressed air flowing into the guiding body 11 may flow along the flow guiding body 15 disposed inside the guiding body 11 and flow toward the outlet 13. In this process, a portion of the compressed air forms a vortex through the rotating vortex unit 16 formed at the end of the flow guiding body 15 and moves along the outer peripheral surface of the flow guiding body 15 to the measurement outlet 14. ) can flow. A measurement guide pipe is connected to the measurement fitting 23 coupled to the measurement outlet 14 so that compressed air can be guided to the measurement means. Compressed air flowing toward the outlet 13 may flow to a place where compressed air is required via the filter module 21 and the flow connector 25 coupled to the bottom of the filter module 21. The filter module 21 may include a pretreatment filter, an activated carbon filter, a heta filter, or various filters similar thereto, but the present invention is not limited thereto.

3 and 4 show an embodiment of an induction chamber that guides compressed air to the compressed air measuring device according to the present invention.

3 and 4, the compressed air measuring device includes at least one inlet conduit (31a, 31b); Pressure regulating means (32a, 32b) formed in the flow path of at least one inlet conduit (31a, 31b); Flow regulating means (33a, 33b) disposed in the flow path of at least one inlet conduit (13a, 31b); Diffusers (10a, 10b) that divert some of the compressed air to the measuring means as compressed air with controlled pressure and flow rate flows in; Filtration means for filtering compressed air discharged from the diffusers (10a, 10b); And at least one measurement guide pipe (314a, 314b) that flows the compressed air branched from the diffusers (10a, 10b) to the measuring means, and the diffusers (10a, 10b) form a vortex from the flowing compressed air to the side. divert some of the compressed air in the direction

The compressed air device may be placed inside the housing (H), and compressed air generating means 41 for generating compressed air may be installed outside the housing (H). Compressed air generated by the compressed air generating means 41 may be guided to the inlet conduits 31a and 31b via the supply conduit 42. The measuring device according to the invention can be applied to the measurement of different volumes of compressed air, for example small-capacity compressed air and large-capacity compressed air. The first inlet conduit (31a) can be applied to measure a small amount of compressed air with a gas pressure of 0.5 to 30 bar and a gas flow rate of 0 to 50 LPM (liter/minute), and the second inlet conduit (31b) has a gas pressure of 0.5. It can be applied to large-capacity compressed air with a pressure of 30 to 30 bar and a gas flow rate of 60 to 1,000 LPM (liter/minute). At least one inlet conduit (31a, 31b) may be composed of a first inlet conduit (31a) for a small capacity input (SIN) and a second inlet conduit (31b) for a large capacity input (LIN), depending on the capacity of compressed air. Accordingly, the inlet conduits 31a and 31b may be appropriately selected. The flow pressure of the compressed air introduced through the inflow conduits (31a, 31b) can be adjusted by the pressure control means (32a, 32b), and pressure gauges (321a, 321b) are connected to the flow control means (32a, 32b). The pressure of the compressed air being regulated can be measured. Compressed air can have its pressure adjusted by the flow control means (32a, 32b) and flow along the flow control pipes (311a, 311b) via the flow control means (33a, 33b) to flow into the diffuser (10a, 10b). there is. The flow control means (33a, 33b) may include a control valve, and may include an electronic control valve whose opening and closing level is determined according to the pressure set by the flow control means (32a, 32b). A portion of the compressed air flowing along the induction control pipes (311a, 311b) and introduced into the diffuser (10a, 10b) flows along the branch induction pipes (313a, 313b) and is measured via the flow meters (34a, 34b). It can flow (SM, LM) along (314a, 314b) and be moved to the measuring means. The remaining portion of the compressed air flows downward of the diffuser (10a, 10b), moves along the filter modules (21a, 21b), and flows along the exhaust supply pipes (312a, 312b) to be supplied to the application site where the compressed air is used. You can. And the contamination level of the compressed air flowing along the measurement guide pipes 314a and 314b can be measured by the measurement means.

5 and 6 show an example of the control structure of the measuring device according to the present invention.

Referring to FIG. 5, the compressed air (IN) introduced through the inlet means 51 flows along the first and second inlet conduits 31a and 31b into the interior of the housing H illustrated in FIGS. 4 and 5. may be introduced. The pressure, flow rate, or flow of the compressed air introduced into the housing (H) can be adjusted by the flow control module 52. The flow control module 52 includes the housing (H) and the control panel 521 described above. It may be composed of, and various adjustment means for controlling the flow of compressed air flowing inside the housing (H) may be disposed on the control panel 521. Compressed air introduced along the inflow means 51 may selectively flow along the first and second inlet conduits (31a, 31b) depending on the amount of compressed air, and the first and second measurement guide pipes (314a, 314b). It may be selectively discharged and moved along the measuring tube 53 to flow into the measuring means 54. The amount of particle components, oil components, or moisture components contained in the compressed air can be measured by the measuring means 54.

Referring to FIG. 6, the control panel 521 includes pressure gauges 61a and 61b for controlling the flow of small and large volumes of compressed air; pressure regulator (62a, 62b); flow control valves (63a, 63b); and flow meters 64a and 64b may be installed, respectively. Each control means may be selected and operated depending on the characteristics of the compressed air flowing along the inside of the housing (H). In this way, the measuring device according to the present invention adjusts the flow appropriately according to the capacity of compressed air to improve measurement precision.

Although the present invention has been described in detail above with reference to the presented embodiments, those skilled in the art will be able to make various variations and modifications without departing from the technical spirit of the present invention by referring to the presented embodiments. . The present invention is not limited by such variations and modifications, but is limited by the claims appended below.

11: induction body 12: inlet
13: outlet 14: measurement outlet
15: flow guiding body 16: rotating vortex unit
18: discharge guide path 31a, 31b: inlet conduit
32a, 32b: pressure control means 33a, 33b: flow rate control means
151: measurement guidance path 161: vortex body
162: Extended induction body 163: Vortex formation path

Claims (5)

An induction body 11 having an overall cylindrical shape and having an inlet 12 and an outlet 13;
A measuring outlet (14) formed on the side of the guiding body (11);
A flow guiding body (15) formed inside the guiding body (11) to flow the compressed air introduced into the inlet (12) to the outlet (13);
A rotating vortex unit (16) formed in the lower part of the flow guiding body (15); and
It is connected to the rotating vortex unit 16 and includes a cone-shaped discharge inducing unit 17 whose cross-sectional area gradually decreases,
The compressed air flowing in the flow inducing body 15 flows along the through hole formed in the central part of the rotating vortex unit 16 and then flows to the cone-shaped discharge inducing unit 17,
A portion of the compressed air flowing into the cone-shaped discharge induction unit 17 is guided to the measurement outlet 14 formed on the side of the induction body 11 by the rotating vortex unit 16, and is guided to the measurement outlet 14. A diffuser for compressed air, characterized in that the compressed air is created in the form of a vortex by a rotating vortex unit (16). The method according to claim 1, wherein the rotating vortex unit 16 includes a cylindrical vortex body 161 having a larger diameter than the outer diameter of the flow inducing body 15; An extended inducing body 162 extending in a cone shape from the vortex body 161; And a diffuser for compressed air consisting of a plurality of vortex forming paths (163) extending along the vortex body (161) and the extended guide body (162). The diffuser according to claim 1, further comprising a measuring guide path (151) formed between the inner surface of the guiding body (11) and the outer surface of the flow guiding body (15). In the compressed air measuring device,
at least one inlet conduit (31a, 31b);
Pressure regulating means (32a, 32b) formed in the flow path of at least one inlet conduit (31a, 31b);
Flow regulating means (33a, 33b) disposed in the flow path of at least one inlet conduit (13a, 31b);
A diffuser that diverts some of the compressed air to a measuring means as compressed air with controlled pressure and flow rate flows in;
Filtration means for filtering compressed air discharged from the diffuser; and
It includes at least one measurement guide pipe (314a, 314b) that flows compressed air branched from the diffuser to the measurement means,
The diffuser includes a rotating vortex unit 16 that forms a vortex from the flowing compressed air and diverges a portion of the compressed air in a lateral direction,
A portion of the compressed air flowing along the through hole formed in the central part of the rotating vortex unit 15 branches to the measurement outlet 14 formed on the side of the guide body 11 of the diffuser, and branches to the measurement outlet 14. Compressed air measuring device, characterized in that compressed air is created in the form of a vortex by a rotating vortex unit (16). The method according to claim 4, wherein at least one inlet conduit (31a, 31b) has a gas pressure of 0.5 to 30 bar and a gas flow rate of 0 to 50 LPM (liter/minute). A compressed air measuring device consisting of a large-capacity inlet conduit (31b) with a gas flow rate of 60 to 1,000 LPM (liter/minute).