KR102599304B1 - Testing system for performance of filter - Google Patents

Abstract

The present invention provides a filter performance evaluation system. One aspect of the filter performance evaluation system according to an embodiment of the present invention includes a test duct in which a flow path in the vertical direction, an inlet, an outlet, and a filter inlet/outlet opening communicating with the flow path are defined; Providing a flow of air such that the air supplied from the outside of the test duct to the inside of the test duct through the inlet flows from upward to downward through the flow path and is then discharged to the outside of the test duct through the outlet. air flow unit; a powder supply unit providing powder supplied into the test duct along with air flowing into the test duct through the inlet by the air flow unit; a filter transfer unit that transfers the filter into and out of the test duct through the filter entry and exit opening; and a filter shielding unit that shields the upper surface of the filter while the filter is drawn out of the test duct through the filter entry/exit opening. Includes.

Description

Filter performance testing system {TESTING SYSTEM FOR PERFORMANCE OF FILTER}

The present invention relates to a filter performance evaluation system.

A filter is used to remove powder, and in particular, an air filter physically removes foreign substances in the air. The performance of a filter can be evaluated by the difference in concentration of powder in the air before and after being filtered by the filter or the ratio of the amount of powder filtered by the filter to the amount of powder introduced.

In particular, when evaluating the performance of a filter based on the amount of powder filtered by the filter, place the filter in a horizontal direction inside the test duct, drop a preset amount of powder from above the filter, and then calculate the initial weight of the filter. And the performance of the filter, that is, the filtration performance, is tested from the weight difference of the filter containing the filtered powder.

However, the filter performance evaluation system according to the prior art has the following problems.

First, when evaluating the performance of a filter as described above, it is important to prevent the powder from falling off the filter during the process of measuring the weight of the filter containing the filtered powder. However, in the process of pulling the filter out of the test duct to measure the weight, there is a risk that the powder may fall off the filter. Various technologies are being proposed to prevent this. However, in the case of the prior art, the structure for preventing the powder from falling out of the filter becomes complicated, or in the case of a simple structure, there is a disadvantage that it is difficult to achieve a practical function of preventing the powder from falling off.

Additionally, conventionally, powder is supplied together with air that is blown into the interior of the test duct by a blowing fan. Therefore, in the past, there was a concern that the flow of air supplied into the test duct by the blowing fan would not be uniform inside the test duct, especially at the entrance of the test duct, which ultimately resulted in the inside of the test duct As the powder does not flow evenly, it becomes difficult to accurately evaluate the filter's performance.

Japanese Patent No. 5438339 (Name: Filter cartridge for measuring powder charge, powder charge meter) Republic of Korea Patent No. 0714958 (Name: Duct system for filter testing for empty space cleaning) Japanese Patent No. 3661905 (name: Device for measuring collection efficiency of air filter media)

The present invention is intended to solve the problems caused by the prior art as described above, and the present invention provides a filter performance evaluation system configured to prevent powder from falling out of the filter with a simpler structure.

Another object of the present invention is to provide a filter performance evaluation system configured to allow powder to flow evenly inside a test duct.

One aspect of the filter performance evaluation system according to an embodiment of the present invention for achieving the above-described object includes: a test duct in which a flow path in the vertical direction, an intake port communicating with the flow path, an outlet port, and a filter entry/exit opening are defined; Providing a flow of air such that the air supplied from the outside of the test duct to the inside of the test duct through the inlet flows from upward to downward through the flow path and is then discharged to the outside of the test duct through the outlet. air flow unit; a powder supply unit providing powder supplied into the test duct along with air flowing into the test duct through the inlet by the air flow unit; a filter transfer unit that transfers the filter into and out of the test duct through the filter entry and exit opening; and a filter shielding unit that shields the upper surface of the filter while the filter is drawn out of the test duct through the filter entry/exit opening. Includes.

In one aspect of the embodiment of the present invention, the filter shielding unit includes: a roller rotatably installed about a horizontal rotation axis and having a shielding sheet wound around its outer circumferential surface; a drive motor that provides driving force for rotation of the roller in a direction in which the shielding sheet is released; a sheet guide that guides the shielding sheet released from the roller; and an attachment portion for attaching the shielding sheet guided by the sheet guide to the upper surface of the filter; Includes.

In one aspect of the embodiment of the present invention, the attachment portion provides heat to the thermosetting adhesive applied to one surface of the shielding sheet.

In one aspect of the embodiment of the present invention, the filter shielding unit further includes a cutting portion that cuts a portion of the shielding sheet attached to the upper surface of the filter from the remainder of the shielding sheet.

In one aspect of the embodiment of the present invention, the filter transfer unit includes: a filter base that enters and exits the inside and outside of the test duct with the filter seated on its upper surface; a filter transport rail along which the filter base entering and exiting the test duct is transported; and a position detection sensor that detects the position of the filter base on the filter transfer rail. It includes, wherein the drive motor is configured to move the shielding sheet to the outside of the test duct calculated from the position of the filter base on the filter transfer rail detected by the position detection sensor. Rotate the roller to release it from the roller.

In one aspect of the embodiment of the present invention, the air flow unit includes: an air discharge duct that communicates with the outlet and through which air discharged to the outside of the test duct flows through the outlet; and an intake fan assembly disposed at the front end of the air discharge duct to suction the air flowing through the flow path to flow through the air discharge duct and be discharged to the outside of the test duct. Includes.

One aspect of the embodiment of the present invention further includes a powder removal unit provided inside the test duct and removing powder in the air discharged to the outside of the test duct through the outlet.

In one aspect of the embodiment of the present invention, the powder supply unit includes a powder storage unit in which powder supplied into the test duct is stored; and a powder supply pipe through which the powder stored in the powder storage unit flows to be sucked into the interior of the test duct through the inlet. It includes, and when air is discharged to the outside of the test duct through the outlet by the air flow unit, the powder stored in the powder storage unit flows through the powder supply pipe and into the inside of the test duct through the inlet port. It is inhaled along with the inhaled air.

In one aspect of the embodiment of the present invention, one end of the powder supply pipe is in communication with the powder storage portion, and the other end of the powder supply pipe is located adjacent to the inlet.

According to the filter performance evaluation system according to an embodiment of the present invention, the following effects can be expected.

First, in an embodiment of the present invention, the upper surface of the filter that is drawn out of the test filter is shielded by a shielding sheet. In particular, in an embodiment of the present invention, the upper surface of the filter can be continuously shielded by a shielding sheet supplied according to the distance at which the filter is drawn out of the test duct. Therefore, according to the embodiment of the present invention, the powder can be prevented from falling out of the filter.

Additionally, in the embodiment of the present invention, the air is discharged to the outside of the test duct, thereby creating a negative pressure inside the test duct, and thereby the powder is supplied together with the air sucked into the test duct. Therefore, in the embodiment of the present invention, more accurate filter performance evaluation is possible due to the even flow of powder inside the test duct.

1 is a configuration diagram showing a filter performance evaluation system according to an embodiment of the present invention.
Figure 2 is a longitudinal cross-sectional view showing an embodiment of the present invention.
Figure 3 is an enlarged perspective view of part A of Figure 2.

Hereinafter, the configuration of the filter performance evaluation system according to an embodiment of the present invention will be described in more detail with reference to the attached drawings.

Figure 1 is a configuration diagram showing a filter performance evaluation system according to an embodiment of the present invention, Figure 2 is a longitudinal cross-sectional view showing an embodiment of the present invention, and Figure 3 is an enlarged perspective view of portion A of Figure 2.

1 to 3, the filter performance evaluation system 1 according to an embodiment of the present invention includes a test duct 100, an air flow unit 200, a powder supply unit 300, and a filter transfer unit 400. ), a filter shielding unit 500, and a powder removal unit 600. In the filter performance evaluation system 1, the performance of the filter F is evaluated from the weight of the filter F including the powder that has been filtered by the filter F and remains on the upper surface of the filter F. .

More specifically, the test duct 100 is substantially tested to evaluate the performance of the filter F inside the test duct 100. For this purpose, a flow path 110, an inlet 120, an outlet 130, and a filter inlet/outlet opening 140 are defined inside the test duct 100.

The flow path 110 is defined to be long in the vertical direction inside the test duct 100. In practice, a test is performed to evaluate the performance of the filter (F) while powder flows along with air through the flow path (110). To this end, the filter F is disposed on the flow path 110 in a direction perpendicular to the direction in which air flows through the flow path 110.

The inlet 120 is a place where powder along with air is sucked into the interior of the test duct 100 through the inlet 120, and the outlet 130 is a place where air flowing through the flow path 110 is sucked into the test duct 100. This is where it is discharged to the outside of the duct 100. And the filter entry/exit opening 140 is where the filter F enters and exits the inside and outside of the test duct 100. Accordingly, the inlet 120, outlet 130, and filter inlet/outlet opening 140 will each communicate with the flow path 110. In this embodiment, the inlet 120 is located at the top of the test duct 100, and the outlet 130 is located at the lower part of the test duct 100, for example, the test duct 100. It can be located at the bottom of the border surface. And the filter inlet/outlet opening 140 may be located at the middle of the edge of the test duct 100 between the inlet 120 and the outlet 130. The filter entry/exit opening 140 may be selectively opened and closed by the door 140D.

Next, the air flow unit 200 provides a flow of air into and out of the test duct 100. More specifically, the air flow unit 200 allows air supplied into the test duct 100 from the outside of the test duct 100 through the inlet 120 to move upward through the flow path 110. After flowing downward, it is discharged to the outside of the test duct 100 through the outlet 130. In particular, in this embodiment, the air flow unit 200 sucks air so that it is discharged to the outside of the test duct 100. To this end, the air flow unit 200 includes an air discharge duct 210 and an intake fan assembly 220.

The air discharge duct 210 is a place where air discharged to the outside of the test duct 100 flows through the outlet 130, and is in communication with the outlet 130. And the intake fan assembly 220 suctions the air flowing through the flow path 110 so that it flows through the air discharge duct 210 and is discharged to the outside of the test duct 100. For this purpose, the intake fan assembly 220 is disposed at the tip of the air discharge duct 210.

The powder supply unit 300 provides powder supplied into the test duct 100. Substantially, the powder provided by the powder supply unit 300 is introduced together with the air flowing into the test duct 100 through the inlet 120 by the air flow unit 200. In this embodiment, the powder supply unit 300 includes a powder storage unit 310 and a powder supply pipe 320.

The powder supplied into the test duct 100 is stored in the powder storage unit 310 . Substantially, the powder storage unit 310 will store powder with a preset particle size according to the filter F, which is a test target for performance evaluation.

The powder supply pipe 320 is a place where the powder stored in the powder storage unit 310 flows to be sucked into the interior of the test duct 100 through the suction port 120. One end of the powder supply pipe 320 communicates with the powder storage unit 310, and the other end of the powder supply pipe 320 is located adjacent to the suction port 120. Therefore, when air is discharged to the outside of the test duct 100 through the outlet 130 by the air flow unit 200, the powder stored in the powder storage unit 310 is transferred to the powder supply pipe 320. flows and is sucked together with the air sucked into the interior of the test duct 100 through the intake port 120.

Next, the filter transfer unit 400 transfers the filter F into and out of the test duct 100 through the filter entrance and exit opening 140. The filter transfer unit 400 includes a filter base 410, a filter transfer rail 420, and a position sensor 430.

The filter base 410 enters and exits the test duct 100 with the filter F seated on its upper surface. The filter base 410 may be formed, for example, in a grid shape so as not to interfere with the flow of air in the passage 110, or may be composed of a pair of bar shapes with a preset width.

And the filter base 410 is transferred into and out of the test duct 100 along the filter transfer rail 420. To this end, the filter transfer rail 420 is disposed long inside and outside the test duct 100 across the filter entry/exit opening 140.

Meanwhile, the position sensor 430 detects the position of the filter base 410 on the filter transfer rail 420. Substantially, the filter base 410 is drawn out of the test duct 100 from the position of the filter base 410 on the filter transfer rail 420 detected by the position sensor 430. The transfer distance is calculated.

The filter shielding unit 500 is provided with the filter ( Shield the upper surface of F). Substantially, the filter shielding unit 500 shields the upper surface of the filter (F) during the process of the filter (F) being drawn out of the test duct 100 through the filter entry/exit opening 140. . In this embodiment, the filter shielding unit 500 includes a roller 510, a drive motor 520, a sheet guide 530, an attachment portion 540, and a cutting portion 550.

More specifically, the roller 510 is installed to be rotatable about a horizontal rotation axis 510A. And a shielding sheet (S) is wound around the outer peripheral surface of the roller 510. The shielding sheet (S) is attached to the upper surface of the filter (F) in order to shield the upper surface of the filter (F). For this purpose, a thermosetting adhesive attached to the upper surface of the filter (F) is applied to one surface of the filter (F).

The drive motor 520 provides driving force for rotation of the roller 510 in the direction in which the shielding sheet (S) is released. In particular, in this embodiment, the drive motor 520 unrolls the shielding sheet S from the roller 510 by the transport distance of the filter base 410 pulled out to the outside of the test duct 100. Rotate the roller 510 so that it moves.

Next, the sheet guide 530 guides the shielding sheet S that is released from the roller 510. Substantially, one end of the sheet guide 530 is located adjacent to the roller 510, and the other end of the sheet guide 530 is located adjacent to the upper surface of the filter (F).

The attachment portion 540 attaches the shielding sheet (S) guided by the sheet guide 530 to the upper surface of the filter (F). In this embodiment, a thermosetting adhesive is applied to one side of the shielding sheet (S) attached to the upper surface of the filter (F), and the attachment portion 540 is a thermosetting adhesive applied to one side of the shielding sheet (S). It can provide heat to the adhesive.

The cutting unit 550 cuts a portion of the shielding sheet (S) attached to the upper surface of the filter (F) from the remainder of the shielding sheet (S). To this end, the cutting portion 550 may be arranged to be spaced apart from the sheet outlet 531A, and for example, a heating wire or the like may be used as the cutting portion 550.

The powder removal unit 600 removes powder in the air discharged to the outside of the test duct 100 through the outlet 130. For this purpose, the powder removal unit 600 is disposed inside the test duct 100 between the outlet 130 and the filter F, that is, on the flow path 110.

Hereinafter, the operation of the filter performance evaluation device according to an embodiment of the present invention will be described in more detail.

First, when the air flow unit 200 operates, air is discharged to the outside of the test duct 100 through the discharge port 130, and as a result, the pressure inside the test duct 100 decreases, so that the intake port 120 ) At the same time, air is sucked into the test duct 100 through the powder supply unit 300, and the powder supplied by the powder supply unit 300 is also sucked into the test duct 100 through the suction port 120.

Next, the air sucked into the test duct 100 through the inlet 120 flows through the flow path 110 and passes through the filter F, and the powder is filtered by the filter F, A test is performed on the filter (F). And the air in which the powder has been filtered while passing through the filter (F) is discharged to the outside of the test duct 100 through the outlet 130 by the continuous operation of the air flow unit 200. At this time, the powder remaining in the air, that is, the remaining powder that has passed through the filter F, is removed by the powder removal unit 600.

Meanwhile, when the test on the filter (F) is completed, the filter (F) is pulled out of the test duct 100 through the filter input and output opening 140. More specifically, the filter base 410 on which the filter (F) is seated on its upper surface is transported along the filter transfer rail 420 and drawn out of the test duct 100. At this time, the position sensor 430 detects the position of the filter base 410 on the filter transfer rail 420.

In particular, in this embodiment, while the filter (F) is drawn out of the test duct 100, the filter shielding unit 500 shields the upper surface of the filter (F). More specifically, when the drive motor 520 rotates the roller 510, the shielding sheet S is released from the roller 510 and is guided by the sheet guide 530. And when the shielding sheet (S) is positioned to completely shield the upper surface of the filter (F), the thermosetting adhesive applied to one side of the shielding sheet (S) is cured by the heat provided by the attachment portion 540, After the shielding sheet (S) is attached to the upper surface of the filter (F), the shielding sheet (S) is cut by the cutting part 550.

In particular, the drive motor 520 moves the roller 510 so that the shielding sheet S is released from the roller 510 by the transport distance of the filter base 410 drawn out of the test duct 100. ) rotate. Therefore, the shielding sheet (S) can be accurately attached to the upper surface of the filter (F).

When the filter (F) is completely pulled out of the test duct 100 through the filter entry/exit opening 140, the cut portion 550 is attached to the upper surface of the filter (F). A portion of is cut from the remainder of the shielding sheet (S). In this way, the weight of the filter (F) is measured with the shielding sheet (S) attached to the upper surface, and from the measured weight, the pre-test weight of the filter (F) and the previously entered shielding sheet (S) are measured. By removing the weight, the weight of the powder filtered by the filter (F) is calculated.

Within the scope of the basic technical idea of the present invention, many other modifications are possible for those skilled in the art, and the scope of the present invention should be interpreted based on the appended claims. will be.

100: test duct 110: euro
120: intake port 130: outlet
140: Filter entry/exit opening 200: Air flow unit
210: air discharge duct 220: intake fan assembly
300: powder supply unit 310: powder storage unit
320: powder supply pipe 400: filter transfer unit
410: Filter base 420: Filter transfer rail
430: Position detection sensor 500: Filter shielding unit
510: Roller 520: Drive motor
530: Sheet guide 540: Attachment
550: Cutting portion 600: Powder removal unit
F: Filter S: Shielding sheet

Claims (8)

A test duct (100) in which a vertical flow path (110), an intake port (120) communicating with the flow path (110), an outlet port (130), and a filter input/output opening (140) are defined;
The air supplied from the outside of the test duct 100 to the inside of the test duct 100 through the intake port 120 flows from upward to downward through the flow path 110 and then flows through the outlet 130. an air flow unit 200 that provides a flow of air to be discharged to the outside of the test duct 100;
A powder supply unit 300 that provides powder supplied into the test duct 100 along with air flowing into the test duct 100 through the inlet 120 by the air flow unit 200. );
a filter transfer unit 400 that transfers the filter F into and out of the test duct 100 through the filter entrance and exit opening 140; and
a filter shielding unit 500 that shields the upper surface of the filter F while the filter F is drawn out of the test duct 100 through the filter input and output opening 140; A filter performance evaluation system including.
According to claim 1,
The filter shielding unit 500,
A roller 510 installed to be rotatable about a horizontal rotation axis 510A and having a shielding sheet S wrapped around its outer circumferential surface;
A drive motor 520 that provides driving force for rotation of the roller 510 in the direction in which the shielding sheet (S) is released;
A sheet guide 530 that guides the shielding sheet (S) released from the roller 510; and
Attachment portion 540 for attaching the shielding sheet (S) guided by the sheet guide 530 to the upper surface of the filter (F); A filter performance evaluation system including.
According to claim 2,
The attachment portion 540 is a filter performance evaluation system that provides heat to the thermosetting adhesive applied to one surface of the shielding sheet (S).
According to claim 2,
The filter shielding unit 500 further includes a cutting portion 550 that cuts a portion of the shielding sheet (S) attached to the upper surface of the filter (F) from the remainder of the shielding sheet (S). system.
According to claim 2,
The filter transfer unit 400,
a filter base 410 that enters and exits the test duct 100 with the filter F seated on its upper surface;
a filter transfer rail 420 along which the filter base 410 entering and exiting the test duct 100 is transported; and
A position sensor 430 that detects the position of the filter base 410 on the filter transfer rail 420; Including,
The driving motor 520 is a motor that is drawn out of the test duct 100 calculated from the position of the filter base 410 on the filter transfer rail 420 detected by the position sensor 430. A filter performance evaluation system that rotates the roller 510 so that the shielding sheet (S) is released from the roller 510 by the transport distance of the filter base 410.
According to claim 1,
The air flow unit 200,
An air discharge duct 210 that communicates with the outlet 130 and through which air discharged to the outside of the test duct 100 flows through the outlet 130; and
An intake fan assembly disposed at the tip of the air discharge duct 210 to suction the air flowing through the flow path 110 so that it flows through the air discharge duct 210 and is discharged to the outside of the test duct 100. (220); A filter performance evaluation system including.
According to claim 6,
The powder supply unit 300,
a powder storage unit 310 in which powder supplied into the test duct 100 is stored; and
a powder supply pipe 320 through which the powder stored in the powder storage unit 310 flows to be sucked into the interior of the test duct 100 through the suction port 120; Including,
When air is discharged to the outside of the test duct 100 through the outlet 130 by the air flow unit 200, the powder stored in the powder storage unit 310 flows through the powder supply pipe 320. A filter performance evaluation system that is sucked together with the air sucked into the test duct 100 through the intake port 120.
According to claim 7,
One end of the powder supply pipe 320 is in communication with the powder storage unit 310,
The other end of the powder supply pipe (320) is a filter performance evaluation system located adjacent to the inlet (120).

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