KR101827957B1 - Airtightness measuring device - Google Patents

Abstract

According to an aspect of the present invention, an airtightness measuring device includes: a wind pressure fan for producing wind to be introduced into an airtight space; an introduction pipe for allowing wind produced by the wind pressure fan to flow into the airtight space; a flow rate sensor provided in the introduction pipe and sensing an amount of wind flowing into the introduction pipe; a valve provided in the introduction pipe and controlling opening or closing of the introduction pipe; a discharge pipe for discharging the wind introduced into the airtight space to the outside; and an air flow converting device for converting an air flow of the wind such that the wind produced by the wind pressure fan is moved to the introduction pipe and is discharged to the outside through the discharge pipe.

Description

[0001] Airtightness measuring device [

The present invention relates to an airtightness measuring apparatus, and more particularly, to an airtightness measuring apparatus capable of inflow and outflow of wind pressure through a single fan.

A window (window) is a window or door that is installed in an opening of a window or an entrance to block the inside of the building from the outside.

The window is divided into wood window, metal window and resin window window according to the materials used. In recent years, resin windowpanes having a light weight and excellent airtightness have been widely used.

On the other hand, as the wind leaks into or enters the gap where the window is installed, energy loss occurs. If energy loss occurs through the window like this, the building consumes more energy, so it is likely to become an inefficient building in terms of energy.

In order to prevent this, an attempt is made to test the performance of the window in advance and to improve the performance of the window according to the test result.

The performance of the window can be largely divided into heat insulation, airtightness, watertightness, wind resistance and durability.

In particular, there is a need to simplify the measuring device because the devices for measuring such a performance are large and must be accompanied by various devices.

Korean Patent No. 10-0941768 (Feb. 11, 2010)

SUMMARY OF THE INVENTION It is an object of the present invention to provide an airtightness measuring device capable of inflow and outflow of wind pressure through a single fan.

According to another aspect of the present invention, there is provided an airtightness measuring apparatus including a wind pressure fan for generating air to be introduced into an airtight space, an inlet pipe for allowing wind generated from the wind pressure fan to flow into the airtight space, A flow sensor provided in the inflow pipe for sensing an amount of wind flowing in the inflow pipe, a valve disposed in the inflow pipe for controlling the opening and closing of the inflow pipe, a discharge pipe for discharging wind blown into the airtight space, And an air flow converting device for converting the wind flow so that the wind produced by the wind-turbine fan is moved to the inlet pipe or the wind is discharged to the outside through the outlet pipe.

A connection pipe may be connected to the inflow pipe and the discharge pipe to allow the wind to move to the inflow pipe or the discharge pipe according to the air flow converted by the airflow conversion device.

The air flow converting apparatus includes a base plate, an inlet hole formed in the base plate and allowing wind generated from the wind-turbine fan to flow into the inlet pipe through the connecting pipe, A discharge hole through which the moved wind is discharged to the outside through the connection pipe, and a moving device that is coupled with the connection pipe and moves the connection pipe to the upper portion of the inflow hole or the upper portion of the discharge hole.

The moving device includes a coupling plate provided on the base plate and coupled to the coupling tube, a through hole formed in the coupling plate, a pair of brackets provided on both upper surfaces of the base plate in the longitudinal direction, A pair of shafts provided on upper surfaces of both sides in the width direction of the base plate for connecting the pair of brackets, an air cylinder provided on the outer side of the shaft to move the coupling plate by air pressure, And a pair of first moving bodies coupled to the coupling plate and connected to the shaft and moving along the shaft; a pair of second moving bodies coupled to the coupling plate and connected to the shaft and moving along the shaft, .

Wherein the inflow pipe includes a low flow rate pipe through which a low flow rate flows into the airtight space, a heavy oil flow pipe through which a heavy oil amount flows into the airtight space, a high flow rate pipe through which a specific amount flows into the airtight space, And a coupling pipe for integrating both ends of the high-flow pipe.

The flow rate sensor includes a low flow rate sensor provided in the low flow rate pipe to detect a flow rate, a heavy oil amount sensor provided in the heavy oil flow pipe for sensing a flow rate, and a high flow rate sensor provided in the high flow rate pipe for sensing a flow rate .

The valve may include a low flow rate valve for controlling the opening and closing of the low flow rate pipe, a middle flow rate valve for controlling the opening and closing of the middle flow rate pipe, and a high flow rate valve for controlling the opening and closing of the high flow rate pipe.

The discharge pipe may be provided with a discharge pipe valve for controlling the opening and closing of the discharge pipe.

According to the airtightness measuring apparatus of the present invention, airflow can be easily introduced and discharged through a single fan by providing the airflow converter.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a window performance testing apparatus provided with an airtightness measuring apparatus according to an embodiment of the present invention; FIG.
2 is a flow chart of an air flow of an airtight measuring apparatus according to an embodiment of the present invention.
3 is a perspective view illustrating an air flow converting apparatus of an airtight measuring apparatus according to an embodiment of the present invention.
4 is an exploded perspective view of the airflow converter shown in Fig.

Hereinafter, an airtight measuring apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a view showing a window performance test apparatus having an airtightness measuring apparatus according to an embodiment of the present invention, and FIG. 2 is a flow chart of an airtightness measuring apparatus according to an embodiment of the present invention.

1 and 2, an airtightness measuring apparatus 10 according to an embodiment of the present invention includes a window performance testing apparatus 20 in which a test body 30 is mounted so that an airtight space 21 is formed in front of the airtightness measuring apparatus 10, In the device installation space 22 formed at the rear of the vehicle. The window performance testing apparatus 20 may include various measuring apparatuses such as the airtightness measuring apparatus 10 in the apparatus installing space 22 to measure airtightness, watertightness, wind pressure and the like of the test body 30.

The airtightness measuring apparatus 10 can measure the airtightness of the test body 30 and can measure the airtight performance of the airtight fan 11, the inflow pipe 12, the flow rate sensor 14, the valve 15, A discharge pipe 13 and an airflow converter 100 may be provided.

The wind pressure fan 11 produces wind to be introduced into the airtight space 21 formed in front of the window performance tester 20 and may be provided in the appliance installation space 22. [

The inlet pipe 12 may serve to allow the wind generated from the wind-pressure fan 11 to flow into the airtight space 21. Here, the airtightness measuring apparatus 10 can measure the airtightness performance of the test body 30 at different angles by varying the amount of air flowing into the airtight space 21. To this end, the inlet pipe 12 may include a low flow pipe 12a, a heavy oil pipe 12b, and a high flow pipe 12c having different amounts of wind flowing into the airtight space 21. The low flow rate air flows into the airtight space 21 through the low flow rate pipe 12a and the heavy air flow enters the airtight space 21 through the middle flowrate 12b, A high flow rate of air can be introduced into the airtight space 21 through the flow pipe 12c. As described above, since the amount of wind flowing into the airtight space 21 through the inflow pipe 12 can be made different, the airtightness performance of the test body 30 can be measured in various angles. The inlet pipe 12 may be provided with a pair of coupling pipes 17 for integrating both ends of the low flow pipe 12a, the heavy oil pipe 12b and the high flow pipe 12c. The coupling pipe 17 is moved until the wind produced from the wind pressure fan 11 is moved to one of the low flow pipe 12a, the heavy oil pipe 12b or the high flow pipe 12c, It is possible to move the wind moved through any one of the low flow pipe 12a, the heavy oil pipe 12b, and the high flow pipe 12c to the gas tight space 21.

The flow sensor 14 may be provided in the inlet pipe 12 to sense the amount of wind flowing into the inlet pipe 12. [ The flow rate sensor 14 includes a low flow rate sensor 14a provided in the low flow rate pipe 12a for sensing a flow rate flowing into the low flow rate pipe 12a and a low flow rate sensor 14b provided in the middle flow rate pipe 12b, And a high flow rate sensor 14c provided in the high flow rate pipe 12c for sensing a flow rate flowing into the high flow rate pipe 12c. In this manner, by providing the respective flow rate sensors 14 for the different inlet pipes 12, it is possible to easily detect whether the flow rate corresponding to each inlet pipe 12 is moving.

The valve 15 may be provided in the inflow pipe 12 to control the opening and closing of the inflow pipe 12. The valve 15 is provided in the low flow rate pipe 12a and includes a low flow rate valve 15a for controlling the opening and closing of the low flow rate pipe 12a, And a high flow rate valve 15c provided in the high flow rate pipe 12c for controlling the opening and closing of the high flow rate pipe 12c. As described above, by providing the valves 15 for the different inlet pipes 12, it is possible to individually control the opening and closing of the inlet pipes 12, and thus the movement of the wind can be easily controlled.

The discharge pipe 13 may serve to discharge the wind blown into the airtight space 21 to the outside. The discharge pipe 13 is provided with a discharge pipe valve 13a for controlling the opening and closing of the discharge pipe 13 so that the wind is discharged to the discharge pipe 13 while the air is introduced into the airtight space 21 through the inflow pipe 12 Can be prevented.

The airflow conversion apparatus 100 converts the airflow so that the wind produced by the wind fan 11 is moved to the inflow pipe 12 or the wind introduced into the airtight space 21 through the discharge pipe 13 is discharged to the outside Can play a role. The air flow converting apparatus 100 will be described later in detail.

On the other hand, in the inflow pipe 12 and the discharge pipe 13, the wind is moved to the inflow pipe 12 or the wind moved through the discharge pipe 13 according to the airflow converted by the airflow converter 100, The connection pipe 16 can be connected. Here, the inflow pipe 12 is a unit that moves the wind produced from the wind-pressure fan 11 until it is moved to any one of the low flow pipe 12a, the heavy oil pipe 12b, or the high flow pipe 12c The pipe 17 may be connected to the connection pipe 16. [

Next, the airflow converter 100 will be described. In the following description, only different parts from the above-described embodiment will be described in detail and the same or similar parts will not be described in detail.

FIG. 3 is a perspective view showing an air flow converting apparatus of an airtight measuring apparatus according to an embodiment of the present invention, and FIG. 4 is an exploded perspective view of the air flow converting apparatus shown in FIG.

1 to 4, an airtightness measuring apparatus according to an embodiment of the present invention may include an air flow converting apparatus 100. [

The airflow converter 100 may be configured to move the wind produced by the wind-pressure fan 11 to the inlet pipe 12 or to convert the airflow of the wind to discharge the wind through the discharge pipe 13 .

To this end, the airflow converter 100 may include a base plate 110, an inlet hole 120, a discharge hole 130, and a variable device.

The base plate 110 may have a plate shape having a predetermined thickness and may include an inlet hole 120, a discharge hole 130 and a variable device. have.

The inlet hole 120 may be formed to penetrate both sides of the base plate 110 so that the wind generated from the wind fan 11 may be introduced into the inlet pipe 12 through the connection pipe 16 The discharge hole 130 is formed to penetrate both sides of the base plate 110 as in the case of the inlet hole 120. The discharge hole 130 is provided on one side of the inlet hole 120, So that the wind can be discharged through the connection pipe 16.

The moving device 140 may be coupled with the coupling pipe 16 to move the coupling pipe 16 to the upper portion of the inlet hole 120 or the upper portion of the outlet hole 130. [

To this end, the moving device 140 includes a coupling plate 141, a through hole 142, a bracket 143, a shaft 144, an air cylinder 145, a first moving body 146, 147 may be provided.

The coupling plate 141 is formed in a plate shape having a predetermined thickness in the same manner as the base plate 110 and can be coupled to the coupling pipe 16 on the upper portion of the base plate 110. The through holes 142 may be formed to penetrate both surfaces of the coupling plate 141. The through hole 142 is formed to have the same size as the inlet hole 120 and the outlet hole 130 so that the wind moves from the inlet hole 120 to the connection pipe 16 or from the connection pipe 16 So that it can be moved easily when moving to the hole 130.

The brackets 143 may be provided on both upper surfaces of the base plate 110 in the longitudinal direction. A pair of shafts 144, each of which is formed in a pipe shape and long in one direction, may be provided on the upper surface of both sides in the width direction of the base plate 110. The shaft 144 serves to connect the pair of brackets 143 and to guide the moving direction of the first moving body 146 and the second moving body 147. [

The air cylinders 145 may be provided on both sides in the width direction of the base plate 110 so as to be provided on the outer side of the shaft 144. The air cylinders 145 may be provided as a pair so that the coupling plate 141 can be moved by the atmospheric pressure. In order to move the coupling plate 141 by the air cylinder 145, a medium connecting the air cylinder 145 and the coupling plate 141 is required. The first moving body 146 can perform the role of the medium .

The first moving bodies 146 may be coupled to the air cylinder 145 and the coupling plate 141. Thus, the engaging plate 141 can be moved by the air cylinder 145. At the same time, since the first moving body 146 is connected to the shaft 144, it can move along the shaft 144 when the coupling plate 141 is moved by the air cylinder 145. The movement of the first moving body 146 through the shaft 144 can minimize the flow of the coupling plate 141 when moving and improve the structural safety.

The second moving body 147 is connected to the shaft 144 like the first moving body 146 so that the second moving body 147 can move along the shaft 144 when the coupling plate 141 moves by the air cylinder 145. In this case, the second moving body 147 may be engaged with the coupling plate 141 without being coupled with the air cylinder 145, unlike the first moving body 146. The second moving body 147 moves through the shaft 144 like the first moving body 146, thereby minimizing the flow of the coupling plate 141 when moving and at the same time, improving the structural stability.

As described above, the connecting pipe 16 can be easily connected to the inlet hole 120 or the discharge hole 130 through the air flow converting device 100, The operation of moving to the pipe 12 or discharging the wind discharged through the discharge hole 130 out can be facilitated.

Although the airtightness measuring apparatus according to an embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiments disclosed herein. While the present invention has been described in connection with what is presently considered to be practical and exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, will be.

10: Air tightness measuring device 20: Window performance testing device
11: wind pressure fan 12: inlet pipe
13: Exhaust pipe 14: Flow sensor
15: valve 16: connection pipe
17: Coupling tube 100: Air flow converter
110: base plate 120: inlet hole
130: exhaust hole 140: variable device

Claims (8)

An airtightness measuring device provided in a device installation space formed behind a window performance tester on which a test body is mounted so as to form an airtight space in front,
The airtightness measuring device includes a wind pressure fan for producing wind to be introduced into the airtight space,
An inflow pipe for allowing wind generated from the wind-turbine fan to flow into the airtight space;
A flow sensor provided in the inflow pipe for sensing an amount of wind flowing in the inflow pipe,
A valve provided in the inflow pipe for controlling opening and closing of the inflow pipe,
A discharge pipe for discharging the wind introduced into the airtight space to the outside,
And an air flow converting device for converting the wind flow so that the wind produced by the wind-turbine fan is moved to the inlet pipe or the wind is discharged through the outlet pipe,
A connection pipe is connected to the inflow pipe and the discharge pipe to allow the wind to move to the inflow pipe or the discharge pipe according to the air flow converted by the airflow conversion device,
The air flow converting apparatus includes a base plate, an inlet hole formed in the base plate and allowing wind generated from the wind fan to flow into the inlet pipe through the connecting pipe, A discharge hole for allowing the moved wind to be discharged to the outside through the connection pipe and a moving device for causing the connection pipe to move to an upper portion of the inflow hole or an upper portion of the discharge hole in association with the connection pipe Measuring device.
delete delete The method according to claim 1,
The moving device includes an engaging plate provided on the base plate and engaging with the connecting pipe,
A through hole formed in the coupling plate,
A pair of brackets provided on upper surfaces of both sides in the longitudinal direction of the base plate,
A pair of shafts provided on upper surfaces of both sides in the width direction of the base plate for connecting the pair of brackets,
An air cylinder provided on the outer side of the shaft to move the coupling plate by air pressure,
A pair of first moving bodies coupled to the air cylinder and the coupling plate and connected to the shaft and moving along the shaft,
And a pair of second moving bodies coupled to the coupling plate and connected to the shaft and moving along the shaft.
The method according to claim 1,
Wherein the inflow pipe includes a low flow pipe through which a low flow rate flows into the airtight space,
A middle oil-flow pipe into which the heavy oil amount flows into the airtight space,
A high flow rate tube through which a specific amount flows into the airtight space,
And a coupling pipe for integrating both ends of the low flow rate pipe, the heavy oil flow pipe and the high flow rate pipe.
6. The method of claim 5,
Wherein the flow rate sensor comprises a low flow rate sensor provided in the low flow rate tube for sensing a flow rate,
A middle oil level sensor provided in the heavy oil level pipe for sensing a flow rate,
And a high flow rate sensor provided in the high flow rate pipe and sensing a flow rate.
The method according to claim 6,
Wherein the valve comprises a low flow rate valve for controlling the opening and closing of the low flow rate pipe,
A middle oil level valve for controlling the opening and closing of the heavy oil level pipe,
And a high flow rate valve for controlling the opening and closing of the high flow rate pipe.
The method according to claim 1,
Wherein the discharge pipe is provided with a discharge pipe valve for controlling the opening and closing of the discharge pipe.

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