KR101635627B1 - Ventilation equipment of composite corrosion test chamber - Google Patents

Abstract

The present invention relates to ventilation equipment of a composite corrosion test chamber, which is used to ventilate air in a chamber in a process to perform a corrosion test, and discharges air to the outside of the chamber. According to the present invention, the ventilation equipment is installed in a discharge line discharging air of the chamber, and comprises: a nozzle cylindrical component (10); an air inflow container (30); and an air discharge container (20). Moreover, one or more ventilation equipment is installed in a discharge line (161) along a length of the discharge line (161).

Description

[0001] The present invention relates to a ventilation equipment of a composite corrosion test chamber,

The present invention relates to a composite corrosion test chamber for performing corrosion test on automobile parts and building materials, and more particularly, to a test chamber for automobile parts, building materials, etc. using chambers such as calcium chloride and sodium chloride And it is used to ventilate the air inside the chambers containing these substances during the corrosion test. Even if it is used for a long time, it does not corrode due to the air containing these corrosive substances and works smoothly. To a ventilation system for a composite corrosion test chamber which can be discharged.

When snow falls in the winter and snow accumulates on the road, a large amount of calcium chloride is sprinkled on the road to dissolve the snow. In this case, it is buried in the vehicle in which calcium chloride is run, and the vehicle parts are corroded over time. And the houses and vehicles near the beach contain the salty water contained in the sea and fly in the air, so they also corrode the building materials and the vehicles over time.

As such, since automobile parts and building materials are corroded by calcium chloride and sodium chloride, they are manufactured so as to prevent corrosion at the time of manufacturing these parts, and legally required corrosion resistance.

Therefore, these components and building materials should be subjected to corrosion resistance performance test for sample parts at the research and development stage.

The corrosion resistance test is performed by placing a sample of a component under test in a chamber capable of realizing a harsh environment such as temperature, humidity, and other environmental conditions in which actual parts are used. Inside the chamber, you can create a more harsh environment and find out if the part can withstand the actual environment for a certain period of time in a short period of time.

FIG. 1 is a view showing the structure of the composite corrosion test chamber and the brine flow system, and FIG. 2 is a view showing the precision of the complex corrosion test chamber.

As shown, the chamber 100 is capable of spraying saline water therein, in which clean filtered water is stored in the water tank 110, and a portion of the water therein is discharged to the operation of the pump 111 The water flows into the salt water tank 120, and the water is stirred with the salt in the salt water tank 120 to provide brine. The brine is stirred into the brine tank 120 by injecting compressed air through an air injection line 185 to produce brine. The brine in the brine tank 120 is dispensed through the brine supply line 121 at the manifold 130 and through the various brine nozzles 140 in the chamber 100. The brine supply line 121 is provided with an on-off valve 122 to control the supply of salt water. The compressed air supplied from the main air injection line 180 is saturated with water in a saturator 181 and then supplied to the open / close valve (not shown) 182 to the brine nozzle 140. The brine nozzle 140 injects the compressed air to spray the brine. The pressure of the compressed air to be injected appears in the pressure gauge 113.

After the salt water is sprayed from the brine nozzle 140, the water in the water tank 110 is sent to the water spray nozzle 150 through the water supply line 112 in order to remove the salt on the nozzle, The brine nozzle 140 is washed.

Meanwhile, purified air is supplied to the chamber 100 to regulate humidity, and the air inside the chamber 100 must be exhausted. The air is supplied through the air supply line 160 and discharged through the discharge line 161.

Such ventilation of the air is performed by a ventilation device such as a blower. In the past, ventilation was performed by using a fan made of aluminum or stainless steel. However, since the inside of the chamber and the air to be discharged have a large amount of salt, there is a problem that the blower is easily corroded and becomes inoperable when it is used for a long period of time.

In addition, the conventional fan made of synthetic resin has a problem in durability due to deformation during high temperature operation. In order to solve such a problem, a fan made of titanium is also used. However, there is a problem that it is difficult to process the fan and the cost is high because of the nature of the material. It is also difficult to prevent the corrosion of the shaft portion connecting the fan and the motor.

Also, since the discharge air contains salt, the discharge line 161 has a very long length since it must be completely discharged to the outside. Therefore, in order to smoothly discharge the air to the outside and ventilate the inside of the chamber 100, the blower must have a large capacity with a strong force. Therefore, an expensive blower should be used.

The present invention has been conceived to solve the problems of the prior art as described above, and it is an object of the present invention to provide a ventilation system, And to provide a ventilation system of a complex corrosion test chamber which can reduce the installation cost of the chamber by allowing the gas to be discharged to a far distance with a simple structure.

According to another aspect of the present invention, there is provided a ventilation apparatus for a chamber for venting air from a chamber, the ventilation apparatus comprising a first through-hole through which exhaust air flows in the center, A second through hole having a diameter larger than that of the first through hole and communicating with the first through hole; an air inflow portion formed in an annular shape on the outside; an air inlet portion inclined in the air flow direction around the front portion of the second through hole, A nozzle cylinder having a plurality of air nozzles formed to communicate with the inlet portion and the second through-hole; A hollow for receiving the nozzle cylinder is formed and a hose connecting groove communicating with the air inlet of the nozzle cylindrical body is formed and communicated with the first through hole of the nozzle cylindrical body and having a diameter larger than that of the first through hole An air inflow passage in which a discharge air inflow hole and a discharge hole are formed in which an inflow side discharge line is coupled; And an air discharge cylinder coupled to an outlet side of the nozzle cylinder and having a discharge air discharge hole having the same inner diameter as the second through hole of the nozzle cylinder and a coupling hole for coupling the discharge discharge line, And one or more ventilation devices can be installed on the discharge line according to the length of the discharge line.

The ventilation device of the composite corrosion test chamber of the present invention is also characterized in that the nozzle cylinder, the air inflow tube and the air discharge tube are formed of a material which does not corrode salt.

The ventilation system of the composite corrosion test chamber of the present invention is characterized in that an O-ring is inserted between the nozzle cylinder and the air inflow cylinder, and the air discharge cylinder is coupled with the air inflow through the screw connection.

The air venting device of the composite corrosion test chamber of the present invention is also characterized in that a screw fastening mechanism is inserted into the outer surface of the air discharge tube so as to firmly fasten the air discharge tube, And an instrument groove is formed.

The ventilation system of the complex corrosion test chamber of the present invention does not discharge air by mechanical action using electricity but exhausts air from the chamber by using compressed air so that precise parts or parts to be operated are not required, And even if the discharged air contains salt, it can be used for a long period of time without causing a breakdown due to corrosion, and even if the length of the discharge line is long, So that the air containing the salt can be easily discharged to the outside of the building.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing a structure of a composite corrosion test chamber to which a ventilation system of the present invention is applied and a brine flow system;
2 is a front view of a composite corrosion test chamber to which the venting device of the present invention is applied,
3 is a sectional view of the ventilation system of the composite corrosion test chamber of the present invention,
FIG. 4A is a cross-sectional view of the nozzle cylinder, which is a component of the ventilation system of the composite corrosion test chamber of the present invention, and FIG. 4B is a front view of the nozzle cylinder of FIG. 4A.

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

As shown in FIG. 1, the ventilation device 170 of the composite corrosion test chamber of the present invention is installed on a discharge line 161 for discharging the air of the chamber 100 to the outside. Since the air containing the salt is preferably discharged to the outside of the building, the length of the discharge line 161 may be considerably long. In this case, a plurality of ventilation apparatuses 170 of the present invention are installed at appropriate intervals.

As shown in FIG. 3, the ventilator 170 of the present invention includes a nozzle cylinder 10, an air discharge cylinder 20, and an air inlet cylinder 30. As a material of these parts, it is preferable to use a material which does not corrode due to the salt contained in the discharged air, that is, a synthetic resin.

The nozzle cylinder 10 has a first through hole 13 through which exhaust air flows in the center and a second through hole 13 communicating with the first through hole 13 and having a larger diameter than the first through hole 13, The air inlet portion 11 is inclined in the direction of air flow around the front portion of the second through hole 14. The air inlet portion 11 is formed with a hole 14, And a plurality of air nozzles 12 communicating with the second through holes 14 are formed. As shown in FIGS. 4A and 4B, the nozzle cylinder 12 has an air nozzle 12 having a small inner diameter in the circumferential direction of the end portion of the second through hole 13 at the side of the first through hole 13 A large number of which are formed at regular intervals.

The air inlet tube 30 is formed with a hollow into which the nozzle cylinder 10 is inserted and a hose connecting groove 31 communicating with the air inlet 11 of the nozzle cylinder 10 is formed, A discharge air inflow hole 33 having a diameter larger than that of the first through hole 13 and communicating with the first through hole 13 of the nozzle cylinder 10, Holes 32 are formed. A hose for supplying compressed air is connected to the hose connecting groove 31.

The air discharge tube 20 is coupled to the outlet side of the nozzle cylinder 10 and includes an exhaust air outlet hole 21 having the same inner diameter as the second through hole 14 of the nozzle cylinder 10, And an engagement hole 22 to which the outflow-side discharge line 161 is coupled is formed.

3, the discharge air inflow hole 33, the second through hole 14, and the discharge air outlet hole 21 have the same diameter, and the diameter of the first through hole 13 is larger than the diameter The diameter of each of them is smaller than the diameter of each of them. The inner diameter of the discharge line 161 coupled to the discharge air inflow hole 33 and the discharge line 161 coupled to the discharge air discharge hole 21 are also connected to the discharge air inflow hole 33, 21).

3, the coupling structure of the air inflow cylinder 30, the discharge line 161, the air discharge cylinder 20 and the discharge line 161 is such that the discharge line 161 is connected to the air inlet cylinder 30 Is inserted into the coupling hole (22) of the coupling hole (32) and the air discharge cylinder (20).

O rings 15 and 16 are inserted between the nozzle cylinder 10 and the air inflow cylinder 30 to maintain airtightness. The air discharging cylinder 20 is coupled to the air inflow cylinder 30 by screwing and is connected to the air discharging cylinder 20 Is formed with an engaging mechanism groove 23 that allows the air discharging cylinder 20 to be rotated while being inserted.

The ventilation system of the composite corrosion test chamber of the present invention constituted as above operates as follows.

The mixed corrosion test is performed by spraying the brine into the sample parts through the brine nozzle 140 inside the chamber 100. In this process, the inside of the chamber 100 is blown through the air supply line 160 to ventilate the inside of the chamber 100, And the air containing the salt in the chamber 100 is discharged through the discharge line 161. [

On the other hand, when compressed air is supplied through the hose connection groove 31 of the air inlet tube 30 of the ventilation device 170, the compressed air flows to the air inlet portion 11 of the nozzle cylindrical body 10, Through the plurality of air nozzles 12 to the second through holes 14 diagonally toward the axis of the second through holes 14. [

When the compressed air flows into the second through hole 14 and flows as described above, the pressure of the second through hole 14 becomes lower than the pressure of the discharge air inflow hole 33, and the discharge air inflow hole 33 are made to flow in the direction of the second through hole 14 and the discharge air outlet hole 21, and the discharge air is discharged. At this time, since the diameter of the first through hole 13 is smaller than the diameter of the discharge air inflow hole 33, the flow velocity gradually increases and flows to the second through hole 14.

When the length of the discharge line 161 is long, the ventilation device 170 is installed at a predetermined length to smoothly discharge the discharge air.

As described above, the ventilating apparatus of the present invention does not ventilate by a device mechanically driven by electricity such as a blower, but merely discharges the exhausted air by a pressure difference caused by compressed air.

Therefore, in the structure of the present invention, there is no precise parts or parts to be operated, and the structure is simple, there is no friction and wear due to operation, so that even if the discharged air contains salt, the situation of inoperability does not occur, It is possible to use it for a long period of time without corrosion, and there is no friction or operation part even at a high temperature operation, so that heat deformation does not occur. In addition, even if the length of the discharge line 161 is long, a large number of the ventilation devices 170 can be installed at appropriate intervals, so that a smooth discharge operation can be performed, so that the air containing the salt can be easily discharged to the outside of the building.

While the invention has been shown and described with reference to certain exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims.

100: chamber 110: water tank
111: Pump
120: brine tank 121: brine supply line
122: opening / closing valve 130: manifold
140: brine nozzle 150: water jet nozzle
160: air supply line 161: exhaust line
170: Ventilation device 180: Main air injection line
181: saturator 182: opening / closing valve
183: Pressure gauge 185: Air injection line
10: nozzle cylindrical body 11: air inlet
12: air nozzle 13: first through hole
14: second through hole 15, 16: O-ring
20: air discharge cylinder 21: exhaust air discharge cylinder
22: engaging hole 23: engaging mechanism groove
30: air inlet tube 31: hose connecting groove
32: coupling hole 33: exhaust air inflow hole

Claims (4)

A ventilation device installed in a discharge line for discharging air in a chamber to the outside,
A first through hole 13 through which exhaust air flows in the center and a second through hole 14 communicating with the first through hole 13 and larger in diameter than the first through hole 13 are formed, (11) and a second through hole (14) are inclined in the air flow direction around the front portion of the second through hole (14), and the air inlet portion (11) and the second through hole A nozzle cylinder (10) having a plurality of air nozzles (12) communicated therewith;
The hose connecting groove 31 is formed in the hollow cylindrical body 10 and communicates with the air inlet 11 of the nozzle cylindrical body 10, A discharge air inflow hole 33 having a diameter larger than that of the first through hole 13 and an engagement hole 32 for coupling the inflow discharge line 161 are formed in communication with the first through hole 13 An air inlet tube (30); And
An exhaust air outlet hole 21 coupled to the outflow side of the nozzle cylinder 10 and having the same inner diameter as the second through hole 14 of the nozzle cylinder 10, And an air discharge tube (20) in which a coupling hole (22) is formed to be engaged with the air discharge tube (20);
Characterized in that one or more ventilation devices can be installed in the discharge line (161) according to the length of the discharge line (161). The ventilation apparatus of claim 1, wherein the nozzle cylinder (10), the air discharge cylinder (20), and the air inflow cylinder (30) are made of a material which is not corrosive to salt. An air purifier according to claim 1, wherein an O ring (15) (16) is inserted between the nozzle cylinder (10) and the air inflow cylinder (30) (30). ≪ RTI ID = 0.0 > 8. < / RTI > The air discharge tube (20) according to claim 3, wherein a tightening mechanism is inserted into the outer surface of the air discharge cylinder (20) to securely fasten the air discharge cylinder (30) And a fastening mechanism groove (23) is formed to allow the fastening mechanism to be fastened.

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