KR20130047966A - Blower device for high temperature and cryogenic gas - Google Patents

Abstract

PURPOSE: A blower device for high-temperature or cryogenic gas is provided to accurately simulate a space environmental test of a satellite on the ground by circulating the high-temperature or cryogenic gas into a shroud. CONSTITUTION: A blower device for high-temperature or cryogenic gas comprises a blower case(101), a blower(110), a heat exchanger(130), and an airtight member(150). The blower is embedded in the blower case and supplies the high-temperature or cryogenic gas. The heat exchanger circulates heat exchange mediums to the internal space of the blower case to prevent the heating of a blower motor due to the gas supplied by the blower. The airtight member seals a driving shaft of the blower so that the driving shaft of the blower cannot come in contact with the gas supplied by the blower.

Description

BLOWER DEVICE FOR HIGH TEMPERATURE AND CRYOGENIC GAS}

The present invention relates to a blower device for high temperature and cryogenic environment, and more particularly, it can be driven under the harsh experimental temperature conditions of the space environment, so that the high temperature to perform the simulation experiment before the satellite is exposed to the space environment And a blower apparatus for cryogenic environment simulation.

The space environment is characterized by a high vacuum environment and a harsh environment with repeated high and low temperature conditions caused by solar radiation.

Satellites are continuously exposed to the above-mentioned space environment from the moment when they are launched from the ground and enter space orbit, and due to the harsh conditions of the space environment, satellites may cause malfunctions in major parts, which ultimately fails mission. It can also lead to

In other words, the space environment is very different from the ground environment, so, unlike the fact that the satellite is normally operated on the ground at the time of manufacture, satellites exposed to the space environment under severe conditions may cause various unexpected problems. Is there.

For the reasons described above, satellites, etc., have undergone various preliminary tests (hereinafter referred to as 'space environmental tests') conducted under the same conditions as the actual space environment, and need to be checked in advance for major functions and operating conditions. have. The space environment simulation equipment used to conduct these space environment tests is called a thermal vacuum chamber.

Thermal vacuum chambers known to date largely include the configuration of a vacuum system and a thermal control system.

The vacuum system is configured to maintain a high vacuum state by operating a vacuum pump provided separately to discharge the gas in the thermal vacuum chamber to the outside. In addition, the thermal control system is configured to simulate high temperature and cryogenic space temperature conditions through heat exchange with a satellite body mounted in a thermal vacuum chamber, and includes a heat exchanger commonly referred to as a shroud.

In particular, the shroud is a device that simulates the same or similar temperature conditions as the space environment by receiving nitrogen supplied from a separate source (eg LN2 tank) in a certain space to form a high temperature and cryogenic temperature conditions. To this end, the shroud is provided with a blower device connected through a pipe and configured to supply nitrogen at a set pressure and temperature conditions.

That is, the blower device used for the space environment test should have a function to smoothly supply and circulate fluid at high temperature (eg 100 ° C) and cryogenic temperature (eg -150 ° C) into the shroud. .

However, when the conventional conventional blower device is driven in a low temperature state, as the shaft of the motor is exposed to the low temperature fluid as it is, the lubrication characteristics of the shaft have to deteriorate, which is a cause of impairing driving performance.

On the contrary, when the conventional conventional blower device is driven in a high temperature state, it causes a temperature rise to the electric component constituting the motor, resulting in a problem that the drive cannot function or even becomes impossible at the time of driving. .

Therefore, as described above, by solving the problems that may occur in the conventional blower device, the development of a blower device that can smoothly supply and circulate the fluid of high temperature as well as cryogenic conditions to meet the harsh temperature conditions of the space environment It is urgent.

It is an object of the present invention to smoothly supply and circulate fluid at high temperatures (eg 100 ° C.) as well as cryogenic temperatures (eg -150 ° C.), so that spaces such as satellites can be subjected to harsh experimental temperature conditions in space environments. It is to provide a blower device that can accurately simulate the environmental test.

Another object of the present invention is to improve the internal structure such that the motor and shaft in the device are not in direct contact with the hot and cryogenic fluid, thereby preventing the cryogenic properties of the shaft from degrading due to the cryogenic fluid, It is to provide a blower device that can solve the problem that the heat generated in the electrical components of the motor.

Problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems not mentioned herein will be clearly understood by those skilled in the art from the following description.

According to the idea of the present invention for achieving the above technical problem, a blower case; A blower embedded in the blower case and supplying a high temperature or cryogenic fluid to a shroud; A heat exchanger for circulating a heat exchange medium into an inner space of the blower case to prevent the motor of the blower from generating heat by the fluid supplied through the blower; And an airtight member for sealing the drive shaft of the blower to block contact with the fluid supplied through the blower.

Here, the blower case is a cylinder member provided with an inner hollow of a circular cross section, which is separately manufactured and manufactured by a front end portion and a rear end portion along a longitudinal direction, and may be coupled to form a series of bodies.

In this case, a support member for supporting and fixing the blower may be further provided at a portion where the front end and the rear end of the blower case are coupled.

In addition, a drive shaft and a rotary blade of the blower may be disposed at a front end of the blower case to face a fluid discharge port in front of the blower case, and a motor rear end of the blower may be disposed at a rear end of the blower case.

The heat exchanger may include an inlet pipe disposed on a wall facing the rear surface of the blower and connected to the blower case to receive a heat exchange medium; A water outlet pipe connected to the blower case and formed to discharge the heat exchange medium having completed the heat exchange circulation; And a heat exchange channel provided to circulate the heat exchange medium supplied through the inlet pipe.

At this time, the heat exchange medium that has completed the circulation through the heat exchanger may further include a heat exchange pipe for supplying and recirculating the drive shaft of the blower sealed section.

Meanwhile, a water level sensor may be further provided inside the blower case to detect that the heat exchange medium flows out from the heat exchanger.

In addition, the emergency switch for receiving a signal sensed from the water level sensor or the temperature sensor, cut off the power supply applied to the motor of the blower may be further provided.

In addition, a temperature sensor may be further provided inside the blower case to sense a temperature at which the motor of the blower generates heat.

And an emergency switch for receiving a signal sensed from the water level sensor or the temperature sensor, to cut off the power supply applied to the motor of the blower may be further provided.

According to the blower apparatus for high temperature and cryogenic environment of the present invention, it is possible to supply and circulate fluids of high temperature (for example, 100 ° C.) and cryogenic (for example, -150 ° C.) state inside the shroud. It has the effect of simulating environmental test relatively accurately.

In particular, the high temperature and cryogenic environment blower apparatus of the present invention provides an improved internal structure in which the embedded motor and shaft do not directly contact high and low temperature fluids.

According to such an improved structure, as the shaft is in contact with the cryogenic fluid, the lubrication characteristic may be prevented from being lowered during driving, and the phenomenon in which the electric parts of the motor are generated due to the flow effect of the high temperature fluid may be prevented. Therefore, when using the blower apparatus according to the present invention, the smooth drive performance is stably exhibited despite the severe temperature conditions of the fluid supplied and circulated through the blower apparatus.

In addition, according to the blower device for high temperature and cryogenic environment of the present invention, having a configuration of a cooling unit for cooling the motor heat generated inside the housing, and equipped with a water level sensor and a temperature sensor, to control the operation of the blower device in an emergency It can be equipped with automated configuration.

1 is a cross-sectional view illustrating a schematic structure of a blower apparatus for high temperature and cryogenic environment simulation according to an embodiment of the present invention.
2 is a cross-sectional view schematically illustrating a configuration in which a blower device for high temperature and cryogenic environment simulation according to an embodiment of the present invention includes a water level sensor and a temperature sensor to cut off power applied to a blower motor in an emergency.
Figure 3 is a view showing the effect of preventing the motor heat generation of the blower through the heat exchange medium circulation in the blower device for high temperature and cryogenic environment according to an embodiment of the present invention.
Figure 4 is a view showing the effect of improving the drive shaft cooling problem of the blower through the heat exchange medium recirculation in the blower device for high temperature and cryogenic environment according to an embodiment of the present invention.
5 is a view schematically showing the front view of the front end of the blower case in a blower device for high temperature and cryogenic environment simulation according to an embodiment of the present invention.
6 is a view schematically illustrating a rear view of the rear end of the blower case in the high temperature and cryogenic environment-type blower apparatus according to the embodiment of the present invention.

The terms or words used in this specification and claims are not to be construed as limiting in their usual or dictionary meanings, and the inventors may appropriately define the concept of terms in order to best describe their invention. Based on the principle that it can, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications may be present. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

The high temperature and cryogenic environment blower apparatus of the present invention is a part of the thermal vacuum chamber used for conducting a space environment test, such as a satellite produced on the ground. In other words, in order to test in advance whether the satellite body or the like performs its intended function smoothly under the same temperature conditions as the real space environment, a heat exchanger commonly referred to as a shroud is used for the high and low temperature fluids using the blower device. Feed into and circulate.

Hereinafter, a blower apparatus for high temperature and cryogenic environment simulation according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a cross-sectional structural view schematically showing the overall configuration of a blower apparatus according to an embodiment of the present invention.

As shown, the blower device 100 according to the preferred embodiment of the present invention, the blower case 101, the blower 110 is built into the blower case to supply a high temperature or cryogenic fluid, and the motor heat of the blower Heat exchanger 130 to prevent the, and the airtight member 150 to block the cooling of the drive shaft of the blower.

The blower case 101 is a cylindrical member provided with a hollow 103 therein. The material of the blower case 101 need not be limited, but may be manufactured using SUS material having excellent heat resistance, chemical resistance, abrasion resistance, and mechanical strength.

In particular, as shown in FIG. 1, the blower case 101 is separated from both ends at the center along the longitudinal direction of the entire body, and then manufactured, respectively, and then coupled to each other to form a series of bodies to seal the inner hollow 103. It may be provided as a structure.

Here, the support member 105 is further provided on the coupling portion of the blower case 101 is formed to extend in the cross section toward the inner hollow 103, the blower 110 to be described later is fixed by the support member 105 And may be mounted inside the blower case 101.

At this time, the support member 105 need not be limited to the specific shape and structure shown in the drawings, and may be implemented in a variety of forms little by little without departing from the scope of the invention. In addition, it is not necessary to limit not only the shape of the coupling site | part of the blower case 101 but also a coupling system.

On the other hand, the front end portion 101a of the blower case 101 is provided with a fluid discharge port 102 through which the fluid (for example, GN2) is discharged by the blower device of the present invention, and thus, plays a main role in supplying fluid. The shaft 113 and the rotary blade 115 of the blower are also disposed forward in the front end portion 101a of the blower case 101.

Here, an example of the front shape of the front end portion 101a of the blower case can be confirmed through FIG. 5. Referring to the drawings, a fluid inlet 210 through which fluid is introduced is provided at one side of the front end portion 101a of the blower case 101. Through this, the fluid introduced into the blower case 101 is discharged through the fluid discharge port 102 due to the driving of the rotary blades 115 of the blower. The discharged fluid is supplied and circulated through the fluid outlet 220 into a heat exchanger, commonly referred to as a shroud.

On the other hand, the blower motor 111 is arranged at the rear end 101b of the blower case 101. An example of the rear shape of the rear end 101b of the blower case 101 may be confirmed through FIG. 6. The rear end portion 101b of the illustrated blower case 101 may further include an inlet pipe 131 and a outlet pipe 133 formed so that the heat exchange medium is obtained and exited to prevent heat generation of the motor 111. A detailed description thereof will be provided through the heat exchanger 130 to be described later.

Next, the blower 110 will be described.

As briefly mentioned above, the blower 110 may include a motor 111 that generates a rotational force by receiving a large power, a drive shaft 113 mounted on the shaft center of the motor 111 to drive rotation, and the drive. It is mounted to the end of the shaft 113 includes a rotary blade 115 that rotates to generate wind power in a predetermined direction.

The blower 110 forcibly flows a fluid of high temperature (eg 100 ° C.) as well as a cryogenic temperature (eg 150 ° C.) toward the fluid discharge port 102 of the blower case 101 in accordance with an object of the present invention. This is a device that circulates and supplies fluid to the shroud.

However, when the electrically operated motor 111 is heated up to a predetermined temperature, a problem may occur that its function is lost. When the driving shaft 113 is exposed to a low temperature fluid, the driving shaft 113 may be damaged. The lubrication property of the deterioration may be a problem that can not rotate at the target speed. As a detailed configuration for solving and improving such a problem, a heat exchanger 130 and an airtight member 150 are used.

Next, the heat exchanger 130 will be described.

The heat exchanger 130 is a device for circulating a heat exchange medium (that is, a refrigerant) in order to prevent heat generation on the motor 111 side of the blower.

The heat exchanger 130 according to the present invention has a function of cooling the temperature of the hollow 103 region of the rear end portion 101b of the blower case 101 in which the motor 111 is disposed to a predetermined temperature (for example, 20 to 50 ° C.). To provide.

The heat exchanger 130, the heat exchange channel formed to circulate the heat exchange medium supplied from the inlet pipe 131 receiving the heat exchange medium, the outlet pipe 133 for discharging the heat exchange medium, and the inlet pipe 131 ( 135).

The water inlet pipe 131 and the water outlet pipe 131 may be installed through the wall of the rear end portion 101b of the blower case, and the heat exchange channel 135 is blower in a position facing the rear of the motor 111 of the blower. It may be disposed on the rear surface 101b of the case.

The heat exchange medium supplied, circulated and discharged through the heat exchanger 130 may use water or cooling water at room temperature or a similar temperature (for example, 20 ° C.). To this end, each of the inlet pipe 131 and the outlet pipe 131 may have a structure connected to the external heat exchange medium storage tank (not shown).

Here, the description of the function of preventing heat generation of the motor 111 of the blower according to the action of the heat exchanger 130 may be described with reference to FIG. 3. Figure 3 is a view showing the effect of preventing the motor heat generation of the blower through the heat exchange medium circulation in the blower device for high temperature and cryogenic environment according to an embodiment of the present invention. As shown, the inlet pipe 131 and the outlet pipe 133 of the heat exchanger are installed through the wall of the rear end 101b of the blower case 101, and the heat exchange channel 135 is rearward of the motor 111. Are arranged opposite.

The heat exchange medium L1 at room temperature is supplied through the inlet pipe 131 and circulated through the heat exchange channel 135 connected thereto. As a result of the circulating action of the heat exchange medium L1, the temperature of the rear end portion 101b of the blower case 101 drops to a predetermined temperature TL. At this time, since the dropped temperature TL is lower than the heat generation temperature TH of the motor 111, the temperature of the motor 111 is cooled until mutual thermal equilibrium due to the heat transfer action.

On the other hand, the heat exchange medium (L2) after the heat exchange action is slightly elevated than the temperature of the heat exchange medium (L1) at the time of acquisition, is discharged to the outside through the water discharge pipe (133).

In addition, the heat exchange medium used in the heat exchanger 130 will be recirculated to look at the function of preventing the cooling of the drive shaft. Description of this may be described with reference to FIG. 4. Referring to FIG. 4, the heat exchange medium is connected between the water discharge pipe 133 and the sealing section 157 of the drive shaft 113 of the blower, and the sealing section 157 of the drive shaft 113 to the water inlet pipe 131. It can be seen that the heat exchange pipe 160 capable of circulation is provided.

Next, the function of preventing the heat generation of the motor 111 by the heat exchange medium L1 obtained through the heat exchange channel 135 will be described. Next, the function of the heat exchange pipe 160 will be described in detail. The heat exchange medium L2 discharged through the circulator may be circulated and supplied to the section 157 in which the driving shaft 113 is sealed.

That is, the heat exchange medium L3 at this time is used as a fruit to prevent overcooling of the drive shaft 113.

And the heat exchange medium (L4) after being used to prevent the supercooling of the drive shaft 113 is lowered to a low temperature again, which is used as a heat exchange medium (L1) to prevent the heat of the motor 111 again. It is introduced through the inlet pipe 131 to.

As such, the heat exchange method of the blower device described with reference to FIG. 4 is one of the methods for efficiently using thermal energy, and may be implemented and modified in various forms by additionally configuring a heater, a cooler, etc. without departing from the scope of the present invention. have.

Meanwhile, the airtight member 150 seals around the drive shaft 113 to prevent the low temperature fluid from directly contacting the drive shaft 113. The airtight member 150 may be implemented in a variety of different embodiments. In particular, according to a preferred embodiment of the present invention, as shown in Figure 1, the airtight member 150 is a diaphragm type airtight member 151 for partitioning between the drive shaft 113 and the rotary blade 114, It can be seen that the airtight member 153 sealed on the rear surface and the airtight member 155 sealed with a predetermined space around the outer periphery of the drive shaft 113. Among the hermetic members 151, 153, and 155, in particular, the hermetic member 155 surrounding the drive shaft 113 should be completely blocked from the outside so that the hermetic member 151 can be sealed. Accordingly, the drive shaft 113 is in contact with the low temperature fluid. This can prevent the phenomenon of deterioration of lubrication characteristics.

Next, with reference to Figure 2 will be described with respect to the embodiment provided with a variety of sensors in the blower device for high temperature and cryogenic environment simulation according to the embodiment of the present invention.

Referring to FIG. 2, the illustrated blower apparatus 100 includes the configuration of the blower case 101, the blower 110, the heat exchanger 130, and the airtight member 150 as described above, and additionally, a water level sensor. 172 and the temperature sensor 174 can be confirmed.

The water level sensor 172 is provided inside the blower case 101 and serves to detect the leakage of the heat exchange medium from the heat exchanger 130. In particular, as shown, it can be seen that the installation position of the water level sensor 172 is provided at the bottom edge of the rear end of the blower case 101, this installation position does not necessarily limit the present invention.

The temperature sensor 174 is provided inside the blower case 101 similarly to the water level sensor 172 and serves to sense a temperature at which the motor 111 generates heat. In particular, the meaning that the temperature sensor 174 detects the heat generated temperature of the motor 111, by measuring the temperature of the hollow region of the rear end of the blower case 101, the motor 111 is disposed, the motor 111 It can be understood as a means to monitor whether the heat is generated above the set temperature.

In addition, each of the water level sensor 172 and the temperature sensor 174 is electrically connected to the emergency switch 190 provided in the power supply unit 180. Thus, when the leakage of the heat exchange medium is detected from the water level sensor 172, or when a signal is detected that the temperature value measured from the temperature sensor 174 exceeds the allowable temperature range, the power applied to the motor 111 Can be shut off in an emergency. This helps to maintain the device as well as to ensure the safety of the operator.

As described above, according to the present invention, it is possible to supply and circulate fluids of high temperature (for example, 100 ° C.) and cryogenic (for example, -150 ° C.) state inside the shroud. It has a relatively accurate effect.

In particular, according to the high temperature and cryogenic environment blower apparatus of the present invention, it is possible to provide an improved internal structure in which the embedded motor and shaft do not directly contact high and low temperature fluids.

According to the improved structure as described above, it is possible to prevent the phenomenon that the lubrication function of the shaft is caused by the influence of the cryogenic fluid, and the motor of the blower heats due to the influence of the high temperature fluid, the driving performance is worsened or lost. Problems can be prevented.

That is, in the case of using the blower device according to the present invention, although the fluid supplied and circulated through the blower device has severe temperature conditions, the user can stably supply and circulate the fluid as desired.

In addition, according to the blower apparatus for high temperature and cryogenic environment which is the present invention, it has the structure of the cooling part which cools the motor which generate | occur | produced inside the housing, and is equipped with a water level sensor and a temperature sensor. Accordingly, in the event of an emergency, the blower device can be stopped quickly, preventing excessive damage to the device, and also ensuring worker safety.

As mentioned above, the preferred embodiment regarding the high temperature and cryogenic environment-type blower apparatus which concerns on this invention was described.

It is to be understood that the foregoing embodiments are illustrative in all respects and not restrictive, the scope of the invention being indicated by the following claims rather than the foregoing description. And it is to be understood that all changes and modifications derived from the equivalent concept as well as the meaning and scope of the claims are included in the scope of the present invention.

100: blower device
101: blower case
110: blower
111: motor 113: drive shaft
115: rotary wing
130: heat exchanger
131: water supply pipe 133: water supply pipe
135: heat exchange channel
150: airtight member
160: heat exchange pipe
172: water level sensor 174: temperature sensor
180: Power supply
190: emergency switch

Claims (9)

Blower case;
A blower embedded in the blower case and supplying a high temperature or cryogenic fluid;
A heat exchanger for circulating a heat exchange medium into an inner space of the blower case to prevent the motor of the blower from generating heat by the fluid supplied through the blower; And
And a hermetic member sealing the drive shaft of the blower to block contact with the fluid supplied through the blower.
The method of claim 1,
The blower case,
A cylindrical member provided with an inner hollow of a circular cross section, the blower device for high temperature and cryogenic environment, characterized in that the separation is produced after the front end and the rear end in the longitudinal direction are combined to form a series of bodies.
The method of claim 1,
The blower device for high temperature and cryogenic environment, characterized in that the support member for supporting and fixing the blower is further provided at a portion where the front and rear ends of the blower case are coupled.
The method of claim 3, wherein
At the front end of the blower case, a drive shaft and a rotary blade of the blower are disposed to face the fluid discharge port in front of the blower case.
Blower device for high temperature and cryogenic environment, characterized in that the rear end of the blower case is disposed at the rear end of the blower case.
The method of claim 1,
The heat exchanger is disposed on the wall facing the rear of the motor of the blower,
An inlet pipe formed through the blower case and supplied with a heat exchange medium;
A water outlet pipe connected to the blower case and formed to discharge the heat exchange medium having completed the heat exchange circulation; And
And a heat exchange channel provided to circulate the heat exchange medium supplied through the inlet pipe.
The method of claim 5, wherein
And a heat exchange pipe for supplying and recirculating the heat exchange medium that has been circulated through the heat exchanger to a section in which the drive shaft of the blower is sealed.
The method of claim 1,
The blower device for high temperature and cryogenic environment is provided in the blower case further comprises a water level sensor for detecting the outflow of the heat exchange medium from the heat exchanger.
The method of claim 1,
A blower apparatus for high temperature and cryogenic environment, which is provided inside the blower case and further includes a temperature sensor for detecting a temperature at which the motor of the blower generates heat.
9. The method according to claim 7 or 8,
Blower device for high temperature and cryogenic environment, characterized in that the emergency switch for receiving a signal sensed from the water level sensor or the temperature sensor, to cut off the power supply applied to the motor of the blower.

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