KR20110115446A - Pressure control system for door leakage performance testing apparatus - Google Patents

Abstract

The present invention relates to a pressure control system for a window performance test apparatus for testing the airtight performance of curtain walls, windows and doors.
The present invention is provided with a blower, an airflow converting body, and an adjusting unit to operate in a constant pressure mode for supplying air to the airtight space, or to switch to a negative pressure mode for discharging air from the airtight space to form a negative pressure. Through the pressure control system and the window performance tester equipped with this, the test specimens such as curtain walls, doors and windows can be mounted in the airtight box, and static pressure and negative pressure can be easily applied to the internal airtight space. By switching the internal flow path through the diaphragm rotation of the adjuster, the pressure inside the hermetic box can be adjusted within a short time at a positive and negative pressure of up to ± 5000pa.

Description

PRESSURE CONTROL SYSTEM FOR DOOR LEAKAGE PERFORMANCE TESTING APPARATUS

The present invention relates to a pressure control system for a window performance test apparatus for testing the airtight performance of curtain walls, windows and doors, and more specifically, it is easy to pressurize and vacuum the airtight box through an airflow converter with a single high pressure blower. Pressure control for window performance tester that can generate pressure, fine control of pressure can be obtained by finely adjusting the rotation angle of the airflow converter, and can quickly change the pressure inside the airtight box by positive pressure and negative pressure in a short time. It is about the system.

In general, energy waste is increased when heating or cooling a house or building depending on the amount of wind leaking from or entering doors or windows. To prevent this, the airtight performance of curtain walls, doors and windows is tested in advance. According to the results, it is necessary to develop technology to improve the confidentiality performance.

Conventionally, a door test apparatus for testing the airtight performance, order performance, and explosion proof performance of a door has been developed. For example, there is a "heavy door test apparatus" described in Patent No. 10-0886344, such a conventional heavy door test apparatus is formed in the form of a box, the five sides are sealed, the door frame is formed on the other side The door frame may be equipped with a heavy weight to be tested, reinforced by a reinforcement beam structure installed around the gas inlet for injecting gas for gastight test into the door frame, and measuring the pressure of the injected gas. A first mounting hole to which a gas pressure measuring device can be connected is formed, and a second mounting hole to which a hydraulic pressure measuring device that can measure water pressure is connected.

And the upper panel is equipped with a flange pipe for connecting the connection pipe for the hydraulic test, the explosion gas injection hole and the viewing window formed on one side wall.

Such a conventional door tightness test apparatus is provided with a high-pressure fan accommodated in the interior of the device mounting space of the main body portion, by connecting the outlet tube of the high-pressure fan to the air inlet of the airtight space to press the airtight space to 10 to 500Pa It is provided with a pressurizing part.

It is also provided with a differential pressure sensor mounted on the rear wall of the hermetic space to detect the differential pressure of the hermetic space to output the pressure value to the differential pressure display window of the instrument panel provided in the body portion, the flow sensor mounted on the outlet pipe of the high pressure fan Detects air flow through and outputs the flow rate in the flow rate display on the instrument panel.

And the conventional door tightness test apparatus is provided with a volume-type blowing pressure control switch for adjusting the air flow rate of the high pressure fan, and has a flow rate microvalve for fine control of the flow rate supplied to the outlet pipe of the high pressure fan It is to test the airtight performance of the door or window mounted in the airtight space, including a controller for controlling the air volume and the differential pressure in the airtight space.

However, such a conventional door airtight test apparatus can easily work to apply a static pressure to the interior of the airtight box equipped with curtain walls, doors, windows and doors, on the contrary, a technology for applying a negative pressure There was a problem that can not be provided.

In addition, since the conventional technology had only a function of giving air at a constant pressure, there was a problem in that not only a sudden change in air pressure, such as a typhoon drove, but also a test of watertight performance such as water penetration was impossible.

The present invention is to solve the above-mentioned conventional problems, the object of which is to give a positive pressure and a negative pressure easily to the inside of the airtight box equipped with a test body such as curtain wall, door, window and In addition, the present invention provides a pressure control system for a window performance test apparatus that makes it easy to control the pressure, and allows the pressure inside the airtight box to be adjusted in a short time with positive and negative pressure.

Another object of the present invention is to freely fix various kinds of test specimens of different sizes through one airtight box, and to easily apply static pressure and negative pressure to the inside of the airtight box, and perform various performance tests. The present invention provides a pressure control system for a window performance test apparatus.

In order to achieve the above object, the present invention, a blower for introducing air through the inlet, exhaust air through the outlet; A first port connected to the outlet of the blower through a first pipe, a second port configured to allow inflow and outflow of outside air, and a third port connected to the inlet of the blower through a third pipe An airflow converting body having a fourth port connected to an external hermetic space through a fourth pipe; And a diaphragm rotatably mounted in the airflow conversion body, wherein the diaphragm is rotated to connect a first port and a fourth port, a second port and a third port, or a first port and a first diaphragm. A control unit which connects two ports and switches an internal flow path to connect the third port and the fourth port, and introduces air into the blower from the outside through the second port and the third port; It operates in a constant pressure mode to supply air to the airtight space through the fourth port, or inflows air from the airtight space through the fourth port and the third port to the blower, and air to the outside through the first port and the second port. It provides a pressure control system that is switched to the negative pressure mode to form a gas tight space to the negative pressure by discharging.

And the present invention is preferably the airtight space is an inner space of the airtight test box for testing the test body airtight performance of curtain walls, windows, doors, etc., the diaphragm of the adjustment portion has a width corresponding to the inner diameter of the airflow conversion body And a pressure control system rotated inside the airflow conversion body to change an internal flow path of the airflow conversion body.

In addition, the present invention preferably the pressure control system to form a pressure of ± 5000pa in the inside of the airtight space through the blower, and a predetermined amount of water through the water supply unit while varying the pressure in the airtight space at intervals of 2 seconds Provides a window performance tester for airtight and watertight tests.

According to the present invention, through the pressure control system including the blower, the airflow converting body, and the adjusting unit, the positive pressure and the negative pressure can be easily generated in the airtight box in which test objects such as curtain walls, doors, and windows are mounted. It is possible to apply, and by switching the internal flow path through the diaphragm rotation of the adjustment section, an excellent effect of controlling the pressure inside the hermetic box at a maximum speed of up to ± 5000 pa in a short time at an instant is obtained.

In addition, according to the present invention, as well as the airtight test for the test body, by freely supplying the water to the airtight space through the water supply system, similar to the situation in the typhoon drove the airtight test and watertight test at the same time accurately and easily performance test An excellent effect that can be variously performed can be obtained.

1 is a configuration diagram showing a pressure control system according to the present invention.
2A is an operation explanatory diagram showing a state in which the pressure control system according to the present invention operates in the constant pressure mode.
2B is an operation explanatory diagram showing a state in which the pressure control system according to the present invention operates in the negative pressure mode.
Figure 3 is a side sectional view showing a window performance test apparatus to which the pressure control system according to the present invention is applied.
Figure 4a is a front view showing a cylinder arrangement structure of the clamp unit in the window performance test apparatus according to the present invention.
4B is an operation explanatory diagram showing the test piece fixing operation of the pneumatic cylinder provided in the window performance test apparatus according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

The pressure control system 100 according to the present invention has a blower 110, as shown in FIG. 1, which blows air in through the inlet 112 and the outlet 114. Through the air is to discharge in one direction.

The blower 110 is connected to the air flow conversion body 120, the air flow conversion body 120 is made of a hollow structure having an air flow path therein, the outlet 114 of the blower 110 It has a first port 122 connected to the first pipe 122a.

In addition, the airflow conversion body 120 has a second port 124 through which the inflow and outflow of outside air is made on the other side, and is connected to the inlet 112 of the blower 110 through a third pipe 126a. Three ports 126 are provided.

In addition, a fourth port 128 connected to the external hermetic space 130 through the fourth tube 128a is provided on the outside, such an external hermetic space 130 may include, for example, curtain walls, windows, doors, and the like. The inner space of the hermetic test box for testing the hermetic performance of the test body (S).

In addition, the pressure control system 100 according to the present invention includes an adjusting unit 140 having a diaphragm 142 rotatably mounted in the air flow converting body 120.

The diaphragm 142 of the adjusting unit 140 has a width corresponding to the inner diameter of the airflow conversion body 120, and is provided through an adjustment dial (not shown) located outside the airflow conversion body 120. It rotates to change the internal flow path of the airflow conversion body 120.

Therefore, when the external operator rotates the diaphragm 142 through a separate operation dial, the diaphragm 140 may be formed of the first port 122 and the first port 122 of the airflow conversion body 120. The constant pressure mode P1 connecting the four ports 128 and connecting the second port 124 and the third port 126, or the first port 122 and the second port 124 The internal flow path is switched to the negative pressure mode P2 connecting the third port 126 and the fourth port 128.

The pressure control system 100 according to the present invention configured as described above converts airflow into an external hermetic space 130 such as an inner space of an hermetic test box for testing hermetic performance of a test body S such as curtain walls, windows, doors, and doors. The fourth port 128 of the body 120 is connected through the fourth pipe 128a.

In this state, the operator rotates the diaphragm 142 of the adjusting unit 140 through a separate operation dial (not shown), through which the constant pressure mode P1 as shown in FIG. 2A. And the negative pressure mode P2 as shown in FIG. 2B.

That is, in the positive pressure mode P1 as shown in FIG. 2A, the diaphragm 142 of the adjusting unit 140 is rotated inside the airflow conversion body 120 to connect the first port 122 and the fourth port 128. The second port 124 and the third port 126 are connected to each other.

When the blower 110 is operated in such a state, air is drawn from the third port 126 connected to the inlet 112 of the blower 110 through the third pipe 126a and the third port 126. ) Is connected to the second port 124 through the internal flow path of the airflow conversion body 120, and draws outside air through the second port 124 to supply to the blower 110.

The blower 110 supplies such air to the first port 122 of the airflow conversion body 120 through the first pipe 122a and to the fourth port 128 through the internal flow path. Supply air to the airtight space 130 of the airtight test box through the tube (128a). Therefore, the pressure control system 100 according to the present invention can supply air to the airtight space 130 of the airtight test box at a positive pressure of up to + 5000pa.

In this case, the static pressure in the hermetic space 130 is detected through the differential pressure sensor 152 mounted in the hermetic test box, and the flow rate of the supplied air is determined by the flow sensor 162 mounted in the fourth pipe 128a. By detecting the pressure difference and the flow rate display window (164a, 164b) of the instrument panel 172 and outputs the pressure value and the flow rate, respectively, when the set differential pressure and flow rate is reached, the blower 110 is stopped by the controller 170. .

In addition, the pressure control system 100 according to the present invention may operate in the negative pressure mode P2 as shown in FIG. 2B. In such a negative pressure mode P2, the diaphragm 142 of the adjusting unit 140 is airflow. The inside of the conversion body 120 rotates to connect the first port 122 and the second port 124, and connects the third port 126 and the fourth port 128.

When the blower 110 is operated in such a state, air is drawn from the third port 126 connected to the inlet 112 of the blower 110 through the third pipe 126a and the third port 126. ) Is connected to the fourth port 128 through the internal flow path of the airflow conversion body 120, and thus draws air from the airtight space 130 of the airtight test box through the fourth pipe 128a to the blower 110. Will be supplied.

And the blower 110 supplies such air to the 1st port 122 of the airflow conversion body 120 through the 1st pipe 122a, and supplies it to the 2nd port 124 through an internal flow path, and is airtight. The airtight space 130 of the test box is discharged to the outside.

Therefore, the pressure control system 100 according to the present invention can maintain the inside of the airtight space 130 of the airtight test box at a negative pressure of up to −5000 pa.

Even in this case, the negative pressure in the hermetic space 130 is detected through the differential pressure sensor 152 mounted in the hermetic test box, the flow rate of the discharged air is detected through the flow sensor 162, instrument panel 172 The differential pressure and flow rate display windows 164a and 164b output the pressure values and the flow rate values, respectively, and when the set differential pressure and the flow rate are reached, the operation of the blower 110 is stopped by the controller 170.

As described above, the pressure control system 100 according to the present invention has an airtight body in which a test body S such as a curtain wall, a door, a window or the like is mounted by rotating the diaphragm 142 of the adjusting unit 140 inside the airflow conversion body 120. It is possible to easily change the constant pressure and the negative pressure inside the box easily and quickly in a short time, and obtain an excellent effect of selectively and conveniently performing the positive pressure test and the negative pressure test.

Reference numeral 180 is a support frame for mounting the test body (S), 182 is a sealing material 182 mounted on its edge.

The pressure control system 100 of the present invention as described above can be used in the window performance testing apparatus 200 as shown in FIG.

Window performance test apparatus 200 according to the present invention has a hollow box-shaped structure of a rectangular box, the inside is formed with an open airtight space 130, the rear of the airtight space 130, the device mounting space 212 ) Is provided with a main body 210.

That is, the main body 210 has a hermetic space 130 is formed on the front, such a hermetic space 130 is formed on the front of the main body 210, as shown in Figure 4a, the main body ( A plurality of pneumatic cylinders 232 are respectively spaced at the edges along the rear wall 220 of the hermetic space 130, that is, the wall 220 partitioning the hermetic space 130 and the device mounting space 212. It is provided with a clamp unit 230 disposed.

As shown in FIG. 4B, the clamp unit 230 includes a test body in which a rotatable fixing lever 236 is connected to the rod 234 of the pneumatic cylinder 232 and is disposed on the front surface of the hermetic space 130. (S) is fixed by being in close contact with the support frame 182.

That is, such a fixed lever 236 is formed in the shape of "￢", the test body support frame 180 and the test body (S) of the front surface disposed on the front surface of the wall 220, the wall 220 In close contact with the front surface of the test body support frame 180 to form an airtight space 130.

The test body support frame 180 has a rectangular door-shaped structure, and as shown in FIG. 4B, the sealing member 182 made of a rubber material is attached to the front and rear surfaces of the wall 220, respectively, When pressed to the front surface, the back seal 182 is pressed between the wall 220, and at the same time the front seal 182 is pressed between the test body (S) and the airtight space inside the test body support frame 180 Maintain 130 in a stable sealed state.

The differential pressure is supplied to the hermetic space 130 of the main body portion 210 through the pressure control system 100. The pressure control system 100 as described above in relation to FIG. A blower 110 for supplying air to the space is provided.

In addition, the pressure control system 100 includes a first port 122 connected to the outlet 114 of the blower 110 through a first pipe 122a, and a second port through which inflow and outflow of external air is made. And a third port 126 connected to the inlet 112 of the blower 110 through a third pipe 126a, and externally sealed through a fourth pipe 128a to the outside. An airflow conversion body 120 having a fourth port 128 connected to the space 130 is provided.

In addition, such a pressure control system 100 is a diaphragm 142 of the adjusting unit 140 rotatably mounted in the air flow conversion body 120, and an adjustment dial (not shown) for rotating the diaphragm 142. ) To the outside to connect the first port 122 and the fourth port 128 of the airflow conversion body 120, the second port 124 and the third port 126 as shown in Figure 2a Connection can be made in the same constant pressure mode (P1).

In addition, in the negative pressure mode P2 as illustrated in FIG. 2B, the first port 122 and the second port 124 of the airflow conversion body 120 are connected, and the third port 126 and the fourth port are connected. The internal flow path can be switched to connect the port 128.

Therefore, the pressure control system 100 introduces air into the blower 110 from the outside through the second port 124 and the third port 126 of the blower 110 and the airflow conversion body 120, and The air is supplied at a constant pressure to the hermetic space 130 through the first port 122 and the fourth port 128, or from the hermetic space 130 through the fourth port 128 and the third port 126. The air may be introduced into the blower 110, and the air may be discharged to the outside through the first port 122 and the second port 124 to form the airtight space 130 under negative pressure.

In addition, the window performance test apparatus 200 according to the present invention can test the watertight test by supplying water to the hermetic space (130).

In other words, the present invention can be similarly simulated and conducted variously the airtight performance test and watertight test for the test body (S) such as curtain walls, windows, doors, similar to the situation that the typhoon is driven, In order to include a water supply unit 270 having a pump 274 connected to the hermetic space 130 through a water supply pipe 272.

The water supply unit 270 includes a quantity sensor 276 connected to the water supply pipe 272 to detect the quantity of water supplied to the hermetic space, and control the pump 274 through the controller 170 in advance. A fixed amount of water is supplied according to a predetermined pattern.

In addition, the water supply unit 270 is connected to the nozzle hole 278 formed in the wall 220 of the end of the water supply pipe 272 may supply water to the inside of the airtight space 130, the water supply pipe 272 A plurality of nozzle holes 278 are formed to spray a predetermined amount of water onto the test body S while varying the pressure in the hermetic space 130 at a period of 2 seconds to perform a hermetic and watertight test.

That is, the watertight test is to change the pressure up to ± 5000pa in the airtight space 130 through the pressure control system 100 in a period of 2 seconds, that is, to apply the pneumatic pressure to the pressure as shown in Table 1 below to remove the air pressure In this way, a certain amount of water is sprayed under pulsating pressure.

Pulsating pressure

Classification (Unit: Pa)       10       15      25       35      50    median      100      150     250      350     500    Upper limit      150      225     375      525     750    Lower limit       50       75     125      175     250    Cycle (S)                                 2

When the watertight test is performed in this way, the test body S, such as a window, is exposed to the typhoon, and the external force is applied and removed by the wind pressure, so that the airtight performance and the watertightness performance can be more accurately tested. It is.

As described above, according to the present invention, the positive pressure and the negative pressure can be easily applied to the inside of the airtight box equipped with the test body S such as curtain walls, doors and windows through the pressure control system 100. By switching the internal flow path through the rotation of the diaphragm 142 embedded in the airflow converting body 120 of the pressure control system 100, the pressure inside the hermetic box can be changed to a positive pressure and a negative pressure of up to ± 5000pa within a short time. It can be adjusted and performance tests can be conducted.

In addition, the present invention, as well as the airtight test for the test body (S), it is possible to freely supply water to the airtight space 130 through the water supply unit 270, the airtight test and watertight test similar to the situation where the typhoon is driven Simultaneous simulation can be easily performed in various performance tests, and thus more accurate performance tests can be made.

An embodiment of the present invention described above and illustrated in the drawings should not be construed as limiting the technical spirit of the present invention. The protection scope of the present invention is limited only by the matters described in the claims, and those skilled in the art can change and change the technical idea of the present invention in various forms. Accordingly, such improvements and modifications are within the scope of the present invention as long as they are obvious to those skilled in the art.

100 ...... Pressure control system 110 ...... Blower
112 ...... Entrance 114 ...... Exit
120 ...... airflow conversion body 122 ...... the first port
122a ..... Tube 1 124 ...... Port 2
126 ...... Port 3 126a ..... Tube 3
128 ...... 4th port 128a ...... 4th tube
130 ...... Confidential Space
140 ...... adjuster 142 ...... diaphragm
152 ..... Differential pressure sensor 162 ...... Flow sensor
164a, 164b ..... Differential pressure and flow rate display 170 ...... Controller
172 ...... Instrument panel 180 ...... Support frame
182 ...... Sealing material 200 ...... Windows performance tester
210 ...... Main unit 212 ...... Device mounting space
220 ...... rear wall 230 ...... clamp part
232 ...... pneumatic cylinder 234 ...... rod
236 ...... fixed lever 242 ...... medium pneumatic cylinder
P1 ....... Constant pressure mode P2 ...... Negative pressure mode
S ....... Test body

Claims (3)

A blower for introducing air through the inlet and exhausting the air through the outlet;
A first port connected to the outlet of the blower through a first pipe, a second port configured to allow inflow and outflow of outside air, and a third port connected to the inlet of the blower through a third pipe An airflow converting body having a fourth port connected to an external hermetic space through a fourth pipe; And
A diaphragm rotatably mounted in the airflow conversion body, the diaphragm being rotated to connect a first port and a fourth port, a second port and a third port, or a first port and a second port A control unit which connects a port and switches an internal flow path so as to connect a third port and a fourth port; air is introduced into the blower from the outside through the second port and the third port, and the first port and the second port. It operates in a constant pressure mode for supplying air to the airtight space through the four ports, or inflows air from the airtight space to the blower through the fourth and third ports, and supplies air to the outside through the first and second ports. A pressure control system for a window performance testing apparatus, characterized in that the switching to the negative pressure mode to discharge the airtight space to form a negative pressure. According to claim 1, wherein the airtight space is an inner space of the airtight test box for testing the airtight performance of the test body, such as curtain walls, windows, doors, etc., the diaphragm of the adjusting portion has a width corresponding to the inner diameter of the air flow conversion body. And rotating the inside of the airflow converting body to change the internal flow path of the airflow converting body. According to claim 2, wherein the airtight space is the interior space of the airtight test box for testing the airtight performance of the curtain wall, window and door, the pressure control system to create a pressure of ± 5000pa in the airtight space through the blower The pressure control system for the window performance test apparatus, characterized in that for performing the airtightness and watertightness test by spraying a predetermined amount of water to the test body through the water supply unit while varying the pressure in the airtight space at intervals of 2 seconds.

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