KR20160066062A - Combustion Testing Device of High Altitude Environment and Testing Method of the Same - Google Patents

Abstract

The present invention relates to a combustion testing device of an internal combustion engine and, more specifically, to a high altitude environment simulation combustion testing device and a testing method thereof which simulate a high altitude environment such as low pressure or a low temperature on the ground to perform a combustion test.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high-

The present invention relates to an apparatus for testing combustion of an internal combustion engine and, more particularly, to an apparatus for testing high-altitude environment simulated combustion capable of simulating a high-altitude environment such as low-pressure and low- And a test method.

As a device simulating high altitude (high) environment, there is a method using a vacuum pump or a diffuser. However, in the case of high altitude environment simulation apparatus using a vacuum pump, it is advantageous to realize an initial low pressure environment, It is difficult to keep the low-pressure environment continuously because it is difficult to maintain the vacuum state inside the vacuum pump when the gas is generated.

In addition, the high-altitude environment simulator using the diffuser has a merit that it is possible to maintain the low-pressure environment irrespective of the generation of the combustion gas, but since it takes a certain time to simulate the low-pressure environment, the initial environment is not a low-pressure environment, When the target altitude is high, there is a disadvantage that the combustion test can not be performed in a state where the low-pressure environment is simulated initially.

Therefore, it is necessary to develop a technology for high-altitude environment simulated combustion test that can simulate the initial low-pressure environment and maintain the low-pressure environment continuously even when the combustion gas is generated.

Korean Patent Publication No. 10-2013-0047129 (published on May 20, 2013).

SUMMARY OF THE INVENTION It is an object of the present invention to solve the problems described above and to provide a method and apparatus for a low pressure environment simulation and a low pressure environment simulation in a thermal vacuum chamber even in a state in which a combustion test is conducted inside a thermal vacuum chamber using an ejector and a thermal vacuum chamber. And a high-altitude environmental simulated combustion test apparatus and test method capable of maintaining the environment.

It is another object of the present invention to provide a high-altitude environmental simulated combustion test apparatus and test method capable of simulating a low-temperature environment by connecting a cooling means to a thermal vacuum chamber.

The high altitude environment simulated combustion testing apparatus of the present invention comprises: a thermal vacuum chamber in which a combustion test object is accommodated; A suction chamber for communicating with the nozzle and the thermal vacuum chamber to lower the pressure of the thermal vacuum chamber through the pressure of the main flow fluid and a diffuser for discharging the main flow fluid, ; A main flow fluid supply part supplying main flow fluid to the nozzle; A floating fluid supply part for supplying a floating fluid to the thermal vacuum chamber; .

The combustion test apparatus may further include: a heat exchange device provided inside the thermal vacuum chamber; And a cooling fluid supply unit for supplying the cooling fluid to the heat exchanger and circulating the cooling fluid to lower the internal temperature of the thermal vacuum chamber; .

The high-altitude environment simulated combustion test method of the present invention includes: a low-pressure environment simulation step of supplying a main flow fluid to a nozzle of an ejector to lower a pressure of a thermal vacuum chamber communicated with a suction chamber of the ejector; Supplying a flue gas to the thermal vacuum chamber to simulate a combustion gas generated during combustion of a combustion test object; And a burning step of stopping the supply of the floating fluid when the pressure inside the thermal vacuum chamber reaches a target pressure, and burning the object to be tested; .

The high-altitude environment simulated combustion test method may further include: supplying a combustion gas; Adjusting a pressure inside the thermal vacuum chamber by adjusting a pressure of a main flow fluid supplied to the nozzle when the internal pressure of the thermal vacuum chamber does not reach a target pressure; .

The high-altitude environment simulated combustion test method may further include: the low-pressure environment simulating step; A low temperature environment simulation step of supplying and circulating a cooling fluid to a heat exchange device provided inside the thermal vacuum chamber so as to lower the temperature inside the thermal vacuum chamber previously; .

In addition, the method may further include: supplying the combustion gas; The flow rate of the floating fluid to be supplied to the thermal vacuum chamber is equal to the flow rate of the combustion gas generated during the combustion of the object to be tested.

The apparatus and method for testing high-altitude environment simulated combustion according to the present invention as described above can simulate a low-pressure environment in the initial combustion test when the target altitude is high, that is, when a low-pressure environment is required, There is an advantage that the combustion test can be performed in a state where the temperature is high.

In addition, it is possible to maintain a low-pressure environment even in the case of sample combustion, and it is possible to maintain a low-pressure environment continuously in a combustion test.

1 is a schematic view of an overall combustion test apparatus of the present invention
2 is a schematic sectional view of the ejector according to the present invention
3 is a flowchart of the combustion test method of the present invention

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

1 is a schematic diagram of an apparatus for testing high-altitude environment simulated combustion according to an embodiment of the present invention (hereinafter referred to as a "combustion test apparatus"). 2 is a schematic cross-sectional view of an ejector 100 according to an embodiment of the present invention. Here, the high altitude environment is defined as a low-temperature environment lower than the atmospheric pressure on the ground and a low-temperature environment lower than the atmospheric temperature on the ground.

Referring to FIG. 1, the combustion testing apparatus of the present invention includes an ejector 100, a main flow fluid supply unit 200, a floating fluid supply unit 300, a thermal vacuum chamber (not shown) 500 and a cooling fluid supply unit 600.

Referring to FIGS. 1 and 2, the ejector 100 includes a nozzle 110 to which a main flow fluid is supplied, a suction chamber 110 communicating with the nozzle 110, (120), and a diffuser (130) through which the main flow fluid and the floating fluid are discharged. The ejector 100 is connected to the thermal vacuum chamber 500 to lower the pressure inside the thermal vacuum chamber 500 communicated with the suction chamber 120 through the main flow fluid supplied to the nozzle 110, 500). ≪ / RTI >

The main flow fluid supply part 200 is configured to supply the main flow fluid to the nozzle 110 of the ejector 100 and the main flow fluid supply part 200 and the nozzle 110 are connected to the first line (L1). The first line (L1) has one end communicating with the main flow fluid supply part (200) and the other end communicating with the inlet end of the nozzle (110). A first valve (V1) for opening and closing the first line (L1) is provided on the first line (L1). The main flow fluid supply pressure to the nozzle 110 can be controlled through the opening and closing control of the first valve V1.

The floating fluid supply part 300 is configured to supply the floating fluid to the thermal vacuum chamber 500 to simulate the flow rate of the combustion gas generated from the object of the combustion test provided in the thermal vacuum chamber 500. Therefore, the floating fluid supply part 300 and the thermal vacuum chamber 500 are communicated through the second line L2. The second line (L2) has one end communicated with the floating fluid supply part (300) and the other end communicated with the thermal vacuum chamber (500). And a second valve V2 for opening and closing the second line L2 is provided on the second line L2. The supply of the floating fluid to the thermal vacuum chamber 500 through the opening and closing of the second valve V2 can be controlled.

The floating fluid flowing into the thermal vacuum chamber 500 can be sucked into the suction chamber 120 through the fifth line L5 communicating the thermal vacuum chamber 500 and the suction chamber 120 of the ejector 100 have. The fifth line L5 has one end communicated with the thermal vacuum chamber 500 and the other end communicated with the suction chamber 120. [ The fifth line L5 may be configured to maintain the open state.

The thermal vacuum chamber 500 can be applied to the construction of a conventional thermal vacuum chamber, and a combustion test object (not shown) is accommodated therein. The inside of the thermal vacuum chamber 500 is subjected to a high-altitude environment simulation test of the target of combustion test by simulating a low-pressure environment through the ejector 100, the main flow fluid supply part 200 and the floating fluid supply part 300 do.

The cooling fluid supply part 600 is configured to cool the internal temperature of the thermal vacuum chamber 500 by supplying a cooling fluid to the thermal vacuum chamber 500. In other words, a heat exchanging device (not shown) such as a radiator is provided in the thermal vacuum chamber 500, and the cooling fluid supply part 600 supplies and circulates the cooling fluid to the heat exchanging device to cool the inside of the thermal vacuum chamber 500 The internal temperature of the thermal vacuum chamber 500 is lowered.

To this end, the cooling fluid supply unit 600 and the heat exchanger of the thermal vacuum chamber 500 are communicated through the third line L3. The third line (L3) has one end communicating with the cooling fluid supply part (600) and the other end communicating with the heat exchange device. A third valve (V3) for opening and closing the third line (L3) is provided on the third line (L3). The supply of cooling fluid to the heat exchanger can be controlled through opening and closing of the third valve V3.

Hereinafter, a combustion test method using the combustion test apparatus of the present invention constructed as above will be described with reference to the drawings.

FIG. 3 is a flow chart of a high altitude environmental simulated combustion test method according to an embodiment of the present invention.

First, the first valve (V1) is opened to perform a low-pressure environment simulation step (S10) for supplying the main flow fluid to the nozzle (110) of the ejector (100). At this time, the pressure of the thermal vacuum chamber 500 communicated with the suction chamber 120 of the ejector 100 is lowered, and the pressure of the thermal vacuum chamber 500 can be set to a low pressure state which is much lower than the test target pressure.

Next, the second valve V2 is opened to supply the floating fluid having the same flow rate as the combustion gas to be generated from the combustion test object provided in the thermal vacuum chamber 500 to the thermal vacuum chamber 500, And performs the combustion gas using fluid supply step (S20). The pressure of the thermal vacuum chamber 500 is brought close to the test target pressure by the supply of the floating fluid.

When the inside of the thermal vacuum chamber 500 does not reach the target pressure, the supply pressure of the main flow fluid supplied to the ejector 100 is adjusted to adjust the pressure of the ejector 100 to the inside of the thermal vacuum chamber 500 A target pressure setting step (S30) is performed so that the pressure becomes the test target pressure. Further, the test target pressure is set by further adjusting the pressure of the ejector 100 when the test target pressure is changed (when the specification of the ejector is changed).

Next, when the inside of the thermal vacuum chamber 500 reaches the target pressure, a combustion step S40 for closing the second valve V2 and igniting the object to be tested to burn the object to be tested to generate the combustion gas . The combustion test can be performed in a state where the pressure inside the thermal vacuum chamber 500 is equal to the target pressure during the combustion test subject to the combustion test through the combustion step S40 described above.

Next, a combustion gas discharging step (S50) is performed in which the combustion gas in the thermal vacuum chamber (500) is discharged through the diffuser (130) of the ejector (100).

When the combustion test of the combustion test object is completed, the first valve (V1) is closed to stop the supply of the main flow fluid supplied to the ejector (100), the pressure of the thermal vacuum chamber (500) It is finished.

The third valve V3 is opened to simulate the low-temperature environment of the thermal vacuum chamber 500 before performing the low-pressure environment simulation step S10 to introduce the cooling fluid into the thermal vacuum chamber 500, 500) may be added to the low temperature environment.

The technical idea should not be construed as being limited to the above-described embodiment of the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, such modifications and changes are within the scope of protection of the present invention as long as it is obvious to those skilled in the art.

100: Ejector 110: Nozzle
120: suction chamber 130: diffuser
200: main flow fluid supply part
300: Floating fluid supply part
500: Thermal vacuum chamber
600: cooling fluid supply part
L1, L2, L3, L5: first line, second line, third line and fifth line
V1, V2, V3: First to third valves

Claims (6)

A thermal vacuum chamber in which a combustion test object is accommodated;
A suction chamber for communicating with the nozzle and the thermal vacuum chamber to lower the pressure of the thermal vacuum chamber through the pressure of the main flow fluid and a diffuser for discharging the main flow fluid, ;
A main flow fluid supply part supplying main flow fluid to the nozzle;
A floating fluid supply part for supplying a floating fluid to the thermal vacuum chamber;
High altitude environmental simulated combustion test equipment.
The method according to claim 1,
In the high altitude environment simulated combustion testing apparatus,
A heat exchange device provided inside the thermal vacuum chamber; And
A cooling fluid supply unit for supplying and circulating a cooling fluid to the heat exchange apparatus to lower the internal temperature of the thermal vacuum chamber;
High altitude environmental simulated combustion test equipment.
A high-altitude environment simulated combustion test method using the high-altitude environment simulated combustion testing apparatus according to claim 1 or 2,
A low pressure environment simulation step of supplying a main flow fluid to a nozzle of the ejector to lower the pressure of the thermal vacuum chamber communicated with the suction chamber of the ejector;
Supplying a flue gas to the thermal vacuum chamber to simulate a combustion gas generated during combustion of a combustion test object; And
A combustion step of stopping the supply of the fluid of the fluid when the pressure inside the thermal vacuum chamber reaches a target pressure and burning the object to be tested;
The method comprising the steps of:
The method of claim 3,
In the high altitude environment simulated combustion test method,
Supplying the flue gas using the flue gas; Since the
Adjusting the pressure inside the thermal vacuum chamber by regulating the pressure of the main flow fluid supplied to the nozzle when the internal pressure of the thermal vacuum chamber does not reach the target pressure;
Further comprising a high-altitude environmental simulated combustion test method.
The method of claim 3,
In the high altitude environment simulated combustion test method,
The low-pressure environment simulation step; Before
A low temperature environment simulation step of supplying and circulating a cooling fluid to a heat exchange device provided inside the thermal vacuum chamber to lower the temperature inside the thermal vacuum chamber;
Further comprising a high-altitude environmental simulated combustion test method.
The method of claim 3,
Supplying the flue gas to the flue gas; city
Wherein the flow rate of the floating fluid supplied to the thermal vacuum chamber is equal to the flow rate of the combustion gas generated during the combustion of the object to be tested.

Images