KR101924209B1 - Heat Radiating Control Method of Active Electronically Scanned Array Long Range Radar - Google Patents

Abstract

According to the present invention, provided is a method of radiating a long-range active phase array radar. A body part including a plurality of heat-radiating packaging structures connected to a separate antenna device and transferring heat to the outside and a wing frame rotatably connected to the body part and selectively located on both sides of the body part are provided. So, it is possible to cool many heat sources in a limited space by air cooling.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method of radiating long distance active phased array radar,

The present invention relates to a heat dissipation method of a long-range active phased array radar, and more particularly, to a heat dissipation structure of an extendable long-range radar that satisfies at least 300 km, and a long-range active phased array radar and a heat dissipation method.

The radar performs a search to detect the target, performs the task of swiftly and precisely detecting the identification and wake of the aircraft through 24-hour uninterrupted operation, and transmits the detected target to the central control station to monitor and reconnaissance .

In order to maintain the performance of high power large radar in high temperature environment, air cooling type cooling structure is essential. As the size of the antenna increases, the space for applying the air-cooling structure does not increase proportionally, so it is necessary to air-cool many heat sources within a limited space.

In addition, cooling structure design technology is required to satisfy radar performance 24 hours uninterruptedly through shape and layout design of cooling structure (duct) and heat dissipation component (blower, etc.) to apply efficient air cooling type cooling structure in limited space.

In particular, when moving large structures, vehicle movement according to the Road Traffic Act is considered. A foldable structure design technique is required to make a mobile or mobile radar.

Korean Registered Patent No. 10-1808592 (Registered on Dec. 07, 2017)

The present invention relates to a heat dissipation structure of an expandable long-range radar, a long-range active phased array radar having the same, a body part including a plurality of heat dissipation packaging structures connected to a separate antenna device through heat dissipation method, Air cooling in a limited space by providing a wing frame that is rotatably connected to the body portion and can be selectively positioned on both sides of the body portion.

It is another object of the present invention to solve the performance degradation due to the occurrence of a misalignment of the antenna alignment due to disassembly and reassembly for the mobile installation, and to maintain the same antenna performance as the proximity field result even when moving and reinstalling.

In addition, even if the blower which is the main heat-dissipating component fails, it is possible to maintain the reliability that the radar can be operated 24 hours a day by applying the thermal insulation structure that can operate continuously, and the flow loss prevention structure that can occur when the redundant structure is applied. .

Other and further objects, which are not to be described, may be further considered within the scope of the following detailed description and easily deduced from the effects thereof.

According to an aspect of the present invention, there is provided a heat dissipation structure of an expandable long-range radar, including: a body portion including a plurality of heat dissipation packaging structures connected to a separate antenna device, And a wing frame rotatably connected to the body portion and selectively positioned on both sides of the body portion.

The body part further includes a mounting frame connected to the body part and mounting the plurality of heat dissipating packaging structures. The wing frame includes a support frame for seating the separate antenna device, And at least one assembling module rotatably connected to the body part, and is connected to the body part in a folding structure.

Here, the heat-dissipating packaging structure may include a structure enclosure capable of assembling a plurality of heat-dissipating devices in series inside the enclosure, an internal housing disposed inside the enclosure, and the air supplied to the heat- And a fluid inlet fixed to an end of the duct and introducing the air to form an air flow path in the heat dissipation device.

Here, the heat dissipating device may include at least one electronic component, and may include a body capable of transmitting heat to the outside and a plurality of radiating fins arranged at an outer side of the body, wherein each of the radiating fins includes an air Wherein the main body surrounds at least a part of the partition part for separating and mounting each of the electronic components and discharges heat from the electronic component to the outside, And a heat dissipation housing positioned adjacent to the heat dissipation fin.

Here, the fluid inflow portion includes an open / close control portion connected to the duct and controlling the flow rate by opening / closing the inside of the duct, and the open / close control portion connects the duct and the fluid inflow portion, A lid part, a hinge structure for connecting the lid part and the fluid inflow part, rotating the lid part according to the inflow of the fluid, and a hinge part for detecting the operation state of the fluid inflow part and automatically controlling the air flow rate and intensity of the fluid inflow part And a sensor unit connected to the hinge structure.

The hinge structure includes a fixed base fixed to the fluid inlet and a coil spring installed on the fixed base to store elastic restoring force when the cover is deployed and to provide the elastic restoring force such that the cover is closed in the original state The coil spring is connected to one end of the sensor unit, and the sensor unit senses the operation of the coil spring.

Here, the heat dissipation packaging structure may include a first fluid inflow portion and a second fluid inflow portion at a lower end of the heat dissipation packaging structure, and the first fluid inflow portion and the second fluid inflow portion may respectively have a first open / close control portion, The first opening / closing control unit senses the operation of the first fluid inlet and stops the operation of the first fluid inlet, and transmits the driving signal to the second opening / closing control unit, and the second fluid inlet unit operates.

Here, the heat-dissipating packaging structure may include a heat insulating part located between the plurality of heat dissipating devices, a fixed plate block connecting and fixing the outer pipe of the duct to the heat dissipating fins, a heat sink connected to the heat dissipating housing, An adapter block, a packing unit assembled with the adapter block and having a waterproof function of the main body, and a shielding unit connecting the outside of the main body and the inside of the heat dissipation unit and shielding electromagnetic waves of the electronic component.

Here, the heat dissipation packaging structure may include a plurality of heat dissipating devices mounted on the right side of the adapter block, the duct being assembled on the left side of the fixed plate block, the adapter block being assembled on the right side, The assembly direction is opposite to the wing frame.

According to another aspect of the present invention, there is provided an expandable long-range active phased array radar comprising: a body portion including a plurality of heat-dissipating packaging structures for connecting an antenna device and transferring heat to the outside; A wing frame that can be selectively positioned on both sides of the body portion, and a radar maintenance unit that performs maintenance in a direction opposite to a direction in which the body unit connects the antenna device, wherein the body unit is connected to the body unit, A mounting frame for mounting a plurality of heat-dissipating packaging structures, and a support portion connected to the mounting frame and supporting the antenna device so as to be rotatable and angularly adjustable, wherein the wing frame is connected to the body portion in a folding- And includes a plurality of array elements within a plane range of the wing frame.

Here, the heat-dissipating packaging structure may include a structure enclosure capable of assembling a plurality of heat-dissipating devices in series inside the enclosure, an internal housing disposed inside the enclosure, and the air supplied to the heat- And a fluid inlet fixed to an end of the duct and introducing the air to form an air flow path in the heat dissipation device.

Here, the heat dissipating device may include at least one communication module, and may include a main body capable of transmitting heat to the outside, and a plurality of radiating fins arranged at an outer side of the main body, And a heat dissipating unit for performing heat exchange with the outside through the flow path, wherein the main body includes a temperature sensor for sensing the temperature of the electronic component, a partition wall for separately mounting each of the electronic components, and at least a part of the partition wall And a heat dissipation housing that discharges heat from the electronic component to the outside and is located adjacent to the heat dissipation fin.

Here, the fluid inlet may include an opening / closing controller connected to the duct and controlling the flow rate by opening / closing the inside of the duct, wherein the opening / closing controller connects the duct and the fluid inlet, A hinge structure for connecting the lid part and the fluid inflow part and rotating the lid part according to the inflow of the fluid and a hinge structure part for sensing the operation state of the fluid inflow part and automatically controlling the air volume and intensity of the fluid inflow part The hinge structure includes a fixing base fixed to the fluid inlet and a fixing unit installed on the fixing base to store an elastic restoring force when the cover is unfolded, And a coil spring for providing the elastic restoring force to close the coil Spring is connected with one end of the sensor part and the sensor portion detects the operation of the coil spring.

Here, the heat dissipation packaging structure may include a first fluid inflow portion and a second fluid inflow portion at a lower end of the heat dissipation packaging structure, and the first fluid inflow portion and the second fluid inflow portion may respectively have a first open / close control portion, The first opening / closing control unit senses the operation of the first fluid inlet and stops the operation of the first fluid inlet, and transmits the driving signal to the second opening / closing control unit, and the second fluid inlet unit operates.

Here, the heat dissipation packaging structure may include a plurality of heat dissipating devices mounted on the right side of the adapter block, the duct being assembled on the left side of the fixed plate block, the adapter block being assembled on the right side, The assembly direction is opposite to the wing frame.

A method of radiating a long-range active phased array radar according to another embodiment of the present invention includes: sensing a first fluid inlet motion detection step, receiving the first fluid inlet motion detection signal, detecting a motion of the first fluid inlet part Checking the temperature of the electronic component when receiving a signal, and determining that the temperature of the electronic component is normal when the temperature is below the set temperature.

A step of transmitting a driving signal to the second opening / closing control unit when the temperature of the electronic component is equal to or higher than a predetermined temperature, and a step of transmitting a driving signal to the second opening / And the second opening and closing control unit drives the second fluid inlet.

As described above, according to the embodiments of the present invention, it is possible to provide a heat exchanger having a body portion including a plurality of heat-dissipating packaging structures connected to a separate antenna device for transferring heat to the outside, and a body portion rotatably connected to the body portion, By providing a wing frame that can be selectively positioned on either side of the body portion, many of the heat sources can be air cooled in a confined space.

In addition, by applying the cooling module integrated electronic module assembly structure, the cooling performance of the radar can be ensured, and mechanical / electronic shielding performance that can be exposed when the integral assembly structure is applied can be secured.

In addition, even if the blower which is the main heat dissipation component fails, it is possible to ensure the reliability that the radar can be operated without interruption for 24 hours by applying the redundant structure of heat dissipation component that can be continuously operated and the flow loss prevention structure that can occur when the redundant structure is applied.

Accordingly, if a blower having a fault diagnosis function is used or a separate sensor is applied to the inside of the duct to monitor the normal operation of the heat radiation structure, the motion detection signal is integrated into the flow loss prevention structure, Waste can be minimized.

Even if the effects are not expressly mentioned here, the effects described in the following specification which are expected by the technical characteristics of the present invention and their potential effects are handled as described in the specification of the present invention.

1 is a perspective view illustrating a heat dissipation structure of an expandable long-range radar according to an embodiment of the present invention.
2 is a view illustrating a heat dissipation packaging structure of a heat dissipation structure of an expandable long-range radar according to an embodiment of the present invention.
3 is a view illustrating a heat dissipation device of a heat dissipation structure of an expandable long-range radar according to an embodiment of the present invention.
4 is a view illustrating a fluid inflow portion of a heat radiating structure of an expandable long-range radar according to an embodiment of the present invention.
FIG. 5 is a view illustrating a hinge structure of a heat radiating structure of an expandable long-range radar according to an embodiment of the present invention.
6A and 6B are views showing the appearance of a heat radiating packaging structure of a heat radiating structure of an expandable long-range radar according to an embodiment of the present invention.
7 is an exploded view showing a heat dissipation packaging structure of a heat dissipation structure of an expandable long-range radar according to an embodiment of the present invention.
8a-8c illustrate an expandable long-range active phased array radar in accordance with an embodiment of the present invention.
FIG. 9 is a diagram illustrating a thermal packaging structure mounted on an expandable long-range active phased array radar according to an embodiment of the present invention.
10 is a flowchart illustrating a heat dissipation method of an expandable long-range active phased array radar according to an embodiment of the present invention.

Hereinafter, a heat dissipation structure of an expandable long-range radar according to the present invention, a long-range active phased array radar and a heat dissipation method having the same will be described in detail with reference to the drawings. However, the present invention can be implemented in various different forms, and is not limited to the embodiments described. In order to clearly describe the present invention, parts that are not related to the description are omitted, and the same reference numerals in the drawings denote the same members.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, .

The suffix " module " and " part " for the components used in the following description are given or mixed in consideration of ease of specification, and do not have their own meaning or role.

The terms first, second, etc. may be used to describe various elements, but the elements should not be limited by terms. The terms are used only for the purpose of distinguishing one component from another.

The present invention relates to a heat radiating structure of an extendable long-range radar, a long-range active phased array radar having the same, and a heat dissipating method.

1 is a perspective view illustrating a heat dissipation structure of an expandable long-range radar according to an embodiment of the present invention.

1, an expandable long-range radar heat dissipation structure 10 according to an embodiment of the present invention includes a body 100, a wing frame 200, a heat dissipation packaging structure 300, a mount frame 400, .

In the present embodiment, the long-range radar means an apparatus including all of the structures for performing operations as a radar including a body portion, a wing frame, and a heat radiating packaging structure. The long-range radar is a detection radar that can detect the surrounding wake and acquire target information including three-dimensional target information, for example, distance, bearing, and altitude. The long-range radar of this embodiment may have identification capability for peer identification according to international standards (ex: International Civil Aviation Organization standards, etc.). In addition, it may further include a communication module capable of communicating with a long-range radar master control center and an air traffic control center.

The heat spreading structure 10 of the expandable long-range radar is a structure used for an antenna device designed as a foldable structure for manufacturing a movable or mobile radar.

In order to maintain the performance of high power large radar in high temperature environment, air cooling type cooling structure is essential. As the size of the antenna increases, the space for applying the air-cooling structure does not increase proportionally, so it is necessary to air-cool many heat sources within a limited space.

In order to apply an efficient air-cooled cooling structure in a limited space, there is a need for cooling structure design technology to satisfy the radar performance 24 hours uninterruptedly through the shape and layout design of the cooling structure (duct) and the heat dissipation component (blower etc.).

The body 100 includes a plurality of heat-dissipating packaging structures connected to a separate antenna device and transferring heat to the outside.

The wing frame 200 may be movably installed on the body portion, and may be selectively positioned on both sides of the body portion.

In case of general large radar air-cooled radiator structure, main radiator components (FAN, etc.) are installed on the antenna left and right wing parts for space utilization and the air generated from FAN etc. is passed through duct to cool the component However, in the embodiment of the present invention, a plurality of heat-dissipating packaging structures are mounted only on the body 100, so that even when the antenna is made into a foldable structure The heat dissipation structure can be applied, and the electronic module and the heat dissipation housing are connected to each other, so that the cooling performance can be secured.

The wing frame 200 includes a first wing frame 210 connected to one side of the body portion and a second wing frame 230 connected to the other side of the body portion.

The wing frame 200 is connected to the body portion in a folding structure. The first wing frame 210 and the second wing frame 230 may be connected to the body 100 in a folding structure. In addition to the folding structure, the first wing frame 210 and the second wing frame 230 may have a slide structure, And can be made in an adjustable structure. The wing frame 200 is a structure capable of reducing a width of about 8 meters when the folding type antenna apparatus is moved, and the structure is folded sequentially without interference.

The wing frame 200 includes support frames 213 and 233 for supporting separate antenna devices and for adjusting the angle and at least one assembly module for pivotally connecting to the body portion, As shown in FIG.

One side of the first wing frame 210 is connected to the first assembly module 211 and one side of the second wing frame 230 is connected to the second assembly module 231.

The assembly modules 211 and 231 are preferably a foldable hinge structure including a hinge portion so as to be hinged to one side of the wing frame 200.

The first assembly module 211 and the second assembly module 231 are formed to have a relatively different height so that when the first wing frame 210 and the second wing frame 230 are folded,

In consideration of the antenna folding structure for vehicle movement, the heat-radiating packaging structure 300 has all the heat-radiating components for cooling the electronic components of the radar placed in the central body portion, not in the wings.

The heat dissipation packaging structure 300 is modularized, and when the modular structure is applied, six heat dissipation packaging structures 300 have the same heat dissipation performance.

The heat dissipation packaging structure 300 is a heat dissipation structure applying an air cooling type cooling structure. Air cooling is a type of cooling in a thermal design, in which air is used as a cooling medium. It is adopted in many information devices because it is excellent in economy. Natural air cooling using natural convection of air, and forced air cooling using forced fan to make air flow. Compared to natural air cooling, forced air cooling has a large flow rate, so the heat dissipation effect is one place larger. For ICs and transistors with a large amount of heat generated in information devices, heat dissipation effect may be locally increased by attaching heat dissipating vanes.

Specifically, it is a type of a cooling device for cooling air by circulating air around cylinders and blocks to eliminate the heat generated inside the transmission / reception part of the radar. In this type, there is no need for cooling water flowing through the inside of the radar, and a radiator is not required. A radiating fin with cooling effect is installed and air cools the radiating fin. Forced cooling and natural cooling can be used.

The mounting frame 400 is connected to the body 100 and mounts a plurality of heat dissipation packaging structures. In an embodiment of the present invention, a total of six heat-dissipating packaging structures are mounted, and the amount of the heat-radiating packaging structure can be adjusted depending on the structure and size of the radar.

In addition, the body 100 may further include an antenna mounting structure 110 to allow a separate antenna device to be mounted thereon. In addition, the body 100 may include a plurality of antenna mounting structures 110, And may include connecting structures 111 and 113. The angle adjusting unit may include a motor for receiving a driving signal for rotating and lifting the body and receiving a driving signal to rotate forward or reverse and a motor Side gear.

2 is a view showing a heat dissipation packaging structure 300 of a heat dissipation structure of an expandable long-range radar according to an embodiment of the present invention.

2, the heat dissipation packaging structure 300 according to an embodiment of the present invention includes a structure enclosure 310, a duct 320, a heat dissipation device 330, and a fluid inflow portion 340.

In consideration of the antenna folding structure for vehicle movement, the heat-radiating packaging structure 300 has all the heat-radiating components for cooling the electronic components of the radar placed in the central body portion, not in the wings. The heat dissipation packaging structure 300 has a structure in which a structure is twisted in a heat treatment process after welding in the case of an aluminum welding structure having a width of 10m or more and a length of 10m or more. It is difficult to match the interface of the assembled components. However, when a modularized heat dissipation structure is used, The interface between the antenna body and the modularized heat dissipation structure can be satisfied.

The heat dissipation packaging structure 300 is modularized, and when the modular structure is applied, six heat dissipation packaging structures 300 have the same heat dissipation performance.

The heat dissipation packaging structure 300 is a heat dissipation structure applying an air cooling type cooling structure. Air cooling is a type of cooling in a thermal design, in which air is used as a cooling medium. It is adopted in many information devices because it is excellent in economy. Natural air cooling using natural convection of air, and forced air cooling using forced fan to make air flow. Compared to natural air cooling, forced air cooling has a large flow rate, so the heat dissipation effect is one place larger. For ICs and transistors with a large amount of heat generated in information devices, heat dissipation effect may be locally increased by attaching heat dissipating vanes.

Specifically, it is a type of a cooling device for cooling air by circulating air around cylinders and blocks to eliminate the heat generated inside the transmission / reception part of the radar. In this type, there is no need for cooling water flowing through the inside of the radar, and a radiator is not required. A radiating fin with cooling effect is installed and air cools the radiating fin. Forced cooling and natural cooling can be used.

The structure enclosure 310 constitutes an outer appearance, and a plurality of heat dissipation devices can be assembled in series inside.

The ducts 320 are located inside the structure enclosure and guide the air supplied to the heat sinks assembled in series.

The duct 320 is a passage and structure through which air or other fluid flows. When the air flows, it is also called "wind". It is often used that the cross section is rectangular or circular, but sometimes it may be elliptical. When the temperature of the air flowing through the duct is different from the surrounding temperature, it is necessary to wind the insulation around the duct when it is desired to prevent the heat from moving. Usually steel sheets are often used, but sometimes vinyl chloride or glass fiber is also used.

The heat dissipating device 330 may include an electronic component, and examples of the electronic component include a transmitting and receiving portion. And is installed outside the transceiver unit to perform heat exchange with the outside. Specifically, a plurality of heat-radiating fins 332 are connected to the heat-radiating housing provided at the outer side of the main body of the transceiver unit, and an air passage is formed between the heat-radiating fins 332 to perform heat exchange with the outside .

The fluid inlet 340 is fixed to an end of the duct to allow the air to flow into the heat sink. The fluid inflow part 340 includes at least one blower, and includes a sensor part, so that operation monitoring and trouble diagnosis are possible. Specifically, the blower, which is the main heat dissipation component, is redundantly applied for 24-hour uninterrupted operation of the radar, and a flow loss prevention structure using a spring is applied to prevent loss of flow to a blower which is not operated when only one blower operates.

Each of the heat dissipating devices 330 is assembled to the heat insulating part 370 so that the heat insulating part 370 surrounds at least a part of each heat dissipating device 330 so that the heat insulating part 370 can heat Insulate to prevent heat loss during transportation.

3 is a view illustrating a heat dissipating device 330 of a heat radiating structure of an expandable long-range radar according to an embodiment of the present invention.

3, the heat dissipating device 330 includes a main body 331, a heat dissipating fin 332, a partition wall 333, and a heat dissipation housing 334. [

The body 331 may comprise at least one electronic component and is capable of transferring heat to the exterior.

The main body 331 includes a separate connection portion inside the main body and includes a partition wall portion 333 on which the communication module can be mounted and a heat dissipation housing 334 on one side of the main body 100 so that the heat dissipation fin can be installed do.

The radiating fins 332 are arranged on one side of the main body, and each of the radiating fins performs heat exchange with the outside through an air passage, which is an adjacent space.

The heat radiating fins 332 are connected to the heat radiating housings so that an air flow path is formed between the heat radiating fins 332 to perform heat exchange with outside air passing through the ducts 320.

The partition portion 333 separates and mounts each of the electronic components. The partition 333 may include a vertical partition wall and a horizontal partition wall. The partition wall 333 may mount an electronic component in a plurality of partition spaces 335 separated from each other.

The partition 333 is connected to the main body 331 by at least one or more fixing portions 337, and can be fixed without moving even when the radar is moved.

A heat dissipation housing (334) surrounds at least a part of the partition part, discharges heat from the electronic component to the outside, and is positioned adjacent to the heat dissipation fin.

The heat dissipation housing 334 serves to lower the heat of the component and the product. It is used for CPU or graphic card which has a lot of heat inside the main body, and it includes various metal materials such as copper and aluminum depending on the product. It is rarely used in the general type, but a memory with a high performance or an overclock (set faster than the original speed) has to heat up to cool down.

Since the heat dissipation housing 334 is required to dissipate heat quickly without a cooler, it is made into a large size advantageous for heat dissipation of the heat dissipation housing, and generally adopts copper or aluminum material having high thermal conductivity. It is possible to reduce the risk of fire when used on one side of the main body and to prevent the heat to the outside by reflecting heat, thereby increasing the heat efficiency and making it possible to detach.

3, the heat dissipating device 330 according to an embodiment of the present invention includes a heat insulating portion 370, a fixed plate block 371, an adapter block 373, a packing portion 375, a shielding portion 377 ) And threaded portions 378 and 379, respectively.

The heat dissipating device 330 has an electronic component structure integrated with a heat sink to minimize the contact thermal resistance between the electronic component and the heat sink, and an adapter between the intermediate plate and the electronic component for shielding the structure exposed to rain and electromagnetic waves when the integrated structure is applied. It is desirable to apply blocks and gaskets.

Each heat dissipating device 330 is assembled to the heat insulating part 370. The heat insulating part 370 surrounds at least a part of each heat dissipating device 330 and the heat insulating part 370 conveys heat for cooling and heating Insulate to prevent heat loss on the way. Particularly, it is preferable to apply the heat insulating wall to minimize the influence of the surrounding heat on the space in which the fluid inlet portion is assembled.

The fixed plate block 371 connects and fixes the outer surface of the duct with the radiating fin.

The adapter block 373 is connected to the heat dissipation housing and assembles the heat dissipating fin and the fixed plate block. It is a coupling tool that makes it possible to connect other electric or mechanical devices to each other. It is made of a spring device or a screw using frictional force so that it does not fall off easily.

The packing portion 375 is assembled with the adapter block and has the waterproof function of the main body. The packing portion 375 preferably includes a gasket. The gasket is a thin piece used to maintain the airtightness of the connection surface, such as a pipe flange joint, and is used for packing a stationary body in a packing. Materials used include asbestos, cotton, hemp, rubber, various synthetic resins, etc., and can be adapted to the conditions of use.

The shielding portion 377 connects the outside of the main body and the inside of the heat radiating portion, and shields the electromagnetic wave of the electronic component. In order to minimize contact thermal resistance between the electronic components and the radiating fins, an integrated electronic component structure with a radiating fin is applied. To apply a waterproof / electromagnetic shielding structure that can be exposed when the integrated structure is applied, an adapter block and a gasket .

The threaded portions 378 and 379 allow the heat dissipation housing to be fixed to the heat insulating portion 370.

4 is a view illustrating a fluid inlet 340 of a heat radiating structure of an expandable long-range radar according to an embodiment of the present invention.

4 (a) shows a case in which the cover is opened by the operation of the fluid inflow part 340, and FIG. 4 (b) shows a case in which the cover is closed.

4, the fluid inflow part 340 includes an opening / closing control part 341, a lid part 342, and a hinge structure part 343 according to an embodiment of the present invention.

The fluid inflow portion 340 is fixed to an end of the duct 320 to introduce the air into the heat dissipating device to form an air flow path. The fluid inflow part 340 includes at least one blower, and includes a sensor part, so that operation monitoring and trouble diagnosis are possible. Specifically, the blower, which is the main heat dissipation component, is redundantly applied for 24-hour uninterrupted operation of the radar, and a flow loss prevention structure using a spring is applied to prevent loss of flow to a blower which is not operated when only one blower operates. The fluid inlet 340 includes a blower 347 therein.

The opening / closing control unit 341 is connected to the duct 320 and controls the flow rate by opening / closing the inside of the duct.

A lid 342 connects the duct and the fluid inlet, opening and closing the fluid passage.

4 (a) shows a case where the lid part is rotated by the operation of the fluid inflow part 340 and the lid part is located in a direction perpendicular to the opening / closing control part 341, and Fig. 4 (b) Closing control unit 341, and closes the fluid passage. Specifically, when the blower is operated, the lid is opened by the wind force, the lid is closed by the spring restoring force when the blower is not operated, and the lid is closed during the operation of the blower.

The hinge structure part 343 connects the lid part and the fluid inflow part, and rotates the lid part according to the inflow of the fluid. The hinge structure 343 has a motion detection function.

The direction of movement of the fluid in the duct 320 is formed in a direction opposite to gravity.

5 is a view showing a hinge structure 343 of a heat radiating structure of an expandable long-range radar according to an embodiment of the present invention.

Referring to FIG. 5, the hinge structure 343 according to an embodiment of the present invention includes a sensor unit 344, a fixing table 345, and a coil spring 346.

The hinge structure 343 is connected to one side of the opening / closing control unit 341 and operated.

A lid 342 connects the duct and the fluid inlet, opening and closing the fluid passage.

The hinge structure portion 343 connects the lid portion and the fluid inlet portion, and rotates the lid portion 342 according to the inflow of the fluid. The hinge structure 343 has a motion detection function.

The sensor unit 344 senses the operation state of the fluid inlet and is connected to the hinge structure so that the flow rate and intensity of the fluid inlet can be automatically adjusted. The sensor unit 334 may include a motion recognition sensor for grasping the operation of the hinge structure 343 and a temperature sensing sensor for confirming the temperature of the electronic components.

A motion recognition sensor is a sensor that recognizes the movement and position of an object and inputs it. A sensor for detecting the direction, a sensor for detecting the movement, and a sensor for measuring the speed. In the infrared sensor equipped with both the light emitting unit and the receiving unit, the infrared ray generated from the light emitting unit is reflected by the object, and the light receiving unit detects the change amount of the reflected light to find the movement of the object or measure the intensity of the reflected light, You can see the distance. Acceleration An acceleration sensor that senses a dynamic force, such as a vibrational impact, can continuously sense the motion of an object. In addition, by using various sensors such as a temperature sensor for measuring the temperature change by changing the resistance value, a pressure sensor for measuring the magnitude and the movement of the pressure, a PSD sensor for measuring the nearness, and an ultrasonic sensor using the piezoelectric / So that the operation state of the fluid inflow portion can be detected.

The fixing table 345 is fixable to the fluid inlet.

The coil spring 346 is installed on the fixing table to store the elastic restoring force when the cover 342 is unfolded, and provides the elastic restoring force such that the cover is closed in the original state.

The coil spring 346 is connected to one end of the sensor unit, and the sensor unit senses the operation of the coil spring. Specifically, when the sensor unit 344 at the end of the coil spring 346 includes an operation recognition sensor and the lid unit is opened, a signal sensing the movement of the spring is sent to the radar opening / closing control unit, and the radar opening and closing control unit monitors the received signal If the operation signal is not received, the first fluid inflow portion is judged as a failure, and the second fluid inflow portion which is in standby is operated. Therefore, the blower which is a main heat dissipation component operates in a redundant manner.

6A and 6B are views showing the outer appearance of the heat dissipation packaging structure 300 of the heat dissipation structure of the expandable long-range radar according to the embodiment of the present invention.

6A shows a front surface of the heat dissipation packaging structure 300, and FIG. 6B shows a back surface of the heat dissipation packaging structure 300. FIG.

6, a thermal packaging structure 300 according to an embodiment of the present invention includes a structure body 310, a duct 320, a heat dissipating device 330, a first fluid inlet 350, a second fluid And includes an inflow portion 360.

In consideration of the antenna folding structure for vehicle movement, the heat-radiating packaging structure 300 has all the heat-radiating components for cooling the electronic components of the radar placed in the central body portion, not in the wings. The heat dissipation packaging structure 300 has a structure in which a structure is twisted in a heat treatment process after welding in the case of an aluminum welding structure having a width of 10m or more and a length of 10m or more. It is difficult to match the interface of the components to be assembled. However, when a modularized heat dissipation structure is used, The interface between the antenna body and the modularized heat dissipation structure can be satisfied.

The heat dissipation packaging structure 300 is a heat dissipation structure applying an air cooling type cooling structure. Air cooling is a type of cooling in a thermal design, in which air is used as a cooling medium. It is adopted in many information devices because it is excellent in economy. Natural air cooling using natural convection of air, and forced air cooling using forced fan to make air flow. Compared to natural air cooling, forced air cooling has a large flow rate, so the heat dissipation effect is one place larger. For ICs and transistors with a large amount of heat generated in information devices, heat dissipation effect may be locally increased by attaching heat dissipating vanes.

Specifically, it is a type of a cooling device for cooling air by circulating air around cylinders and blocks to eliminate the heat generated inside the transmission / reception part of the radar. In this type, there is no need for cooling water flowing through the inside of the radar, and a radiator is not required. A radiating fin with cooling effect is installed and air cools the radiating fin. Forced cooling and natural cooling can be used.

The heat dissipation packaging structure 300 is a modular heat dissipation structure for minimizing welding deformation of a large structure, and has a waterproof and electromagnetic shielding structure.

In addition, the radiating fin with adjustable width allows six heat dissipation structures to have the same heat dissipation capability, thus minimizing the temperature variation between electronic components.

The structure enclosure 310 constitutes an outer appearance, and a plurality of heat dissipation devices can be assembled in series inside.

The ducts 320 are located inside the structure enclosure and guide the air supplied to the heat sinks assembled in series.

The heat dissipating device 330 may include an electronic component, and examples of the electronic component include a transmitting and receiving portion. And is installed outside the transceiver unit to perform heat exchange with the outside. Specifically, a plurality of heat-radiating fins 332 are connected to the heat-radiating housing provided at the outer side of the main body of the transceiver unit, and an air passage is formed between the heat-radiating fins 332 to perform heat exchange with the outside .

The fluid inlet 340 is fixed to an end of the duct to allow the air to flow into the heat sink. The fluid inflow part 340 includes at least one blower, and includes a sensor part, so that operation monitoring and trouble diagnosis are possible. Specifically, the blower, which is the main heat dissipation component, is redundantly applied for 24-hour uninterrupted operation of the radar, and a flow loss prevention structure using a spring is applied to prevent loss of flow to a blower which is not operated when only one blower operates.

The radiating fins 332 are arranged on one side of the main body, and each of the radiating fins performs heat exchange with the outside through an air passage, which is an adjacent space.

The heat radiating fins 332 are connected to the heat radiating housings so that an air flow path is formed between the heat radiating fins 332 to perform heat exchange with outside air passing through the ducts 320.

The first fluid inflow section 350 and the second fluid inflow section 360 are included in the lower end of the heat dissipating packaging structure and include a first opening and closing control section 351 and a second opening and closing control section 361,

The first opening / closing control unit senses this when the first fluid inlet is shut down, transmits a driving signal to the second opening / closing control unit, and the second fluid inlet unit operates.

The fluid inflow hole 311 is a passage through which fluid flows from the fluid inflow portion and includes a first fluid inflow portion 350 and a second fluid inflow portion 360 therein. The fluid discharge portion 313 discharges the fluid that has passed through the radiating fin. The side assembly 315 may include a plurality of electronic components for driving the transceiver and the heat dissipation unit. The rear frame 317 may fix the heat dissipation packaging structure 300 on the rear surface of the heat dissipation packaging structure 300.

In one embodiment of the present invention, a shape and structure of a heat radiating fin having a folding structure can be applied. Accordingly, even if the same transceiver (TRM) is assembled, the temperature deviation between the transceiver (TRM) assembled inside the duct can be minimized by adjusting the heat radiation performance of the transceiver (TRM) .

When assembling the transceiver to the duct, fold the radiating fin according to the assembly position and assemble. In the case of a transceiver assembled at the uppermost stage, all of the radiating fins are unfolded and assembled, and as the lower side is lowered, the number of radiating fins of the transceiver is increased.

The air introduced into the duct by the blower passes through the heat-dissipating housing to exhaust the heat generated by the internal electronic components of the transceiver. The radiating fins having a structure close to the blower are folded and the radiating fins located farther away from the blower are positioned in a flat state so that the width of the radiating fins located remotely in the blower is relatively wide, and the radiating fins positioned close to the blower keep the width relatively small, By widening the flow path, the air discharged from the blower can reach to a far place, and the heat radiating effect of the radiating fin can be enhanced.

6A shows the first fluid inlet 350 and the second fluid inlet 360 on the front surface of the heat dissipating and packaging structure 300 but does not cover the outer surface of the heat dissipating and packaging structure 300. FIG. The first fluid inflow portion 350 and the second fluid inflow portion 360 are formed at the rear surface of the heat dissipation packaging structure 300 without separate decomposition in a structure in which the fluid inflow portion 350 and the second fluid inflow portion 360 are exposed. ) It can be checked and repaired in case of failure.

The first fluid inlet 350 and the second fluid inlet 360 are connected to the fluid inlet connection 361 and connected to the structure enclosure 310 by a rear fixing part 351.

As shown in Fig. 6, the blower which is a main heat dissipation component is duplicated, and a flow loss prevention structure using a spring is applied to prevent loss of flow to a blower which is not operated when only one blower operates.

7 is an exploded view showing a heat dissipation packaging structure 300 of a heat dissipation structure of an expandable long-range radar according to an embodiment of the present invention.

7, the heat dissipation packaging structure 300 according to an embodiment of the present invention includes a duct 320, a heat dissipating device 330, a fluid inflow portion 340, a fixed plate block 371, an adapter block 373, A packing portion 375, and a shielding portion 377. [

The fixed plate block 371 connects and fixes the outer surface of the duct to the radiating fin.

The adapter block 373 is connected to the heat dissipation housing and assembles the heat dissipation fin and the fixed plate block.

The packing portion 375 is assembled with the adapter block and has the waterproof function of the main body.

The shielding portion 377 connects the outside of the main body and the inside of the heat radiating portion, and shields the electromagnetic wave of the electronic component.

In the heat dissipating packaging structure, the duct is assembled on the left side of the fixed plate block, the adapter block is assembled on the right side, the plurality of heat dissipating devices are assembled to the right side of the adapter block, And is opposite to the wing frame.

The adapter block assembled to the fixed plate block, and the assembly direction of the fluid inlet in the opposite direction to the wing frame, the blower can be serviced through the radar maintenance section in the direction of the fluid inlet on the rear side.

8a-8c illustrate an expandable long-range active phased array radar in accordance with an embodiment of the present invention.

8A and 8B show a structure of an electromagnetic wave radar device and a detection device for omnidirectional detection of 300 km or more and 360 degrees.

8A is a perspective view of an expandable long-range active phased array radar 1 according to an embodiment of the present invention.

8B is a side view of an expandable long-range active phased array radar 1 according to an embodiment of the present invention.

8C is an enlarged side view of an expandable long-range active phased array radar 1 according to an embodiment of the present invention.

8A and 8B, an expandable long-range active phased array radar 1 according to an embodiment of the present invention includes a main body 100, a wing frame 200, a heat radiating packaging structure 300, (500), a support (600), and an array element (700).

The active phased array radar of the expandable long-range active phased array radar 1 according to an embodiment of the present invention is characterized in that the elements (radar modules) arranged in the radar antenna have separate semiconductor amplification and phase shifters, It is a phased array radar that can be performed. Since each device can independently emit and deflect the beam and receive its own reflected signal, the characteristics of the deflected beam in each device are all different. This is equivalent to an active electronically scanned array radar (AESAR).

The body part 100 includes a plurality of heat dissipation packaging structures for connecting the antenna device and transmitting heat to the outside.

The wing frame 200 is movably installed on the body portion, and can be selectively positioned on both sides of the body portion.

The wing frame 200 includes a first wing frame 210 connected to one side of the body portion and a second wing frame 230 connected to the other side of the body portion.

The wing frame 200 is connected to the body portion in a folding structure. The first wing frame 210 and the second wing frame 230 may be connected to the body 100 in a folding structure. In addition to the folding structure, the first wing frame 210 and the second wing frame 230 may have a slide structure, And can be made in an adjustable structure. The wing frame 200 is a structure capable of reducing a width of about 8 meters when the folding type antenna apparatus is moved, and the structure is folded sequentially without interference.

The radar maintenance unit 500 performs maintenance in a direction opposite to a direction in which the body portion connects the antenna device.

However, according to the embodiment of the present invention, the radar maintenance unit 500 can perform the maintenance in the direction opposite to the direction in which the body portion connects the antenna device So that it can be efficiently managed.

A plurality of array elements 700 are included within the plane range of the wing frame.

The body part 100 and the wing frame 200 may constitute the antenna part 20 by coupling the antenna device. The antenna unit 20 transmits and receives a detection signal of the radar, and the radiated area is adjustable. It is desirable to apply the folding hinge structure considering the road width when the antenna unit is mounted and moved. The antenna unit 20 is the main antenna unit of the antenna apparatus of the expandable radar. The primary antenna preferably radiates and receives the primary radar beam and preferably has a width of 30 to 36 wavelengths and a length of 27 to 33 wavelengths on the surface emitting the beam. And has a folding structure in which a rotation coupler is applied to an antenna element to facilitate movement. A high power amplifier and a digital transceiver are mounted in each row of the main antenna for electron beam steering and digital beamforming.

The driving unit 880 is connected to the lower end of the antenna unit to drive the antenna unit.

The driving unit 880 fixes the antenna at the time of rotation and rotates the antenna at a constant cycle. The drive unit 880 includes a redundant motor so that it can be immediately replaced when the motor fails. Also, the antenna rotation angle can be recognized by attaching a sensor that detects the rotation angle of the antenna.

The angle adjusting unit 840 connects the antenna unit and the driving unit, and rotates and adjusts the angle of the antenna unit. A motor 860 that receives a driving signal for rotating and raising the antenna unit from the driving unit and receives the driving signal to rotate forward or reverse, and a motor side gear that moves in conjunction with the motor.

The antenna pedestal 890 supports the antenna device and rotates while rotating. The antenna pedestal 890 and the antenna unit are connected by separate hinges, and the antenna can be laid down using the motor 860.

The secondary antenna 820 preferably radiates and receives the beam of the secondary radar and preferably has a wavelength of 27 to 30 wavelengths on the surface radiating the beam and 6 wavelengths to 7 wavelengths in the lengthwise direction.

The antenna coupler 810 can rotate by ± 5 degrees, and the electromagnetic wave radiation surface offset of the main antenna surface and the auxiliary antenna is possible. The offset can be set by considering the beam angle of the main antenna and the beam angle of the sub-antenna, thereby reducing the interference between the two antennas.

The sub-cutoff antenna 830 is mounted on the main antenna, and a low-noise amplifier is incorporated to minimize the reception noise.

The transmission / reception control unit 850 controls the antenna apparatus, collects the status of the apparatus, and performs the maintenance correction function. During beam transmission, control commands are transmitted to each transmitter according to the transmission phase correction value and the beam steering value to adjust the phase. Collects the digital data received by the digital receiver, and transmits the collected data to the signal processing device in the form of data.

FIG. 9 is a diagram illustrating a thermal packaging structure mounted on an expandable long-range active phased array radar according to an embodiment of the present invention.

The body 100 includes a plurality of heat-dissipating packaging structures connected to a separate antenna device and transferring heat to the outside.

The wing frame 200 may be movably installed on the body portion, and may be selectively positioned on both sides of the body portion.

The wing frame 200 includes a first wing frame 210 connected to one side of the body portion and a second wing frame 230 connected to the other side of the body portion.

The ducts 320 are located inside the structure enclosure and guide the air supplied to the heat sinks assembled in series.

The duct 320 is a passage and structure through which air or other fluid flows. When the air flows, it is also called "wind". It is often used that the cross section is rectangular or circular, but sometimes it may be elliptical. When the temperature of the air flowing through the duct is different from the surrounding temperature, it is necessary to wind the insulation around the duct when it is desired to prevent the heat from moving. Usually steel sheets are often used, but sometimes vinyl chloride or glass fiber is also used.

The heat dissipating device 330 may include an electronic component, and examples of the electronic component include a transmitting and receiving portion. And is installed outside the transceiver unit to perform heat exchange with the outside. Specifically, a plurality of heat-radiating fins 332 are connected to the heat-radiating housing provided at the outer side of the main body of the transceiver unit, and an air passage is formed between the heat-radiating fins 332 to perform heat exchange with the outside .

The heat dissipating device 330 may include at least one communication module and includes a body capable of transmitting heat to the outside and a plurality of radiating fins arranged at an outer side of the body, Wherein the main body includes a temperature sensor for sensing a temperature of the electronic component, a partition wall for separately mounting the electronic components, and at least a part of the partition wall, And a heat dissipation housing that discharges heat from the electronic component to the outside and is located adjacent to the heat dissipation fin.

The fluid inlet 340 is fixed to an end of the duct to allow the air to flow into the heat sink. The fluid inflow part 340 includes at least one blower, and includes a sensor part, so that operation monitoring and trouble diagnosis are possible. Specifically, the blower, which is the main heat dissipation component, is redundantly applied for 24-hour uninterrupted operation of the radar, and a flow loss prevention structure using a spring is applied to prevent loss of flow to a blower which is not operated when only one blower operates.

Each of the heat dissipating devices 330 is assembled to the heat insulating part 370 so that the heat insulating part 370 surrounds at least a part of each heat dissipating device 330 so that the heat insulating part 370 can heat Insulate to prevent heat loss during transportation.

The antenna coupler 810 can rotate by ± 5 degrees, and the electromagnetic wave radiation surface offset of the main antenna surface and the auxiliary antenna is possible. The offset can be set by considering the beam angle of the main antenna and the beam angle of the sub-antenna, thereby reducing the interference between the two antennas.

10 is a flowchart illustrating a heat dissipation method of an expandable long-range active phased array radar according to an embodiment of the present invention.

The open / close control unit controls the fluid inflow unit as shown in FIG. 10 for 24-hour uninterrupted operation of the radar.

Referring to FIG. 10, a method for radiating an expandable long-range active phased array radar according to an embodiment of the present invention starts at a step S110 in which a radar is in operation.

In step S120, the first fluid inlet is operated.

In step S130, the sensor unit confirms whether or not the failure signal of the first fluid inlet has been received.

If a failure signal is not received in step S140, the sensor unit checks the temperature of the transmitter and the receiver. The first opening and closing control section judges that the temperature of the electronic component is normal when the temperature is below the set temperature.

When a failure signal is received in step S150, the second fluid inlet is operated. Specifically, a drive signal is transmitted to the second open / close control unit when the operation detection signal of the first fluid inlet unit is not received, and the drive signal is transmitted to the second open / close control unit when the temperature of the electronic component exceeds the set temperature. The second open / close control unit drives the second fluid inlet, and the heat dissipation method of the expandable long-range active phased array radar is terminated.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, the scope of the present invention is not limited to the above-described embodiments, but should be construed to include various embodiments within the scope of the claims.

1: Scalable long-range active phased array radar
10: Extendable long-range radar heat dissipation structure
100:
200: wing frame
300: heat dissipation packaging structure
310: Structure enclosure
320: Duct
330: Heat dissipation device
340: fluid inlet
400: Mounting frame

Claims (5)

A heat dissipation device for transferring heat of at least one electronic component to be discharged to the outside; A fluid inlet fixed to one end of the duct to introduce air into the heat dissipating device to form an air flow path; The method comprising the steps of:
Wherein the fluid inlet includes a first fluid inlet and a second fluid inlet and includes an opening and closing controller for opening and closing the interior of the duct to control the flow rate, A first opening and closing control unit and a second opening and closing control unit for opening and closing the inside of the duct to control the flow rate; / RTI >
Detecting an operation state of the fluid inlet, and sensing an operation of the first fluid inlet, wherein a sensor unit senses an air flow rate or intensity of the fluid inlet; The first opening / closing control unit checking the temperature of the electronic component according to whether the failure signal is received from the sensor unit according to the operation of the first fluid inlet unit; And determining that the first opening / closing control unit is in a first abnormal state in which the operation of the second fluid inlet is required when the temperature of the electronic component is equal to or higher than a set temperature; Wherein the radar system includes a plurality of active radar systems. The method according to claim 1,
Wherein the heat dissipating device includes a foldable heat dissipating fin on the outside,
Wherein the opening / closing control unit comprises: a lid unit for opening / closing a passage of the fluid; And a hinge structure connecting the lid and the fluid inlet and rotating the lid according to the inflow of the fluid,
The sensor unit senses the operation state of the fluid inflow unit and is connected to the hinge structure unit so that the air volume or intensity of the fluid inflow unit can be automatically adjusted.
Sensing the operation state of the fluid inlet by the sensor unit; And
And automatically adjusting an air flow rate or intensity of the fluid inflow portion according to an operation state of the fluid inflow portion. delete 3. The method of claim 2,
Wherein the step of verifying the temperature of the electronic component comprises:
Wherein the first opening and closing control unit confirms the temperature of the electronic component when a failure signal according to the operation of the first fluid inflow unit is not received from the sensor unit,
The first open / close control unit transmitting a drive signal to the second open / close control unit after the step of determining that the first abnormal state is present; And
The second opening / closing control unit driving the second fluid inlet; Wherein the radar system further comprises: 5. The method of claim 4,
Sensing the air flow rate of the fluid inlet; And
And controlling the flow rate of the fluid flowing in the first opening / closing control unit.

Images